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id="toc-Characteristics" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Characteristics"> <div class="vector-toc-text"> 2.3.1 Characteristics </div> </a> <ul id="toc-Characteristics-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Procedures" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Procedures"> <div class="vector-toc-text"> 2.3.2 Procedures </div> </a> <ul id="toc-Procedures-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Examples" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Examples"> <div class="vector-toc-text"> 2.3.3 Examples </div> </a> <ul id="toc-Examples-sublist" class="vector-toc-list"> </ul> </li> </ul> </li> <li id="toc-Structural_materials" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Structural_materials"> <div class="vector-toc-text"> 2.4 Structural materials </div> </a> <ul id="toc-Structural_materials-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Neuronal_computers" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Neuronal_computers"> <div class="vector-toc-text"> 2.5 Neuronal computers </div> </a> <ul id="toc-Neuronal_computers-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Self_healing-materials" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Self_healing-materials"> <div class="vector-toc-text"> 2.6 Self healing-materials </div> </a> <ul id="toc-Self_healing-materials-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Surfaces" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Surfaces"> <div class="vector-toc-text"> 2.7 Surfaces </div> </a> <ul id="toc-Surfaces-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Adhesion" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Adhesion"> <div class="vector-toc-text"> 2.8 Adhesion </div> </a> <ul id="toc-Adhesion-sublist" class="vector-toc-list"> <li id="toc-Wet_adhesion" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Wet_adhesion"> <div class="vector-toc-text"> 2.8.1 Wet adhesion </div> </a> <ul id="toc-Wet_adhesion-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Dry_adhesion" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Dry_adhesion"> <div class="vector-toc-text"> 2.8.2 Dry adhesion </div> </a> <ul id="toc-Dry_adhesion-sublist" class="vector-toc-list"> </ul> </li> </ul> </li> <li id="toc-Liquid_repellency" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Liquid_repellency"> <div class="vector-toc-text"> 2.9 Liquid repellency </div> </a> <ul id="toc-Liquid_repellency-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Optics" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Optics"> <div class="vector-toc-text"> 2.10 Optics </div> </a> <ul id="toc-Optics-sublist" class="vector-toc-list"> <li id="toc-Inspiration_from_fruits_and_plants" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Inspiration_from_fruits_and_plants"> <div class="vector-toc-text"> 2.10.1 Inspiration from fruits and plants </div> </a> <ul id="toc-Inspiration_from_fruits_and_plants-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Inspiration_from_animals" class="vector-toc-list-item vector-toc-level-3"> <a class="vector-toc-link" href="#Inspiration_from_animals"> <div class="vector-toc-text"> 2.10.2 Inspiration from animals </div> </a> <ul id="toc-Inspiration_from_animals-sublist" class="vector-toc-list"> </ul> </li> </ul> </li> <li id="toc-Agricultural_systems" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Agricultural_systems"> <div class="vector-toc-text"> 2.11 Agricultural systems </div> </a> <ul id="toc-Agricultural_systems-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Other_uses" class="vector-toc-list-item vector-toc-level-2"> <a class="vector-toc-link" href="#Other_uses"> <div class="vector-toc-text"> 2.12 Other uses </div> </a> <ul id="toc-Other_uses-sublist" class="vector-toc-list"> </ul> </li> </ul> </li> <li id="toc-Other_technologies" class="vector-toc-list-item vector-toc-level-1 vector-toc-list-item-expanded"> <a class="vector-toc-link" href="#Other_technologies"> <div class="vector-toc-text"> 3 Other technologies </div> </a> <ul id="toc-Other_technologies-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-See_also" class="vector-toc-list-item vector-toc-level-1 vector-toc-list-item-expanded"> <a class="vector-toc-link" href="#See_also"> <div class="vector-toc-text"> 4 See also </div> </a> <ul id="toc-See_also-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-References" class="vector-toc-list-item vector-toc-level-1 vector-toc-list-item-expanded"> <a class="vector-toc-link" href="#References"> <div class="vector-toc-text"> 5 References </div> </a> <ul id="toc-References-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-Further_reading" class="vector-toc-list-item vector-toc-level-1 vector-toc-list-item-expanded"> <a class="vector-toc-link" href="#Further_reading"> <div class="vector-toc-text"> 6 Further reading </div> </a> <ul id="toc-Further_reading-sublist" class="vector-toc-list"> </ul> </li> <li id="toc-External_links" class="vector-toc-list-item vector-toc-level-1 vector-toc-list-item-expanded"> <a class="vector-toc-link" href="#External_links"> <div class="vector-toc-text"> 7 External links </div> </a> <ul id="toc-External_links-sublist" class="vector-toc-list"> </ul> </li> </ul> </div> </div> </nav> </div> </div> <div class="mw-content-container"> <main id="content" class="mw-body"> <header class="mw-body-header vector-page-titlebar"> <nav aria-label="Contents" class="vector-toc-landmark"> <div id="vector-page-titlebar-toc" class="vector-dropdown vector-page-titlebar-toc vector-button-flush-left" > <input type="checkbox" id="vector-page-titlebar-toc-checkbox" role="button" aria-haspopup="true" data-event-name="ui.dropdown-vector-page-titlebar-toc" class="vector-dropdown-checkbox " aria-label="Toggle the table of contents" > <label id="vector-page-titlebar-toc-label" for="vector-page-titlebar-toc-checkbox" class="vector-dropdown-label cdx-button cdx-button--fake-button cdx-button--fake-button--enabled cdx-button--weight-quiet cdx-button--icon-only " aria-hidden="true" > Toggle the table of contents </label> <div class="vector-dropdown-content"> <div id="vector-page-titlebar-toc-unpinned-container" class="vector-unpinned-container"> </div> </div> </div> </nav> <h1 id="firstHeading" class="firstHeading mw-first-heading">Biomimetics</h1> <div id="p-lang-btn" class="vector-dropdown mw-portlet mw-portlet-lang" > <input type="checkbox" id="p-lang-btn-checkbox" role="button" aria-haspopup="true" data-event-name="ui.dropdown-p-lang-btn" class="vector-dropdown-checkbox mw-interlanguage-selector" aria-label="Go to an article in another language. Available in 35 languages" > <label id="p-lang-btn-label" for="p-lang-btn-checkbox" class="vector-dropdown-label cdx-button cdx-button--fake-button cdx-button--fake-button--enabled cdx-button--weight-quiet cdx-button--action-progressive mw-portlet-lang-heading-35" aria-hidden="true" > 35 languages </label> <div class="vector-dropdown-content"> <div class="vector-menu-content"> <ul class="vector-menu-content-list"> <li class="interlanguage-link interwiki-ar mw-list-item"><a href="https://ar.wikipedia.org/wiki/%D9%85%D8%AD%D8%A7%D9%83%D8%A7%D8%A9_%D8%AD%D9%8A%D9%88%D9%8A%D8%A9" title="محاكاة حيوية – Arabic" lang="ar" hreflang="ar" data-title="محاكاة حيوية" data-language-autonym="العربية" data-language-local-name="Arabic" class="interlanguage-link-target">العربية</a></li><li class="interlanguage-link interwiki-az mw-list-item"><a href="https://az.wikipedia.org/wiki/Biomimetika" title="Biomimetika – Azerbaijani" lang="az" hreflang="az" data-title="Biomimetika" data-language-autonym="Azərbaycanca" data-language-local-name="Azerbaijani" class="interlanguage-link-target">Azərbaycanca</a></li><li class="interlanguage-link interwiki-bg mw-list-item"><a href="https://bg.wikipedia.org/wiki/%D0%91%D0%B8%D0%BE%D0%BC%D0%B8%D0%BC%D0%B5%D1%82%D0%B8%D0%BA%D0%B0" title="Биомиметика – Bulgarian" lang="bg" hreflang="bg" data-title="Биомиметика" data-language-autonym="Български" data-language-local-name="Bulgarian" class="interlanguage-link-target">Български</a></li><li class="interlanguage-link interwiki-ca mw-list-item"><a href="https://ca.wikipedia.org/wiki/Biomim%C3%A8tica" title="Biomimètica – Catalan" lang="ca" hreflang="ca" data-title="Biomimètica" data-language-autonym="Català" data-language-local-name="Catalan" class="interlanguage-link-target">Català</a></li><li class="interlanguage-link interwiki-cs mw-list-item"><a href="https://cs.wikipedia.org/wiki/Biomimetika" title="Biomimetika – Czech" lang="cs" hreflang="cs" data-title="Biomimetika" data-language-autonym="Čeština" data-language-local-name="Czech" class="interlanguage-link-target">Čeština</a></li><li class="interlanguage-link interwiki-cy mw-list-item"><a href="https://cy.wikipedia.org/wiki/Bioddynwared" title="Bioddynwared – Welsh" lang="cy" hreflang="cy" data-title="Bioddynwared" data-language-autonym="Cymraeg" data-language-local-name="Welsh" class="interlanguage-link-target">Cymraeg</a></li><li class="interlanguage-link interwiki-ary mw-list-item"><a href="https://ary.wikipedia.org/wiki/%D8%A8%D9%8A%D9%88%D8%AA%D9%82%D9%84%D9%8A%D8%AF" title="بيوتقليد – Moroccan Arabic" lang="ary" hreflang="ary" data-title="بيوتقليد" data-language-autonym="الدارجة" data-language-local-name="Moroccan Arabic" class="interlanguage-link-target">الدارجة</a></li><li class="interlanguage-link interwiki-de badge-Q70894304 mw-list-item" title=""><a href="https://de.wikipedia.org/wiki/Biomimetik" title="Biomimetik – German" lang="de" hreflang="de" data-title="Biomimetik" data-language-autonym="Deutsch" data-language-local-name="German" class="interlanguage-link-target">Deutsch</a></li><li class="interlanguage-link interwiki-et mw-list-item"><a href="https://et.wikipedia.org/wiki/Biomimikri" title="Biomimikri – Estonian" lang="et" hreflang="et" data-title="Biomimikri" data-language-autonym="Eesti" data-language-local-name="Estonian" class="interlanguage-link-target">Eesti</a></li><li class="interlanguage-link interwiki-es mw-list-item"><a href="https://es.wikipedia.org/wiki/Biomimesis" title="Biomimesis – Spanish" lang="es" hreflang="es" data-title="Biomimesis" data-language-autonym="Español" data-language-local-name="Spanish" class="interlanguage-link-target">Español</a></li><li class="interlanguage-link interwiki-eo mw-list-item"><a href="https://eo.wikipedia.org/wiki/Biomimetiko" title="Biomimetiko – Esperanto" lang="eo" hreflang="eo" data-title="Biomimetiko" data-language-autonym="Esperanto" data-language-local-name="Esperanto" class="interlanguage-link-target">Esperanto</a></li><li class="interlanguage-link interwiki-eu mw-list-item"><a href="https://eu.wikipedia.org/wiki/Biomimetismo" title="Biomimetismo – Basque" lang="eu" hreflang="eu" data-title="Biomimetismo" data-language-autonym="Euskara" data-language-local-name="Basque" class="interlanguage-link-target">Euskara</a></li><li class="interlanguage-link interwiki-fa mw-list-item"><a href="https://fa.wikipedia.org/wiki/%D8%B2%DB%8C%D8%B3%D8%AA%E2%80%8C%D8%AA%D9%82%D9%84%DB%8C%D8%AF" title="زیست‌تقلید – Persian" lang="fa" hreflang="fa" data-title="زیست‌تقلید" data-language-autonym="فارسی" data-language-local-name="Persian" class="interlanguage-link-target">فارسی</a></li><li class="interlanguage-link interwiki-fr mw-list-item"><a href="https://fr.wikipedia.org/wiki/Biomim%C3%A9tisme" title="Biomimétisme – French" lang="fr" hreflang="fr" data-title="Biomimétisme" data-language-autonym="Français" data-language-local-name="French" class="interlanguage-link-target">Français</a></li><li class="interlanguage-link interwiki-ki mw-list-item"><a href="https://ki.wikipedia.org/wiki/Bayo-egekia" title="Bayo-egekia – Kikuyu" lang="ki" hreflang="ki" data-title="Bayo-egekia" data-language-autonym="Gĩkũyũ" data-language-local-name="Kikuyu" class="interlanguage-link-target">Gĩkũyũ</a></li><li class="interlanguage-link interwiki-ko mw-list-item"><a href="https://ko.wikipedia.org/wiki/%EC%83%9D%EC%B2%B4%EB%AA%A8%EB%B0%A9" title="생체모방 – Korean" lang="ko" hreflang="ko" data-title="생체모방" data-language-autonym="한국어" data-language-local-name="Korean" class="interlanguage-link-target">한국어</a></li><li class="interlanguage-link interwiki-hi mw-list-item"><a href="https://hi.wikipedia.org/wiki/%E0%A4%AA%E0%A5%8D%E0%A4%B0%E0%A4%95%E0%A5%83%E0%A4%A4%E0%A4%BF_%E0%A4%85%E0%A4%AD%E0%A4%BF%E0%A4%AA%E0%A5%8D%E0%A4%B0%E0%A5%87%E0%A4%B0%E0%A4%BF%E0%A4%A4_%E0%A4%A8%E0%A4%BF%E0%A4%B0%E0%A5%8D%E0%A4%AE%E0%A4%BE%E0%A4%A3" title="प्रकृति अभिप्रेरित निर्माण – Hindi" lang="hi" hreflang="hi" data-title="प्रकृति अभिप्रेरित निर्माण" data-language-autonym="हिन्दी" data-language-local-name="Hindi" class="interlanguage-link-target">हिन्दी</a></li><li class="interlanguage-link interwiki-hr mw-list-item"><a href="https://hr.wikipedia.org/wiki/Biomimikrija_u_energetici" title="Biomimikrija u energetici – Croatian" lang="hr" hreflang="hr" data-title="Biomimikrija u energetici" data-language-autonym="Hrvatski" data-language-local-name="Croatian" class="interlanguage-link-target">Hrvatski</a></li><li class="interlanguage-link interwiki-id mw-list-item"><a href="https://id.wikipedia.org/wiki/Biomimetika" title="Biomimetika – Indonesian" lang="id" hreflang="id" data-title="Biomimetika" data-language-autonym="Bahasa Indonesia" data-language-local-name="Indonesian" class="interlanguage-link-target">Bahasa Indonesia</a></li><li class="interlanguage-link interwiki-it mw-list-item"><a href="https://it.wikipedia.org/wiki/Biomimesi" title="Biomimesi – Italian" lang="it" hreflang="it" data-title="Biomimesi" data-language-autonym="Italiano" data-language-local-name="Italian" class="interlanguage-link-target">Italiano</a></li><li class="interlanguage-link interwiki-he mw-list-item"><a href="https://he.wikipedia.org/wiki/%D7%91%D7%99%D7%95%D7%9E%D7%99%D7%9E%D7%98%D7%99%D7%A7%D7%94" title="ביומימטיקה – Hebrew" lang="he" hreflang="he" data-title="ביומימטיקה" data-language-autonym="עברית" data-language-local-name="Hebrew" class="interlanguage-link-target">עברית</a></li><li class="interlanguage-link interwiki-lv mw-list-item"><a href="https://lv.wikipedia.org/wiki/Biom%C4%ABmikrija" title="Biomīmikrija – Latvian" lang="lv" hreflang="lv" data-title="Biomīmikrija" data-language-autonym="Latviešu" data-language-local-name="Latvian" class="interlanguage-link-target">Latviešu</a></li><li class="interlanguage-link interwiki-ms mw-list-item"><a href="https://ms.wikipedia.org/wiki/Biomimetik" title="Biomimetik – Malay" lang="ms" hreflang="ms" data-title="Biomimetik" data-language-autonym="Bahasa Melayu" data-language-local-name="Malay" class="interlanguage-link-target">Bahasa Melayu</a></li><li class="interlanguage-link interwiki-nl mw-list-item"><a href="https://nl.wikipedia.org/wiki/Biomimetica" title="Biomimetica – Dutch" lang="nl" hreflang="nl" data-title="Biomimetica" data-language-autonym="Nederlands" data-language-local-name="Dutch" class="interlanguage-link-target">Nederlands</a></li><li class="interlanguage-link interwiki-ja mw-list-item"><a href="https://ja.wikipedia.org/wiki/%E3%83%90%E3%82%A4%E3%82%AA%E3%83%9F%E3%83%A1%E3%83%86%E3%82%A3%E3%82%AF%E3%82%B9" title="バイオミメティクス – Japanese" lang="ja" hreflang="ja" data-title="バイオミメティクス" data-language-autonym="日本語" data-language-local-name="Japanese" class="interlanguage-link-target">日本語</a></li><li class="interlanguage-link interwiki-pt mw-list-item"><a href="https://pt.wikipedia.org/wiki/Biomim%C3%A9tica" title="Biomimética – Portuguese" lang="pt" hreflang="pt" data-title="Biomimética" data-language-autonym="Português" data-language-local-name="Portuguese" class="interlanguage-link-target">Português</a></li><li class="interlanguage-link interwiki-ro mw-list-item"><a href="https://ro.wikipedia.org/wiki/Biomimetic%C4%83" title="Biomimetică – Romanian" lang="ro" hreflang="ro" data-title="Biomimetică" data-language-autonym="Română" data-language-local-name="Romanian" class="interlanguage-link-target">Română</a></li><li class="interlanguage-link interwiki-ru badge-Q70894304 mw-list-item" title=""><a href="https://ru.wikipedia.org/wiki/%D0%91%D0%B8%D0%BE%D0%BC%D0%B8%D0%BC%D0%B5%D1%82%D0%B8%D0%BA%D0%B0" title="Биомиметика – Russian" lang="ru" hreflang="ru" data-title="Биомиметика" data-language-autonym="Русский" data-language-local-name="Russian" class="interlanguage-link-target">Русский</a></li><li class="interlanguage-link interwiki-sq mw-list-item"><a href="https://sq.wikipedia.org/wiki/Biomimika" title="Biomimika – Albanian" lang="sq" hreflang="sq" data-title="Biomimika" data-language-autonym="Shqip" data-language-local-name="Albanian" class="interlanguage-link-target">Shqip</a></li><li class="interlanguage-link interwiki-sl mw-list-item"><a href="https://sl.wikipedia.org/wiki/Biomimetika" title="Biomimetika – Slovenian" lang="sl" hreflang="sl" data-title="Biomimetika" data-language-autonym="Slovenščina" data-language-local-name="Slovenian" class="interlanguage-link-target">Slovenščina</a></li><li class="interlanguage-link interwiki-sr mw-list-item"><a href="https://sr.wikipedia.org/wiki/%D0%91%D0%B8%D0%BE%D0%BC%D0%B8%D0%BC%D0%B5%D1%82%D0%B8%D0%BA%D0%B0" title="Биомиметика – Serbian" lang="sr" hreflang="sr" data-title="Биомиметика" data-language-autonym="Српски / srpski" data-language-local-name="Serbian" class="interlanguage-link-target">Српски / srpski</a></li><li class="interlanguage-link interwiki-sv mw-list-item"><a href="https://sv.wikipedia.org/wiki/Biomimetik" title="Biomimetik – Swedish" lang="sv" hreflang="sv" data-title="Biomimetik" data-language-autonym="Svenska" data-language-local-name="Swedish" class="interlanguage-link-target">Svenska</a></li><li class="interlanguage-link interwiki-ta mw-list-item"><a href="https://ta.wikipedia.org/wiki/%E0%AE%89%E0%AE%AF%E0%AE%BF%E0%AE%B0%E0%AE%A9%E0%AF%88%E0%AE%AF%E0%AE%BE%E0%AE%95%E0%AF%8D%E0%AE%95%E0%AE%AE%E0%AF%8D" title="உயிரனையாக்கம் – Tamil" lang="ta" hreflang="ta" data-title="உயிரனையாக்கம்" data-language-autonym="தமிழ்" data-language-local-name="Tamil" class="interlanguage-link-target">தமிழ்</a></li><li class="interlanguage-link interwiki-th mw-list-item"><a href="https://th.wikipedia.org/wiki/%E0%B9%84%E0%B8%9A%E0%B9%82%E0%B8%AD%E0%B8%A1%E0%B8%B4%E0%B9%80%E0%B8%A1%E0%B8%95%E0%B8%B4%E0%B8%81%E0%B8%AA%E0%B9%8C" title="ไบโอมิเมติกส์ – Thai" lang="th" hreflang="th" data-title="ไบโอมิเมติกส์" data-language-autonym="ไทย" data-language-local-name="Thai" class="interlanguage-link-target">ไทย</a></li><li class="interlanguage-link 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searchaux" style="display:none">Imitation of biological systems for the solving of human problems</div> <style data-mw-deduplicate="TemplateStyles:r1237032888/mw-parser-output/.tmulti">.mw-parser-output .tmulti .multiimageinner{display:flex;flex-direction:column}.mw-parser-output .tmulti .trow{display:flex;flex-direction:row;clear:left;flex-wrap:wrap;width:100%;box-sizing:border-box}.mw-parser-output .tmulti .tsingle{margin:1px;float:left}.mw-parser-output .tmulti .theader{clear:both;font-weight:bold;text-align:center;align-self:center;background-color:transparent;width:100%}.mw-parser-output .tmulti .thumbcaption{background-color:transparent}.mw-parser-output .tmulti .text-align-left{text-align:left}.mw-parser-output .tmulti .text-align-right{text-align:right}.mw-parser-output .tmulti .text-align-center{text-align:center}@media all and (max-width:720px){.mw-parser-output .tmulti .thumbinner{width:100%!important;box-sizing:border-box;max-width:none!important;align-items:center}.mw-parser-output .tmulti .trow{justify-content:center}.mw-parser-output .tmulti .tsingle{float:none!important;max-width:100%!important;box-sizing:border-box;text-align:center}.mw-parser-output .tmulti .tsingle .thumbcaption{text-align:left}.mw-parser-output .tmulti .trow>.thumbcaption{text-align:center}}@media screen{html.skin-theme-clientpref-night .mw-parser-output .tmulti .multiimageinner img{background-color:white}}@media screen and (prefers-color-scheme:dark){html.skin-theme-clientpref-os .mw-parser-output .tmulti .multiimageinner img{background-color:white}}</style><div class="thumb tmulti tright"><div class="thumbinner multiimageinner" style="width:402px;max-width:402px"><div class="trow"><div class="tsingle" style="width:176px;max-width:176px"><div class="thumbimage" style="height:140px;overflow:hidden"><a href="/wiki/File:Bur_Macro_BlackBg.jpg" class="mw-file-description"><img alt="burr" src="//upload.wikimedia.org/wikipedia/commons/thumb/1/13/Bur_Macro_BlackBg.jpg/174px-Bur_Macro_BlackBg.jpg" decoding="async" width="174" height="140" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/1/13/Bur_Macro_BlackBg.jpg/261px-Bur_Macro_BlackBg.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/1/13/Bur_Macro_BlackBg.jpg/348px-Bur_Macro_BlackBg.jpg 2x" data-file-width="2184" data-file-height="1760" /></a></div></div><div class="tsingle" style="width:222px;max-width:222px"><div class="thumbimage" style="height:140px;overflow:hidden"><a href="/wiki/File:Klettverschluss.jpg" class="mw-file-description"><img alt="velcro tape" src="//upload.wikimedia.org/wikipedia/commons/thumb/e/e2/Klettverschluss.jpg/220px-Klettverschluss.jpg" decoding="async" width="220" height="141" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/e/e2/Klettverschluss.jpg/330px-Klettverschluss.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/e/e2/Klettverschluss.jpg/440px-Klettverschluss.jpg 2x" data-file-width="1600" data-file-height="1022" /></a></div></div></div><div class="trow" style="display:flex"><div class="thumbcaption">The tiny hooks on <a href="/wiki/Bur" title="Bur">bur</a> fruits (left) inspired <a href="/wiki/Velcro" title="Velcro">Velcro</a> tape (right).</div></div></div></div> <figure class="mw-default-size" typeof="mw:File/Thumb"><a href="/wiki/File:Loligo_forbesii.jpg" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Loligo_forbesii.jpg/220px-Loligo_forbesii.jpg" decoding="async" width="220" height="177" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Loligo_forbesii.jpg/330px-Loligo_forbesii.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Loligo_forbesii.jpg/440px-Loligo_forbesii.jpg 2x" data-file-width="2200" data-file-height="1771" /></a><figcaption> <a href="/wiki/Axons" class="mw-redirect" title="Axons">Giant axons</a> of the <a href="/wiki/Longfin_inshore_squid" title="Longfin inshore squid">longfin inshore squid</a> (Doryteuthis pealeii) were crucial for scientists to understand the <a href="/wiki/Action_potential" title="Action potential">action potential</a>.<a href="#cite_note-1">[1]</a></figcaption></figure> Biomimetics or biomimicry is the emulation of the models, systems, and elements of nature for the purpose of solving complex <a href="/wiki/Human" title="Human">human</a> problems.<a href="#cite_note-:6-2">[2]</a><a href="#cite_note-3">[3]</a><a href="#cite_note-:5-4">[4]</a> The terms "biomimetics" and "biomimicry" are derived from <a href="/wiki/Ancient_Greek_language" class="mw-redirect" title="Ancient Greek language">Ancient Greek</a>: βίος (bios), life, and μίμησις (<a href="/wiki/Mimesis" title="Mimesis">mīmēsis</a>), imitation, from μιμεῖσθαι (mīmeisthai), to imitate, from μῖμος (mimos), actor. A closely related field is <a href="/wiki/Bionics" title="Bionics">bionics</a>.<a href="#cite_note-McCarty-5">[5]</a> Nature has gone through <a href="/wiki/Evolution" title="Evolution">evolution</a> over the 3.8 billion years since life is estimated to have appeared on the Earth.<a href="#cite_note-6">[6]</a> It has evolved species with high performance using commonly found materials. Surfaces of solids interact with other surfaces and the environment and derive the properties of materials. Biological materials are highly organized from the molecular to the nano-, micro-, and macroscales, often in a hierarchical manner with intricate nanoarchitecture that ultimately makes up a myriad of different functional elements.<a href="#cite_note-7">[7]</a> Properties of materials and surfaces result from a complex interplay between surface structure and morphology and physical and chemical properties. Many materials, surfaces, and objects in general provide multifunctionality. Various materials, structures, and devices have been fabricated for commercial interest by engineers, <a href="/wiki/Materials_science" title="Materials science">material scientists</a>, chemists, and biologists, and for beauty, structure, and design by artists and architects. Nature has solved engineering problems such as self-healing abilities, environmental exposure tolerance and resistance, <a href="/wiki/Hydrophobicity" class="mw-redirect" title="Hydrophobicity">hydrophobicity</a>, self-assembly, and harnessing <a href="/wiki/Solar_energy" title="Solar energy">solar energy</a>. Economic impact of bioinspired materials and surfaces is significant, on the order of several hundred billion dollars per year worldwide. <style data-mw-deduplicate="TemplateStyles:r886046785">.mw-parser-output .toclimit-2 .toclevel-1 ul,.mw-parser-output .toclimit-3 .toclevel-2 ul,.mw-parser-output .toclimit-4 .toclevel-3 ul,.mw-parser-output .toclimit-5 .toclevel-4 ul,.mw-parser-output .toclimit-6 .toclevel-5 ul,.mw-parser-output .toclimit-7 .toclevel-6 ul{display:none}</style><div class="toclimit-3"><meta property="mw:PageProp/toc" /></div> <div class="mw-heading mw-heading2"><h2 id="History">History</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=1" title="Edit section: History">edit</a>]</div> One of the early examples of biomimicry was the study of <a href="/wiki/Birds" class="mw-redirect" title="Birds">birds</a> to enable <a href="/wiki/Human_flight" class="mw-redirect" title="Human flight">human flight</a>. Although never successful in creating a "flying machine", <a href="/wiki/Leonardo_da_Vinci" title="Leonardo da Vinci">Leonardo da Vinci</a> (1452–1519) was a keen observer of the <a href="/wiki/Anatomy" title="Anatomy">anatomy</a> and flight of birds, and made numerous notes and sketches on his observations as well as sketches of "flying machines".<a href="#cite_note-Romei_2008_56-8">[8]</a> The <a href="/wiki/Wright_Brothers" class="mw-redirect" title="Wright Brothers">Wright Brothers</a>, who succeeded in flying the first heavier-than-air aircraft in 1903, allegedly derived inspiration from observations of pigeons in flight.<a href="#cite_note-9">[9]</a> <figure typeof="mw:File/Thumb"><a href="/wiki/File:Leonardo_Design_for_a_Flying_Machine,_c._1488.jpg" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/thumb/c/c5/Leonardo_Design_for_a_Flying_Machine%2C_c._1488.jpg/200px-Leonardo_Design_for_a_Flying_Machine%2C_c._1488.jpg" decoding="async" width="200" height="145" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/c/c5/Leonardo_Design_for_a_Flying_Machine%2C_c._1488.jpg/300px-Leonardo_Design_for_a_Flying_Machine%2C_c._1488.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/c/c5/Leonardo_Design_for_a_Flying_Machine%2C_c._1488.jpg/400px-Leonardo_Design_for_a_Flying_Machine%2C_c._1488.jpg 2x" data-file-width="620" data-file-height="450" /></a><figcaption><a href="/wiki/Leonardo_da_Vinci" title="Leonardo da Vinci">Leonardo da Vinci</a>'s <a href="/wiki/Science_and_inventions_of_Leonardo_da_Vinci#Flight" title="Science and inventions of Leonardo da Vinci">design for a flying machine</a> with wings based closely upon the structure of bat wings</figcaption></figure> During the 1950s the American <a href="/wiki/Biophysicist" class="mw-redirect" title="Biophysicist">biophysicist</a> and <a href="/wiki/Polymath" title="Polymath">polymath</a> <a href="/wiki/Otto_Schmitt" title="Otto Schmitt">Otto Schmitt</a> developed the concept of "biomimetics".<a href="#cite_note-Vincent2006-10">[10]</a> During his doctoral research he developed the <a href="/wiki/Schmitt_trigger" title="Schmitt trigger">Schmitt trigger</a> by studying the nerves in squid, attempting to engineer a device that replicated the biological system of <a href="/wiki/Nerve_impulse" class="mw-redirect" title="Nerve impulse">nerve propagation</a>.<a href="#cite_note-11">[11]</a> He continued to focus on devices that mimic natural systems and by 1957 he had perceived a converse to the standard view of <a href="/wiki/Biophysics" title="Biophysics">biophysics</a> at that time, a view he would come to call biomimetics.<a href="#cite_note-Vincent2006-10">[10]</a> <style data-mw-deduplicate="TemplateStyles:r1244412712">.mw-parser-output .templatequote{overflow:hidden;margin:1em 0;padding:0 32px}.mw-parser-output .templatequotecite{line-height:1.5em;text-align:left;margin-top:0}@media(min-width:500px){.mw-parser-output .templatequotecite{padding-left:1.6em}}</style><blockquote class="templatequote">Biophysics is not so much a subject matter as it is a point of view. It is an approach to problems of biological science utilizing the theory and technology of the physical sciences. Conversely, biophysics is also a biologist's approach to problems of physical science and engineering, although this aspect has largely been neglected.<div class="templatequotecite">— <cite>Otto Herbert Schmitt, In Appreciation, A Lifetime of Connections<a href="#cite_note-12">[12]</a></cite></div></blockquote> In 1960 <a href="/wiki/Jack_E._Steele" title="Jack E. Steele">Jack E. Steele</a> coined a similar term, <a href="/wiki/Bionics" title="Bionics">bionics</a>, at Wright-Patterson Air Force Base in Dayton, Ohio, where Otto Schmitt also worked. Steele defined bionics as "the science of systems which have some function copied from nature, or which represent characteristics of natural systems or their analogues".<a href="#cite_note-McCarty-5">[5]</a><a href="#cite_note-vincent-2009-13">[13]</a> During a later meeting in 1963 Schmitt stated, <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1244412712"><blockquote class="templatequote">Let us consider what bionics has come to mean operationally and what it or some word like it (I prefer biomimetics) ought to mean in order to make good use of the technical skills of scientists specializing, or rather, I should say, despecializing into this area of research.<div class="templatequotecite">— <cite>Otto Herbert Schmitt, In Appreciation, A Lifetime of Connections: Otto Herbert Schmitt, 1913 - 1998</cite></div></blockquote> In 1969, Schmitt used the term "biomimetic" in the title one of his papers,<a href="#cite_note-14">[14]</a> and by 1974 it had found its way into <a href="/wiki/Webster%27s_Dictionary" title="Webster's Dictionary">Webster's Dictionary</a>. Bionics entered the same dictionary earlier in 1960 as "a science concerned with the application of data about the functioning of biological systems to the solution of engineering problems". Bionic took on a different connotation when <a href="/wiki/Martin_Caidin" title="Martin Caidin">Martin Caidin</a> referenced Jack Steele and his work in the novel <a href="/wiki/Cyborg_(novel)" title="Cyborg (novel)">Cyborg</a> which later resulted in the 1974 television series <a href="/wiki/The_Six_Million_Dollar_Man" title="The Six Million Dollar Man">The Six Million Dollar Man</a> and its spin-offs. The term bionic then became associated with "the use of electronically operated artificial body parts" and "having ordinary human powers increased by or as if by the aid of such devices".<a href="#cite_note-15">[15]</a> Because the term bionic took on the implication of supernatural strength, the scientific community in <a href="/wiki/English_language" title="English language">English</a> speaking countries largely abandoned it.<a href="#cite_note-16">[16]</a> The term biomimicry appeared as early as 1982.<a href="#cite_note-17">[17]</a> Biomimicry was popularized by scientist and author <a href="/wiki/Janine_Benyus" title="Janine Benyus">Janine Benyus</a> in her 1997 book Biomimicry: Innovation Inspired by Nature. Biomimicry is defined in the book as a "new science that studies nature's models and then imitates or takes inspiration from these designs and processes to solve human problems". Benyus suggests looking to Nature as a "Model, Measure, and Mentor" and emphasizes sustainability as an objective of biomimicry.<a href="#cite_note-Benyus_1997-18">[18]</a> One of the latest examples of biomimicry has been created by Johannes-Paul Fladerer and Ernst Kurzmann by the description of "managemANT".<a href="#cite_note-19">[19]</a> This term (a combination of the words "management" and "ant"), describes the usage of behavioural strategies of ants in economic and management strategies.<a href="#cite_note-20">[20]</a> The potential long-term impacts of biomimicry were quantified in a 2013 Fermanian Business & Economic Institute Report commissioned by the San Diego Zoo. The findings demonstrated the potential economic and environmental benefits of biomimicry, which can be further seen in Johannes-Paul Fladerer and Ernst Kurzmann's "managemANT" approach. This approach utilizes the behavioral strategies of ants in economic and management strategies.<a href="#cite_note-21">[21]</a> <div class="mw-heading mw-heading2"><h2 id="Bio-inspired_technologies">Bio-inspired technologies</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=2" title="Edit section: Bio-inspired technologies">edit</a>]</div> Biomimetics could in principle be applied in many fields. Because of the diversity and complexity of biological systems, the number of features that might be imitated is large. Biomimetic applications are at various stages of development from technologies that might become commercially usable to prototypes.<a href="#cite_note-:5-4">[4]</a> <a href="/wiki/Murray%27s_law" title="Murray's law">Murray's law</a>, which in conventional form determined the optimum diameter of blood vessels, has been re-derived to provide simple equations for the pipe or tube diameter which gives a minimum mass engineering system.<a href="#cite_note-williams-22">[22]</a> <div class="mw-heading mw-heading3"><h3 id="Locomotion">Locomotion</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=3" title="Edit section: Locomotion">edit</a>]</div> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1237032888/mw-parser-output/.tmulti"><div class="thumb tmulti tright"><div class="thumbinner multiimageinner" style="width:392px;max-width:392px"><div class="trow"><div class="tsingle" style="width:180px;max-width:180px"><div class="thumbimage" style="height:133px;overflow:hidden"><a href="/wiki/File:Shinkansen_500_Kyoto_2005-04-05.jpg" class="mw-file-description"><img alt="" src="//upload.wikimedia.org/wikipedia/commons/thumb/e/ef/Shinkansen_500_Kyoto_2005-04-05.jpg/178px-Shinkansen_500_Kyoto_2005-04-05.jpg" decoding="async" width="178" height="134" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/e/ef/Shinkansen_500_Kyoto_2005-04-05.jpg/267px-Shinkansen_500_Kyoto_2005-04-05.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/e/ef/Shinkansen_500_Kyoto_2005-04-05.jpg/356px-Shinkansen_500_Kyoto_2005-04-05.jpg 2x" data-file-width="640" data-file-height="480" /></a></div></div><div class="tsingle" style="width:208px;max-width:208px"><div class="thumbimage" style="height:133px;overflow:hidden"><a href="/wiki/File:Malachite_Kingfisher,_Alcedo_cristata_at_Marievale_Nature_Reserve,_Gauteng,_South_Africa_(8688965285).jpg" class="mw-file-description"><img alt="" src="//upload.wikimedia.org/wikipedia/commons/thumb/3/36/Malachite_Kingfisher%2C_Alcedo_cristata_at_Marievale_Nature_Reserve%2C_Gauteng%2C_South_Africa_%288688965285%29.jpg/206px-Malachite_Kingfisher%2C_Alcedo_cristata_at_Marievale_Nature_Reserve%2C_Gauteng%2C_South_Africa_%288688965285%29.jpg" decoding="async" width="206" height="134" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/3/36/Malachite_Kingfisher%2C_Alcedo_cristata_at_Marievale_Nature_Reserve%2C_Gauteng%2C_South_Africa_%288688965285%29.jpg/309px-Malachite_Kingfisher%2C_Alcedo_cristata_at_Marievale_Nature_Reserve%2C_Gauteng%2C_South_Africa_%288688965285%29.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/3/36/Malachite_Kingfisher%2C_Alcedo_cristata_at_Marievale_Nature_Reserve%2C_Gauteng%2C_South_Africa_%288688965285%29.jpg/412px-Malachite_Kingfisher%2C_Alcedo_cristata_at_Marievale_Nature_Reserve%2C_Gauteng%2C_South_Africa_%288688965285%29.jpg 2x" data-file-width="2048" data-file-height="1328" /></a></div></div></div><div class="trow" style="display:flex"><div class="thumbcaption">The streamlined design of Shinkansen 500 Series (left) mimics the beak of a <a href="/wiki/Kingfisher" title="Kingfisher">Kingfisher</a> bird (right) to improve aerodynamics.</div></div></div></div> <a href="/wiki/Aircraft_wing" class="mw-redirect" title="Aircraft wing">Aircraft wing</a> design<a href="#cite_note-The_Engineer-23">[23]</a> and flight techniques<a href="#cite_note-24">[24]</a> are being inspired by birds and bats. The <a href="/wiki/Aerodynamics" title="Aerodynamics">aerodynamics</a> of streamlined design of improved Japanese high speed train <a href="/wiki/Shinkansen" title="Shinkansen">Shinkansen</a> <a href="/wiki/500_Series_Shinkansen" title="500 Series Shinkansen">500 Series</a> were modelled after the beak of <a href="/wiki/Kingfisher" title="Kingfisher">Kingfisher</a> bird.<a href="#cite_note-25">[25]</a> <a href="/wiki/Biorobotics" title="Biorobotics">Biorobots</a> based on the physiology and methods of <a href="/wiki/Animal_locomotion" title="Animal locomotion">locomotion of animals</a> include <a href="/wiki/BionicKangaroo" title="BionicKangaroo">BionicKangaroo</a> which moves like a kangaroo, saving energy from one jump and transferring it to its next jump;<a href="#cite_note-26">[26]</a> <a href="/wiki/Dash_Robotics,_Inc" title="Dash Robotics, Inc">Kamigami Robots</a>, a children's toy, mimic cockroach locomotion to run quickly and efficiently over indoor and outdoor surfaces,<a href="#cite_note-27">[27]</a> and Pleobot, a shrimp-inspired robot to study metachronal swimming and the ecological impacts of this propulsive gait on the environment.<a href="#cite_note-28">[28]</a> <div class="mw-heading mw-heading3"><h3 id="Biomimetic_flying_robots_(BFRs)">Biomimetic flying robots (BFRs)</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=4" title="Edit section: Biomimetic flying robots (BFRs)">edit</a>]</div> <figure typeof="mw:File/Thumb"><a href="/wiki/File:Skybird.gif" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/4/41/Skybird.gif" decoding="async" width="210" height="156" class="mw-file-element" data-file-width="210" data-file-height="156" /></a><figcaption>Flapping wing BFR in motion</figcaption></figure> BFRs take inspiration from flying mammals, birds, or insects. BFRs can have flapping wings, which generate the lift and thrust, or they can be propeller actuated. BFRs with flapping wings have increased stroke efficiencies, increased maneuverability, and reduced energy consumption in comparison to propeller actuated BFRs.<a href="#cite_note-29">[29]</a> Mammal and bird inspired BFRs share similar flight characteristics and design considerations. For instance, both mammal and bird inspired BFRs minimize <a href="/wiki/Aeroelasticity#Flutter" title="Aeroelasticity">edge fluttering</a> and <a href="/wiki/Wingtip_vortices" title="Wingtip vortices">pressure-induced wingtip curl</a> by increasing the rigidity of the wing edge and wingtips. Mammal and insect inspired BFRs can be impact resistant, making them useful in cluttered environments. Mammal inspired BFRs typically take inspiration from bats, but the flying squirrel has also inspired a prototype.<a href="#cite_note-:2-30">[30]</a> Examples of bat inspired BFRs include Bat Bot<a href="#cite_note-31">[31]</a> and the DALER.<a href="#cite_note-:3-32">[32]</a> Mammal inspired BFRs can be designed to be multi-modal; therefore, they're capable of both flight and terrestrial movement. To reduce the impact of landing, shock absorbers can be implemented along the wings.<a href="#cite_note-:3-32">[32]</a> Alternatively, the BFR can pitch up and increase the amount of drag it experiences.<a href="#cite_note-:2-30">[30]</a> By increasing the drag force, the BFR will decelerate and minimize the impact upon grounding. Different land gait patterns can also be implemented.<a href="#cite_note-:2-30">[30]</a> <figure typeof="mw:File/Thumb"><a href="/wiki/File:Insectothopter.png" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/thumb/8/83/Insectothopter.png/193px-Insectothopter.png" decoding="async" width="193" height="175" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/8/83/Insectothopter.png 1.5x" data-file-width="244" data-file-height="221" /></a><figcaption>Dragonfly inspired BFR.</figcaption></figure> Bird inspired BFRs can take inspiration from raptors, gulls, and everything in-between. Bird inspired BFRs can be feathered to increase the angle of attack range over which the prototype can operate before stalling.<a href="#cite_note-:4-33">[33]</a> The wings of bird inspired BFRs allow for in-plane deformation, and the in-plane wing deformation can be adjusted to maximize flight efficiency depending on the flight gait.<a href="#cite_note-:4-33">[33]</a> An example of a raptor inspired BFR is the prototype by Savastano et al.<a href="#cite_note-34">[34]</a> The prototype has fully deformable flapping wings and is capable of carrying a payload of up to 0.8 kg while performing a parabolic climb, steep descent, and rapid recovery. The gull inspired prototype by Grant et al. accurately mimics the elbow and wrist rotation of gulls, and they find that lift generation is maximized when the elbow and wrist deformations are opposite but equal.<a href="#cite_note-35">[35]</a> Insect inspired BFRs typically take inspiration from beetles or dragonflies. An example of a beetle inspired BFR is the prototype by Phan and Park,<a href="#cite_note-36">[36]</a> and a dragonfly inspired BFR is the prototype by Hu et al.<a href="#cite_note-37">[37]</a> The flapping frequency of insect inspired BFRs are much higher than those of other BFRs; this is because of the <a href="/wiki/Insect_flight" title="Insect flight">aerodynamics of insect flight</a>.<a href="#cite_note-38">[38]</a> Insect inspired BFRs are much smaller than those inspired by mammals or birds, so they are more suitable for dense environments. The prototype by Phan and Park took inspiration from the rhinoceros beetle, so it can successfully continue flight even after a collision by deforming its hindwings. <div class="mw-heading mw-heading3"><h3 id="Biomimetic_architecture">Biomimetic architecture</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=5" title="Edit section: Biomimetic architecture">edit</a>]</div> Living beings have adapted to a constantly changing environment during evolution through mutation, recombination, and selection.<a href="#cite_note-:1-39">[39]</a> The core idea of the biomimetic philosophy is that nature's inhabitants including animals, plants, and microbes have the most experience in solving problems and have already found the most appropriate ways to last on planet Earth.<a href="#cite_note-40">[40]</a> Similarly, biomimetic architecture seeks solutions for building sustainability present in nature. While nature serves as a model, there are few examples of biomimetic architecture that aim to be nature positive.<a href="#cite_note-41">[41]</a> The 21st century has seen a ubiquitous waste of energy due to inefficient building designs, in addition to the over-utilization of energy during the operational phase of its life cycle.<a href="#cite_note-42">[42]</a> In parallel, recent advancements in fabrication techniques, computational imaging, and simulation tools have opened up new possibilities to mimic nature across different architectural scales.<a href="#cite_note-:1-39">[39]</a> As a result, there has been a rapid growth in devising innovative design approaches and solutions to counter energy problems. Biomimetic architecture is one of these multi-disciplinary approaches to <a href="/wiki/Sustainable_design" title="Sustainable design">sustainable design</a> that follows a set of principles rather than stylistic codes, going beyond using nature as inspiration for the aesthetic components of built form but instead seeking to use nature to solve problems of the building's functioning and saving energy. <div class="mw-heading mw-heading4"><h4 id="Characteristics">Characteristics</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=6" title="Edit section: Characteristics">edit</a>]</div> The term biomimetic architecture refers to the study and application of construction principles which are found in natural environments and species, and are translated into the design of sustainable solutions for architecture.<a href="#cite_note-:1-39">[39]</a> Biomimetic architecture uses nature as a model, measure and mentor for providing architectural solutions across scales, which are inspired by natural organisms that have solved similar problems in nature. Using nature as a measure refers to using an ecological standard of measuring sustainability, and efficiency of man-made innovations, while the term mentor refers to learning from natural principles and using biology as an inspirational source.<a href="#cite_note-Benyus_1997-18">[18]</a> Biomorphic architecture, also referred to as bio-decoration,<a href="#cite_note-:1-39">[39]</a> on the other hand, refers to the use of formal and geometric elements found in nature, as a source of inspiration for aesthetic properties in designed architecture, and may not necessarily have non-physical, or economic functions. A historic example of biomorphic architecture dates back to Egyptian, Greek and Roman cultures, using tree and plant forms in the ornamentation of structural columns.<a href="#cite_note-43">[43]</a> <div class="mw-heading mw-heading4"><h4 id="Procedures">Procedures</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=7" title="Edit section: Procedures">edit</a>]</div> Within biomimetic architecture, two basic procedures can be identified, namely, the bottom-up approach (biology push) and top-down approach (technology pull).<a href="#cite_note-44">[44]</a> The boundary between the two approaches is blurry with the possibility of transition between the two, depending on each individual case. Biomimetic architecture is typically carried out in interdisciplinary teams in which biologists and other natural scientists work in collaboration with engineers, material scientists, architects, designers, mathematicians and computer scientists. In the bottom-up approach, the starting point is a new result from basic biological research promising for biomimetic implementation. For example, developing a biomimetic material system after the quantitative analysis of the mechanical, physical, and chemical properties of a biological system. In the top-down approach, biomimetic innovations are sought for already existing developments that have been successfully established on the market. The cooperation focuses on the improvement or further development of an existing product. <div class="mw-heading mw-heading4"><h4 id="Examples">Examples</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=8" title="Edit section: Examples">edit</a>]</div> Researchers studied the <a href="/wiki/Termite" title="Termite">termite</a>'s ability to maintain virtually constant temperature and humidity in their <a href="/wiki/Termite_mound" class="mw-redirect" title="Termite mound">termite mounds</a> in Africa despite outside temperatures that vary from 1.5 to 40 °C (34.7 to 104.0 °F). Researchers initially scanned a termite mound and created 3-D images of the mound structure, which revealed construction that could influence human <a href="/wiki/Building_design" title="Building design">building design</a>. The <a href="/wiki/Eastgate_Centre,_Harare" title="Eastgate Centre, Harare">Eastgate Centre</a>, a mid-rise office complex in <a href="/wiki/Harare" title="Harare">Harare</a>, <a href="/wiki/Zimbabwe" title="Zimbabwe">Zimbabwe</a>,<a href="#cite_note-BI-45">[45]</a> stays cool via a passive cooling architecture that uses only 10% of the energy of a conventional building of the same size. <figure class="mw-default-size" typeof="mw:File/Thumb"><a href="/wiki/File:Co_op_Building_dual_facade.jpg" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/thumb/f/fe/Co_op_Building_dual_facade.jpg/220px-Co_op_Building_dual_facade.jpg" decoding="async" width="220" height="165" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/f/fe/Co_op_Building_dual_facade.jpg/330px-Co_op_Building_dual_facade.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/f/fe/Co_op_Building_dual_facade.jpg/440px-Co_op_Building_dual_facade.jpg 2x" data-file-width="1024" data-file-height="768" /></a><figcaption>A <a href="/wiki/Waagner-Biro" title="Waagner-Biro">Waagner-Biro</a> double-skin facade being assembled at <a href="/wiki/One_Angel_Square" title="One Angel Square">One Angel Square</a>, <a href="/wiki/Manchester" title="Manchester">Manchester</a>. The brown outer facade can be seen being assembled to the inner white facade via struts. These struts create a walkway between both 'skins' for ventilation, solar shading and maintenance.</figcaption></figure> Researchers in the <a href="/wiki/Sapienza_University_of_Rome" title="Sapienza University of Rome">Sapienza University of Rome</a> were inspired by the natural ventilation in termite mounds and designed a double façade that significantly cuts down over lit areas in a building. Scientists have imitated the porous nature of mound walls by designing a facade with double panels that was able to reduce heat gained by radiation and increase heat loss by convection in cavity between the two panels. The overall cooling load on the building's energy consumption was reduced by 15%.<a href="#cite_note-46">[46]</a> A similar inspiration was drawn from the porous walls of termite mounds to design a naturally ventilated façade with a small ventilation gap. This design of façade is able to induce air flow due to the <a href="/wiki/Venturi_effect" title="Venturi effect">Venturi effect</a> and continuously circulates rising air in the ventilation slot. Significant transfer of heat between the building's external wall surface and the air flowing over it was observed.<a href="#cite_note-47">[47]</a> The design is coupled with <a href="/wiki/Green_wall" title="Green wall">greening</a> of the façade. Green wall facilitates additional natural cooling via evaporation, respiration and transpiration in plants. The damp plant substrate further support the cooling effect.<a href="#cite_note-48">[48]</a> <figure class="mw-default-size" typeof="mw:File/Thumb"><a href="/wiki/File:Sepiolite-469730.jpg" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/thumb/a/af/Sepiolite-469730.jpg/220px-Sepiolite-469730.jpg" decoding="async" width="220" height="165" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/a/af/Sepiolite-469730.jpg/330px-Sepiolite-469730.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/a/af/Sepiolite-469730.jpg/440px-Sepiolite-469730.jpg 2x" data-file-width="1024" data-file-height="768" /></a><figcaption>Sepiolite in solid form</figcaption></figure> Scientists in <a href="/wiki/Shanghai_University" title="Shanghai University">Shanghai University</a> were able to replicate the complex microstructure of clay-made conduit network in the mound to mimic the excellent humidity control in mounds. They proposed a porous humidity control material (HCM) using <a href="/wiki/Sepiolite" title="Sepiolite">sepiolite</a> and <a href="/wiki/Calcium_chloride" title="Calcium chloride">calcium chloride</a> with water vapor adsorption-desorption content at 550 grams per meter squared. Calcium chloride is a <a href="/wiki/Desiccant" title="Desiccant">desiccant</a> and improves the water vapor adsorption-desorption property of the Bio-HCM. The proposed bio-HCM has a regime of interfiber mesopores which acts as a mini reservoir. The flexural strength of the proposed material was estimated to be 10.3 MPa using computational simulations.<a href="#cite_note-49">[49]</a><a href="#cite_note-50">[50]</a> In structural engineering, the Swiss Federal Institute of Technology (<a href="/wiki/%C3%89cole_Polytechnique_F%C3%A9d%C3%A9rale_de_Lausanne" title="École Polytechnique Fédérale de Lausanne">EPFL</a>) has incorporated biomimetic characteristics in an adaptive deployable "tensegrity" bridge. The bridge can carry out self-diagnosis and self-repair.<a href="#cite_note-korkmaz-51">[51]</a> The <a href="/wiki/Phyllotaxy" class="mw-redirect" title="Phyllotaxy">arrangement of leaves on a plant</a> has been adapted for better solar power collection.<a href="#cite_note-52">[52]</a> Analysis of the elastic deformation happening when a pollinator lands on the sheath-like perch part of the flower <a href="/wiki/Strelitzia_reginae" title="Strelitzia reginae">Strelitzia reginae</a> (known as <a href="/wiki/Strelitzia" title="Strelitzia">bird-of-paradise</a> flower) has inspired architects and scientists from the <a href="/wiki/University_of_Freiburg" title="University of Freiburg">University of Freiburg</a> and <a href="/wiki/University_of_Stuttgart" title="University of Stuttgart">University of Stuttgart</a> to create hingeless shading systems that can react to their environment. These bio-inspired products are sold under the name Flectofin.<a href="#cite_note-53">[53]</a><a href="#cite_note-54">[54]</a> Other hingeless bioinspired systems include Flectofold.<a href="#cite_note-55">[55]</a> Flectofold has been inspired from the trapping system developed by the carnivorous plant <a href="/wiki/Aldrovanda_vesiculosa" title="Aldrovanda vesiculosa">Aldrovanda vesiculosa</a>. <div class="mw-heading mw-heading3"><h3 id="Structural_materials">Structural materials</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=9" title="Edit section: Structural materials">edit</a>]</div> There is a great need for new structural materials that are light weight but offer exceptional combinations of <a href="/wiki/Stiffness" title="Stiffness">stiffness</a>, strength, and <a href="/wiki/Toughness" title="Toughness">toughness</a>. Such materials would need to be manufactured into bulk materials with complex shapes at high volume and low cost and would serve a variety of fields such as construction, transportation, energy storage and conversion.<a href="#cite_note-56">[56]</a> In a classic design problem, strength and toughness are more likely to be mutually exclusive, i.e., strong materials are brittle and tough materials are weak. However, natural materials with complex and hierarchical material gradients that span from <a href="/wiki/Nanoscopic_scale" class="mw-redirect" title="Nanoscopic scale">nano</a>- to macro-scales are both strong and tough. Generally, most natural materials utilize limited chemical components but complex material architectures that give rise to exceptional mechanical properties. Understanding the highly diverse and multi functional biological materials and discovering approaches to replicate such structures will lead to advanced and more efficient technologies. <a href="/wiki/Bone" title="Bone">Bone</a>, <a href="/wiki/Nacre" title="Nacre">nacre</a> (abalone shell), teeth, the dactyl clubs of stomatopod shrimps and bamboo are great examples of damage tolerant materials.<a href="#cite_note-materials-57">[57]</a> The exceptional resistance to <a href="/wiki/Fracture" title="Fracture">fracture</a> of bone is due to complex deformation and toughening mechanisms that operate at spanning different size scales — nanoscale structure of protein molecules to macroscopic physiological scale.<a href="#cite_note-58">[58]</a> <figure class="mw-default-size" typeof="mw:File/Thumb"><a href="/wiki/File:Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG" class="mw-file-description"><img alt="" src="//upload.wikimedia.org/wikipedia/commons/thumb/8/8a/Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG/220px-Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG" decoding="async" width="220" height="140" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/8/8a/Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG/330px-Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/8/8a/Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG/440px-Bruchfl%C3%A4che_eines_Perlmuttst%C3%BCcks.JPG 2x" data-file-width="766" data-file-height="488" /></a><figcaption>Electron microscopy image of a fractured surface of <a href="/wiki/Nacre" title="Nacre">nacre</a></figcaption></figure><a href="/wiki/Nacre" title="Nacre">Nacre</a> exhibits similar mechanical properties however with rather simpler structure. Nacre shows a brick and mortar like structure with thick mineral layer (0.2–0.9 μm) of closely packed aragonite structures and thin organic matrix (~20 nm).<a href="#cite_note-59">[59]</a> While thin films and micrometer sized samples that mimic these structures are already produced, successful production of bulk biomimetic structural materials is yet to be realized. However, numerous processing techniques have been proposed for producing nacre like materials.<a href="#cite_note-materials-57">[57]</a> <a href="/wiki/Pavement_cells" title="Pavement cells">Pavement cells</a>, epidermal cells on the surface of plant leaves and petals, often form wavy interlocking patterns resembling jigsaw puzzle pieces and are shown to enhance the fracture toughness of leaves, key to plant survival.<a href="#cite_note-auto1-60">[60]</a> Their pattern, replicated in laser-engraved <a href="/wiki/Poly(methyl_methacrylate)" title="Poly(methyl methacrylate)">Poly(methyl methacrylate)</a> samples, was also demonstrated to lead to increased fracture toughness. It is suggested that the arrangement and patterning of cells play a role in managing crack propagation in tissues.<a href="#cite_note-auto1-60">[60]</a> <a href="/wiki/Biomineralization" title="Biomineralization">Biomorphic mineralization</a> is a technique that produces materials with morphologies and structures resembling those of natural living organisms by using bio-structures as templates for mineralization. Compared to other methods of material production, biomorphic mineralization is facile, environmentally benign and economic.<a href="#cite_note-Tong-61">[61]</a> <a href="/wiki/Freeze-casting" title="Freeze-casting">Freeze casting</a> (ice templating), an inexpensive method to mimic natural layered structures, was employed by researchers at Lawrence Berkeley National Laboratory to create alumina-Al-Si and IT HAP-epoxy layered composites that match the mechanical properties of bone with an equivalent mineral/organic content.<a href="#cite_note-62">[62]</a> Various further studies<a href="#cite_note-63">[63]</a><a href="#cite_note-64">[64]</a><a href="#cite_note-65">[65]</a><a href="#cite_note-66">[66]</a> also employed similar methods to produce high strength and high toughness composites involving a variety of constituent phases. Recent studies demonstrated production of cohesive and self supporting macroscopic tissue constructs that mimic <a href="/wiki/Tissue_(biology)" title="Tissue (biology)">living tissues</a> by printing tens of thousands of heterologous picoliter droplets in software-defined, 3D millimeter-scale geometries.<a href="#cite_note-67">[67]</a> Efforts are also taken up to mimic the design of nacre in artificial <a href="/wiki/Composite_material" title="Composite material">composite materials</a> using fused deposition modelling<a href="#cite_note-68">[68]</a> and the helicoidal structures of <a href="/wiki/Mantis_shrimp" title="Mantis shrimp">stomatopod</a> clubs in the fabrication of high performance <a href="/wiki/Carbon_fibers" title="Carbon fibers">carbon fiber</a>-epoxy composites.<a href="#cite_note-69">[69]</a> Various established and novel additive manufacturing technologies like PolyJet printing, direct ink writing, 3D magnetic printing, multi-material magnetically assisted 3D printing and magnetically assisted <a href="/wiki/Slipcasting" class="mw-redirect" title="Slipcasting">slip casting</a> have also been utilized to mimic the complex micro-scale architectures of natural materials and provide huge scope for future research.<a href="#cite_note-70">[70]</a><a href="#cite_note-71">[71]</a><a href="#cite_note-72">[72]</a> <a href="/wiki/Spider" title="Spider">Spider</a> silk is tougher than <a href="/wiki/Kevlar" title="Kevlar">Kevlar</a> used in <a href="/wiki/Ballistic_vest" class="mw-redirect" title="Ballistic vest">bulletproof vests</a>.<a href="#cite_note-73">[73]</a> Engineers could in principle use such a material, if it could be reengineered to have a long enough life, for parachute lines, suspension bridge cables, artificial ligaments for medicine, and other purposes.<a href="#cite_note-Benyus_1997-18">[18]</a> The self-sharpening teeth of many animals have been copied to make better cutting tools.<a href="#cite_note-74">[74]</a> New ceramics that exhibit giant electret hysteresis have also been realized.<a href="#cite_note-75">[75]</a> <div class="mw-heading mw-heading3"><h3 id="Neuronal_computers">Neuronal computers</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=10" title="Edit section: Neuronal computers">edit</a>]</div> <a href="/wiki/Neuromorphic" class="mw-redirect" title="Neuromorphic">Neuromorphic</a> computers and sensors are electrical devices that copy the structure and function of biological neurons in order to compute. One example of this is the <a href="/wiki/Event_camera" title="Event camera">event camera</a> in which only the pixels that receive a new signal update to a new state. All other pixels do not update until a signal is received.<a href="#cite_note-76">[76]</a> <div class="mw-heading mw-heading3"><h3 id="Self_healing-materials">Self healing-materials</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=11" title="Edit section: Self healing-materials">edit</a>]</div> In some biological systems, <a href="/wiki/Self-healing" title="Self-healing">self-healing</a> occurs via chemical releases at the site of fracture, which initiate a systemic response to transport repairing agents to the fracture site. This promotes autonomic healing.<a href="#cite_note-77">[77]</a> To demonstrate the use of micro-vascular networks for autonomic healing, researchers developed a microvascular coating–substrate architecture that mimics human skin.<a href="#cite_note-78">[78]</a> Bio-inspired self-healing structural color hydrogels that maintain the stability of an inverse opal structure and its resultant structural colors were developed.<a href="#cite_note-79">[79]</a> A self-repairing membrane inspired by rapid self-sealing processes in plants was developed for inflatable lightweight structures such as rubber boats or Tensairity constructions. The researchers applied a thin soft cellular polyurethane foam coating on the inside of a fabric substrate, which closes the crack if the membrane is punctured with a spike.<a href="#cite_note-80">[80]</a> <a href="/wiki/Self-healing_material" title="Self-healing material">Self-healing materials</a>, <a href="/wiki/Polymer" title="Polymer">polymers</a> and <a href="/wiki/Composite_material" title="Composite material">composite materials</a> capable of mending cracks have been produced based on biological materials.<a href="#cite_note-81">[81]</a> The self-healing properties may also be achieved by the breaking and reforming of hydrogen bonds upon cyclical stress of the material.<a href="#cite_note-82">[82]</a> <div class="mw-heading mw-heading3"><h3 id="Surfaces">Surfaces</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=12" title="Edit section: Surfaces">edit</a>]</div> <a href="/wiki/Sharklet_(material)" title="Sharklet (material)">Surfaces</a> that recreate the properties of <a href="/wiki/Dermal_denticle#Shark_skin" class="mw-redirect" title="Dermal denticle">shark skin</a> are intended to enable more efficient movement through water. Efforts have been made to produce fabric that emulates shark skin.<a href="#cite_note-williams-22">[22]</a><a href="#cite_note-83">[83]</a> <a href="/wiki/Surface_tension_biomimetics" title="Surface tension biomimetics">Surface tension biomimetics</a> are being researched for technologies such as <a href="/wiki/Hydrophobic" class="mw-redirect" title="Hydrophobic">hydrophobic</a> or <a href="/wiki/Hydrophilic" class="mw-redirect" title="Hydrophilic">hydrophilic</a> coatings and microactuators.<a href="#cite_note-84">[84]</a><a href="#cite_note-85">[85]</a><a href="#cite_note-86">[86]</a><a href="#cite_note-87">[87]</a><a href="#cite_note-88">[88]</a> <div class="mw-heading mw-heading3"><h3 id="Adhesion">Adhesion</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=13" title="Edit section: Adhesion">edit</a>]</div> <div class="mw-heading mw-heading4"><h4 id="Wet_adhesion">Wet adhesion</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=14" title="Edit section: Wet adhesion">edit</a>]</div> Some amphibians, such as tree and <a href="/wiki/Torrent_frog" title="Torrent frog">torrent frogs</a> and arboreal <a href="/wiki/Salamander" title="Salamander">salamanders</a>, are able to attach to and move over wet or even flooded environments without falling. This kind of organisms have toe pads which are permanently wetted by mucus secreted from glands that open into the channels between epidermal cells. They attach to mating surfaces by wet adhesion and they are capable of climbing on wet rocks even when water is flowing over the surface.<a href="#cite_note-:5-4">[4]</a> <a href="/wiki/Tire" title="Tire">Tire</a> treads have also been inspired by the toe pads of <a href="/wiki/Tree_frog" title="Tree frog">tree frogs</a>.<a href="#cite_note-89">[89]</a> 3D printed hierarchical surface models, inspired from tree and torrent frogs toe pad design, have been observed to produce better wet traction than conventional tire design.<a href="#cite_note-90">[90]</a> Marine <a href="/wiki/Mussel" title="Mussel">mussels</a> can stick easily and efficiently to surfaces underwater under the harsh conditions of the ocean. Mussels use strong filaments to adhere to rocks in the inter-tidal zones of wave-swept beaches, preventing them from being swept away in strong sea currents. Mussel foot proteins attach the filaments to rocks, boats and practically any surface in nature including other mussels. These proteins contain a mix of <a href="/wiki/Amino_acid" title="Amino acid">amino acid</a> residues which has been adapted specifically for <a href="/wiki/Adhesive" title="Adhesive">adhesive</a> purposes. Researchers from the University of California Santa Barbara borrowed and simplified chemistries that the mussel foot uses to overcome this engineering challenge of wet adhesion to create copolyampholytes,<a href="#cite_note-91">[91]</a> and one-component adhesive systems<a href="#cite_note-92">[92]</a> with potential for employment in <a href="/wiki/Nanofabrication" class="mw-redirect" title="Nanofabrication">nanofabrication</a> protocols. Other research has proposed adhesive glue from <a href="/wiki/Mussel" title="Mussel">mussels</a>. <div class="mw-heading mw-heading4"><h4 id="Dry_adhesion">Dry adhesion</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=15" title="Edit section: Dry adhesion">edit</a>]</div> Leg attachment pads of several animals, including many insects (e.g., <a href="/wiki/Beetle" title="Beetle">beetles</a> and <a href="/wiki/Fly" title="Fly">flies</a>), <a href="/wiki/Spider" title="Spider">spiders</a> and <a href="/wiki/Lizard" title="Lizard">lizards</a> (e.g., <a href="/wiki/Gecko" title="Gecko">geckos</a>), are capable of attaching to a variety of surfaces and are used for locomotion, even on vertical walls or across ceilings. Attachment systems in these organisms have similar structures at their terminal elements of contact, known as <a href="/wiki/Seta" title="Seta">setae</a>. Such biological examples have offered inspiration in order to produce climbing robots,[<a href="/wiki/Wikipedia:Citation_needed" title="Wikipedia:Citation needed">citation needed</a>] boots and tape.<a href="#cite_note-93">[93]</a> <a href="/wiki/Synthetic_setae" title="Synthetic setae">Synthetic setae</a> have also been developed for the production of dry adhesives. <div class="mw-heading mw-heading3"><h3 id="Liquid_repellency">Liquid repellency</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=16" title="Edit section: Liquid repellency">edit</a>]</div> Superliquiphobicity refers to a remarkable surface property where a solid surface exhibits an extreme aversion to liquids, causing droplets to bead up and roll off almost instantaneously upon contact. This behavior arises from intricate surface textures and interactions at the nanoscale, effectively preventing liquids from wetting or adhering to the surface. The term "superliquiphobic" is derived from "<a href="/wiki/Ultrahydrophobicity" title="Ultrahydrophobicity">superhydrophobic</a>," which describes surfaces highly resistant to water. Superliquiphobic surfaces go beyond water repellency and display repellent characteristics towards a wide range of liquids, including those with very low surface tension or containing surfactants.<a href="#cite_note-:6-2">[2]</a><a href="#cite_note-94">[94]</a> Superliquiphobicity, a remarkable phenomenon, emerges when a solid surface possesses minute roughness, forming interfaces with droplets through wetting while altering contact angles. This behavior hinges on the roughness factor (Rf), defining the ratio of solid-liquid area to its projection, influencing contact angles. On rough surfaces, non-wetting liquids give rise to composite solid-liquid-air interfaces, their contact angles determined by the distribution of wet and air-pocket areas. The achievement of superliquiphobicity involves increasing the fractional flat geometrical area (fLA) and Rf, leading to surfaces that actively repel liquids.<a href="#cite_note-95">[95]</a><a href="#cite_note-96">[96]</a> The inspiration for crafting such surfaces draws from nature's ingenuity, prominently illustrated by the renowned "<a href="/wiki/Lotus_effect" title="Lotus effect">lotus effect</a>". Leaves of water-repellent plants, like the lotus, exhibit inherent hierarchical structures featuring nanoscale wax-coated formations.<a href="#cite_note-97">[97]</a><a href="#cite_note-98">[98]</a> These structures lead to superhydrophobicity, where water droplets perch on trapped air bubbles, resulting in high contact angles and minimal contact angle hysteresis. This natural example guides the development of superliquiphobic surfaces, capitalizing on re-entrant geometries that can repel low surface tension liquids and achieve near-zero contact angles.<a href="#cite_note-99">[99]</a> Creating superliquiphobic surfaces involves pairing re-entrant geometries with low surface energy materials, such as fluorinated substances. These geometries include overhangs that widen beneath the surface, enabling repellency even for minimal contact angles. Researchers have successfully fabricated various re-entrant geometries, offering a pathway for practical applications in diverse fields. These surfaces find utility in self-cleaning, anti-icing, anti-fogging, antifouling, and more, presenting innovative solutions to challenges in biomedicine, desalination, and energy conversion. In essence, superliquiphobicity, inspired by natural models like the lotus leaf, capitalizes on re-entrant geometries and surface properties to create interfaces that actively repel liquids. These surfaces hold immense promise across a range of applications, promising enhanced functionality and performance in various technological and industrial contexts. <div class="mw-heading mw-heading3"><h3 id="Optics">Optics</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=17" title="Edit section: Optics">edit</a>]</div> <style data-mw-deduplicate="TemplateStyles:r1236090951">.mw-parser-output .hatnote{font-style:italic}.mw-parser-output div.hatnote{padding-left:1.6em;margin-bottom:0.5em}.mw-parser-output .hatnote i{font-style:normal}.mw-parser-output .hatnote+link+.hatnote{margin-top:-0.5em}@media print{body.ns-0 .mw-parser-output .hatnote{display:none!important}}</style><div role="note" class="hatnote navigation-not-searchable">Further information: <a href="/wiki/Structural_coloration" title="Structural coloration">Structural coloration</a>, <a href="/wiki/Patterns_in_nature" title="Patterns in nature">Patterns in nature</a>, and <a href="/wiki/Bio-inspired_photonics" title="Bio-inspired photonics">Bio-inspired photonics</a></div> <a href="/wiki/Biomimetic_material" title="Biomimetic material">Biomimetic materials</a> are gaining increasing attention in the field of <a href="/wiki/Optics" title="Optics">optics</a> and <a href="/wiki/Photonics" title="Photonics">photonics</a>. There are still little known <a href="/wiki/Bio-inspired_photonics" title="Bio-inspired photonics">bioinspired or biomimetic products</a> involving the photonic properties of plants or animals. However, understanding how nature designed such optical materials from biological resources is a current field of research. <figure class="mw-default-size mw-halign-right" typeof="mw:File/Thumb"><a href="/wiki/File:Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_(diameter_3.5cm)..jpg" class="mw-file-description"><img src="//upload.wikimedia.org/wikipedia/commons/thumb/b/bf/Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_%28diameter_3.5cm%29..jpg/220px-Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_%28diameter_3.5cm%29..jpg" decoding="async" width="220" height="220" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/b/bf/Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_%28diameter_3.5cm%29..jpg/330px-Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_%28diameter_3.5cm%29..jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/b/bf/Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_%28diameter_3.5cm%29..jpg/440px-Macroscopic_picture_of_a_film_of_cellulose_nanocrystal_suspension_cast_on_a_Petri_dish_%28diameter_3.5cm%29..jpg 2x" data-file-width="2976" data-file-height="2976" /></a><figcaption>Macroscopic picture of a film of cellulose nanocrystal suspension cast on a <a href="/wiki/Petri_dish" title="Petri dish">Petri dish</a> (diameter: 3.5cm)</figcaption></figure> <div class="mw-heading mw-heading4"><h4 id="Inspiration_from_fruits_and_plants">Inspiration from fruits and plants</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=18" title="Edit section: Inspiration from fruits and plants">edit</a>]</div> One source of biomimetic inspiration is from <a href="/wiki/Plant" title="Plant">plants</a>. Plants have proven to be concept generations for the following functions; re(action)-coupling, self (adaptability), self-repair, and energy-autonomy. As plants do not have a centralized decision making unit (i.e. a brain), most plants have a decentralized autonomous system in various organs and tissues of the plant. Therefore, they react to multiple stimulus such as light, heat, and humidity.<a href="#cite_note-journals.sagepub.com-100">[100]</a> One example is the carnivorous plant species <a href="/wiki/Dionaea_muscipula" class="mw-redirect" title="Dionaea muscipula">Dionaea muscipula</a> (Venus flytrap). For the last 25 years, there has been research focus on the motion principles of the plant to develop AVFT (artificial Venus flytrap robots). Through the movement during prey capture, the plant inspired soft robotic motion systems. The fast snap buckling (within 100–300 ms) of the trap closure movement is initiated when prey triggers the hairs of the plant within a certain time (twice within 20 s). AVFT systems exist, in which the trap closure movements are actuated via magnetism, electricity, pressurized air, and temperature changes.<a href="#cite_note-journals.sagepub.com-100">[100]</a> Another example of mimicking plants, is the <a href="/wiki/Pollia_condensata" title="Pollia condensata">Pollia condensata</a>, also known as the marble berry. The chiral <a href="/wiki/Self-assembly" title="Self-assembly">self-assembly</a> of cellulose inspired by the <a href="/wiki/Pollia_condensata" title="Pollia condensata">Pollia condensata</a> berry has been exploited to make optically active films.<a href="#cite_note-101">[101]</a><a href="#cite_note-102">[102]</a> Such films are made from cellulose which is a biodegradable and biobased resource obtained from wood or cotton. The structural colours can potentially be everlasting and have more vibrant colour than the ones obtained from chemical absorption of light. <a href="/wiki/Pollia_condensata" title="Pollia condensata">Pollia condensata</a> is not the only fruit showing a structural coloured skin; iridescence is also found in berries of other species such as <a href="/wiki/Margaritaria_nobilis" title="Margaritaria nobilis">Margaritaria nobilis</a>.<a href="#cite_note-103">[103]</a> These fruits show <a href="/wiki/Iridescence" title="Iridescence">iridescent</a> colors in the blue-green region of the visible spectrum which gives the fruit a strong metallic and shiny visual appearance.<a href="#cite_note-:0-104">[104]</a> The structural colours come from the organisation of cellulose chains in the fruit's <a href="/wiki/Fruit_anatomy" class="mw-redirect" title="Fruit anatomy">epicarp</a>, a part of the fruit skin.<a href="#cite_note-:0-104">[104]</a> Each cell of the epicarp is made of a multilayered envelope that behaves like a <a href="/wiki/Bragg_reflector" class="mw-redirect" title="Bragg reflector">Bragg reflector</a>. However, the light which is reflected from the skin of these fruits is not polarised unlike the one arising from man-made replicates obtained from the self-assembly of cellulose nanocrystals into helicoids, which only reflect left-handed <a href="/wiki/Circular_polarization" title="Circular polarization">circularly polarised light</a>.<a href="#cite_note-105">[105]</a> The fruit of <a href="/wiki/Elaeocarpus_angustifolius" title="Elaeocarpus angustifolius">Elaeocarpus angustifolius</a> also show structural colour that come arises from the presence of specialised cells called iridosomes which have layered structures.<a href="#cite_note-:0-104">[104]</a> Similar iridosomes have also been found in <a href="/wiki/Delarbrea" title="Delarbrea">Delarbrea</a> michieana fruits.<a href="#cite_note-:0-104">[104]</a> In plants, multi layer structures can be found either at the surface of the leaves (on top of the epidermis), such as in <a href="/wiki/Selaginella_willdenowii" title="Selaginella willdenowii">Selaginella willdenowii</a><a href="#cite_note-:0-104">[104]</a> or within specialized intra-cellular <a href="/wiki/Organelle" title="Organelle">organelles</a>, the so-called iridoplasts, which are located inside the cells of the upper epidermis.<a href="#cite_note-:0-104">[104]</a> For instance, the rain forest plants Begonia pavonina have iridoplasts located inside the epidermal cells.<a href="#cite_note-:0-104">[104]</a> Structural colours have also been found in several algae, such as in the red alga <a href="/wiki/Chondrus_crispus" title="Chondrus crispus">Chondrus crispus</a> (Irish Moss).<a href="#cite_note-106">[106]</a> <div class="mw-heading mw-heading4"><h4 id="Inspiration_from_animals">Inspiration from animals</h4>[<a href="/w/index.php?title=Biomimetics&action=edit&section=19" title="Edit section: Inspiration from animals">edit</a>]</div> <figure class="mw-default-size" typeof="mw:File/Thumb"><a href="/wiki/File:Morpho_didius_Male_Dos_MHNT.jpg" class="mw-file-description"><img alt="Morpho butterfly." src="//upload.wikimedia.org/wikipedia/commons/thumb/e/ee/Morpho_didius_Male_Dos_MHNT.jpg/220px-Morpho_didius_Male_Dos_MHNT.jpg" decoding="async" width="220" height="164" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/e/ee/Morpho_didius_Male_Dos_MHNT.jpg/330px-Morpho_didius_Male_Dos_MHNT.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/e/ee/Morpho_didius_Male_Dos_MHNT.jpg/440px-Morpho_didius_Male_Dos_MHNT.jpg 2x" data-file-width="5410" data-file-height="4032" /></a><figcaption>The vibrant blue color of <a href="/wiki/Morpho_(genus)" title="Morpho (genus)">Morpho</a> butterfly due to <a href="/wiki/Structural_coloration" title="Structural coloration">structural coloration</a> has been mimicked by a variety of technologies.</figcaption></figure> <a href="/wiki/Structural_coloration" title="Structural coloration">Structural coloration</a> produces the rainbow colours of <a href="/wiki/Soap_bubble" title="Soap bubble">soap bubbles</a>, butterfly wings and many beetle scales.<a href="#cite_note-107">[107]</a><a href="#cite_note-108">[108]</a> Phase-separation has been used to fabricate ultra-<a href="/wiki/White" title="White">white</a> <a href="/wiki/Scattering" title="Scattering">scattering</a> membranes from <a href="/wiki/Polymethylmethacrylate" class="mw-redirect" title="Polymethylmethacrylate">polymethylmethacrylate</a>, mimicking the <a href="/wiki/Beetle" title="Beetle">beetle</a> <a href="/wiki/Cyphochilus" title="Cyphochilus">Cyphochilus</a>.<a href="#cite_note-109">[109]</a> <a href="/wiki/Light-emitting_diode" title="Light-emitting diode">LED</a> lights can be designed to mimic the patterns of scales on <a href="/wiki/Firefly" title="Firefly">fireflies</a>' abdomens, improving their efficiency.<a href="#cite_note-110">[110]</a> <a href="/wiki/Morpho_(genus)" title="Morpho (genus)">Morpho</a> butterfly wings are structurally coloured to produce a vibrant blue that does not vary with angle.<a href="#cite_note-Ball-111">[111]</a> This effect can be mimicked by a variety of technologies.<a href="#cite_note-112">[112]</a> <a href="/wiki/Lotus_Cars" title="Lotus Cars">Lotus Cars</a> claim to have developed a paint that mimics the Morpho butterfly's structural blue colour.<a href="#cite_note-113">[113]</a> In 2007, <a href="/wiki/Qualcomm" title="Qualcomm">Qualcomm</a> commercialised an <a href="/wiki/Interferometric_modulator_display" title="Interferometric modulator display">interferometric modulator display</a> technology, "Mirasol", using Morpho-like optical interference.<a href="#cite_note-114">[114]</a> In 2010, the dressmaker Donna Sgro made a dress from <a href="/wiki/Teijin" title="Teijin">Teijin Fibers</a>' <a href="/wiki/Morphotex" class="mw-redirect" title="Morphotex">Morphotex</a>, an undyed fabric woven from structurally coloured fibres, mimicking the microstructure of Morpho butterfly wing scales.<a href="#cite_note-115">[115]</a><a href="#cite_note-116">[116]</a><a href="#cite_note-117">[117]</a><a href="#cite_note-118">[118]</a><a href="#cite_note-119">[119]</a> <a href="/wiki/Canon_Inc." title="Canon Inc.">Canon Inc.</a>'s SubWavelength structure Coating uses wedge-shaped structures the size of the wavelength of visible light. The wedge-shaped structures cause a continuously changing refractive index as light travels through the coating, significantly reducing <a href="/wiki/Lens_flare" title="Lens flare">lens flare</a>. This imitates the structure of a moth's eye.<a href="#cite_note-120">[120]</a><a href="#cite_note-121">[121]</a> Notable figures such as the Wright Brothers and Leonardo da Vinci attempted to replicate the flight observed in birds.<a href="#cite_note-122">[122]</a> In an effort to reduce aircraft noise researchers have looked to the leading edge of owl feathers, which have an array of small finlets or <a href="/wiki/Rachis" title="Rachis">rachis</a> adapted to disperse aerodynamic pressure and provide nearly silent flight to the bird.<a href="#cite_note-123">[123]</a> <div class="mw-heading mw-heading3"><h3 id="Agricultural_systems">Agricultural systems</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=20" title="Edit section: Agricultural systems">edit</a>]</div> <a href="/wiki/Holistic_management" class="mw-redirect" title="Holistic management">Holistic planned grazing</a>, using fencing and/or <a href="/wiki/Herder" title="Herder">herders</a>, seeks to restore <a href="/wiki/Grasslands" class="mw-redirect" title="Grasslands">grasslands</a> by carefully planning movements of large <a href="/wiki/Herding_behavior" class="mw-redirect" title="Herding behavior">herds</a> of livestock to mimic the vast herds found in nature. The natural system being mimicked and used as a template is <a href="/wiki/Grazing" title="Grazing">grazing</a> animals concentrated by pack predators that must move on after eating, trampling, and manuring an area, and returning only after it has fully recovered. Its founder <a href="/wiki/Allan_Savory" title="Allan Savory">Allan Savory</a> and some others have claimed potential in building soil,<a href="#cite_note-124">[124]</a> increasing biodiversity, and reversing <a href="/wiki/Desertification" title="Desertification">desertification</a>.<a href="#cite_note-125">[125]</a> However, many researchers have disputed Savory's claim. Studies have often found that the method increases desertification instead of reducing it.<a href="#cite_note-126">[126]</a><a href="#cite_note-127">[127]</a> <div class="mw-heading mw-heading3"><h3 id="Other_uses">Other uses</h3>[<a href="/w/index.php?title=Biomimetics&action=edit&section=21" title="Edit section: Other uses">edit</a>]</div> Some <a href="/wiki/Air_conditioning" title="Air conditioning">air conditioning</a> systems use biomimicry in their fans to increase <a href="/wiki/Airflow" title="Airflow">airflow</a> while reducing power consumption.<a href="#cite_note-128">[128]</a><a href="#cite_note-129">[129]</a> Technologists like <a href="/wiki/Jas_Johl" class="mw-redirect" title="Jas Johl">Jas Johl</a> have speculated that the functionality of vacuole cells could be used to design highly adaptable security systems.<a href="#cite_note-auto-130">[130]</a> "The functionality of a vacuole, a biological structure that guards and promotes growth, illuminates the value of adaptability as a guiding principle for security." The functions and significance of vacuoles are fractal in nature, the organelle has no basic shape or size; its structure varies according to the requirements of the cell. Vacuoles not only isolate threats, contain what's necessary, export waste, maintain pressure—they also help the cell scale and grow. Johl argues these functions are necessary for any security system design.<a href="#cite_note-auto-130">[130]</a> The <a href="/wiki/500_Series_Shinkansen" title="500 Series Shinkansen">500 Series Shinkansen</a> used biomimicry to reduce energy consumption and noise levels while increasing passenger comfort.<a href="#cite_note-131">[131]</a> With reference to space travel, NASA and other firms have sought to develop swarm-type space drones inspired by bee behavioural patterns, and oxtapod terrestrial drones designed with reference to desert spiders.<a href="#cite_note-132">[132]</a> <div class="mw-heading mw-heading2"><h2 id="Other_technologies">Other technologies</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=22" title="Edit section: Other technologies">edit</a>]</div> <a href="/wiki/Protein_folding" title="Protein folding">Protein folding</a> has been used to control material formation for <a href="/wiki/Molecular_self-assembly" title="Molecular self-assembly">self-assembled functional nanostructures</a>.<a href="#cite_note-133">[133]</a> Polar bear fur has inspired the design of thermal collectors and clothing.<a href="#cite_note-134">[134]</a> The light refractive properties of the moth's eye has been studied to reduce the reflectivity of solar panels.<a href="#cite_note-135">[135]</a> <figure class="mw-default-size" typeof="mw:File/Thumb"><a href="/wiki/File:TobaccoMosaicVirus.jpg" class="mw-file-description"><img alt="Electron micrograph of rod shaped TMV particles" src="//upload.wikimedia.org/wikipedia/commons/thumb/4/47/TobaccoMosaicVirus.jpg/170px-TobaccoMosaicVirus.jpg" decoding="async" width="170" height="219" class="mw-file-element" srcset="//upload.wikimedia.org/wikipedia/commons/thumb/4/47/TobaccoMosaicVirus.jpg/255px-TobaccoMosaicVirus.jpg 1.5x, //upload.wikimedia.org/wikipedia/commons/thumb/4/47/TobaccoMosaicVirus.jpg/340px-TobaccoMosaicVirus.jpg 2x" data-file-width="900" data-file-height="1158" /></a><figcaption><a href="/wiki/Scanning_electron_micrograph" class="mw-redirect" title="Scanning electron micrograph">Scanning electron micrograph</a> of rod shaped <a href="/wiki/Tobacco_mosaic_virus" title="Tobacco mosaic virus">tobacco mosaic virus</a> particles</figcaption></figure> The <a href="/wiki/Bombardier_beetle" title="Bombardier beetle">Bombardier beetle</a>'s powerful repellent spray inspired a Swedish company to develop a "micro mist" spray technology, which is claimed to have a low carbon impact (compared to aerosol sprays). The beetle mixes chemicals and releases its spray via a steerable nozzle at the end of its abdomen, stinging and confusing the victim.<a href="#cite_note-136">[136]</a> Most <a href="/wiki/Virus" title="Virus">viruses</a> have an outer capsule 20 to 300 nm in diameter. Virus capsules are remarkably robust and capable of withstanding temperatures as high as 60 °C; they are stable across the <a href="/wiki/PH" title="PH">pH</a> range 2–10.<a href="#cite_note-Tong-61">[61]</a> Viral capsules can be used to create nano device components such as nanowires, nanotubes, and quantum dots. Tubular virus particles such as the <a href="/wiki/Tobacco_mosaic_virus" title="Tobacco mosaic virus">tobacco mosaic virus</a> (TMV) can be used as templates to create nanofibers and nanotubes, since both the inner and outer layers of the virus are charged surfaces which can induce nucleation of crystal growth. This was demonstrated through the production of <a href="/wiki/Platinum" title="Platinum">platinum</a> and <a href="/wiki/Gold" title="Gold">gold</a> nanotubes using TMV as a template.<a href="#cite_note-Dujardin-137">[137]</a> Mineralized virus particles have been shown to withstand various pH values by mineralizing the viruses with different materials such as silicon, <a href="/wiki/Lead(II)_sulfide" title="Lead(II) sulfide">PbS</a>, and <a href="/wiki/Cadmium_sulfide" title="Cadmium sulfide">CdS</a> and could therefore serve as a useful carriers of material.<a href="#cite_note-Shenton-138">[138]</a> A spherical plant virus called <a href="/wiki/Cowpea_chlorotic_mottle_virus" title="Cowpea chlorotic mottle virus">cowpea chlorotic mottle virus</a> (CCMV) has interesting expanding properties when exposed to environments of pH higher than 6.5. Above this pH, 60 independent pores with diameters about 2 nm begin to exchange substance with the environment. The structural transition of the viral capsid can be utilized in <a href="/wiki/Biomineralization" title="Biomineralization">Biomorphic mineralization</a> for selective uptake and deposition of minerals by controlling the solution pH. Possible applications include using the viral cage to produce uniformly shaped and sized quantum dot <a href="/wiki/Semiconductor" title="Semiconductor">semiconductor</a> nanoparticles through a series of pH washes. This is an alternative to the <a href="/wiki/Ferritin" title="Ferritin">apoferritin</a> cage technique currently used to synthesize uniform CdSe nanoparticles.<a href="#cite_note-139">[139]</a> Such materials could also be used for targeted drug delivery since particles release contents upon exposure to specific pH levels. <div class="mw-heading mw-heading2"><h2 id="See_also">See also</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=23" title="Edit section: See also">edit</a>]</div> <style data-mw-deduplicate="TemplateStyles:r1239009302">.mw-parser-output .portalbox{padding:0;margin:0.5em 0;display:table;box-sizing:border-box;max-width:175px;list-style:none}.mw-parser-output .portalborder{border:1px solid var(--border-color-base,#a2a9b1);padding:0.1em;background:var(--background-color-neutral-subtle,#f8f9fa)}.mw-parser-output .portalbox-entry{display:table-row;font-size:85%;line-height:110%;height:1.9em;font-style:italic;font-weight:bold}.mw-parser-output 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href="/wiki/Artificial_enzyme#Nanozymes" title="Artificial enzyme">Artificial enzyme § Nanozymes</a></li> <li><a href="/wiki/Bio-inspired_computing" title="Bio-inspired computing">Bio-inspired computing</a></li> <li><a href="/wiki/Bioinspiration_%26_Biomimetics" title="Bioinspiration & Biomimetics">Bioinspiration & Biomimetics</a></li> <li><a href="/wiki/Biomimetic_synthesis" title="Biomimetic synthesis">Biomimetic synthesis</a></li> <li><a href="/wiki/Carbon_sequestration" title="Carbon sequestration">Carbon sequestration</a></li> <li><a href="/wiki/Reverse_engineering" title="Reverse engineering">Reverse engineering</a></li> <li><a href="/wiki/Synthetic_biology" title="Synthetic biology">Synthetic biology</a></li></ul> <div class="mw-heading mw-heading2"><h2 id="References">References</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=24" title="Edit section: References">edit</a>]</div> <style data-mw-deduplicate="TemplateStyles:r1239543626">.mw-parser-output .reflist{margin-bottom:0.5em;list-style-type:decimal}@media screen{.mw-parser-output .reflist{font-size:90%}}.mw-parser-output .reflist .references{font-size:100%;margin-bottom:0;list-style-type:inherit}.mw-parser-output .reflist-columns-2{column-width:30em}.mw-parser-output .reflist-columns-3{column-width:25em}.mw-parser-output .reflist-columns{margin-top:0.3em}.mw-parser-output .reflist-columns ol{margin-top:0}.mw-parser-output .reflist-columns li{page-break-inside:avoid;break-inside:avoid-column}.mw-parser-output .reflist-upper-alpha{list-style-type:upper-alpha}.mw-parser-output .reflist-upper-roman{list-style-type:upper-roman}.mw-parser-output .reflist-lower-alpha{list-style-type:lower-alpha}.mw-parser-output .reflist-lower-greek{list-style-type:lower-greek}.mw-parser-output .reflist-lower-roman{list-style-type:lower-roman}</style><div class="reflist reflist-columns references-column-width" style="column-width: 28em;"> <ol class="references"> <li id="cite_note-1"><a href="#cite_ref-1">^</a> <style data-mw-deduplicate="TemplateStyles:r1238218222">.mw-parser-output cite.citation{font-style:inherit;word-wrap:break-word}.mw-parser-output .citation q{quotes:"\"""\"""'""'"}.mw-parser-output .citation:target{background-color:rgba(0,127,255,0.133)}.mw-parser-output .id-lock-free.id-lock-free a{background:url("//upload.wikimedia.org/wikipedia/commons/6/65/Lock-green.svg")right 0.1em center/9px no-repeat}.mw-parser-output .id-lock-limited.id-lock-limited a,.mw-parser-output .id-lock-registration.id-lock-registration a{background:url("//upload.wikimedia.org/wikipedia/commons/d/d6/Lock-gray-alt-2.svg")right 0.1em center/9px no-repeat}.mw-parser-output .id-lock-subscription.id-lock-subscription a{background:url("//upload.wikimedia.org/wikipedia/commons/a/aa/Lock-red-alt-2.svg")right 0.1em center/9px no-repeat}.mw-parser-output .cs1-ws-icon a{background:url("//upload.wikimedia.org/wikipedia/commons/4/4c/Wikisource-logo.svg")right 0.1em center/12px no-repeat}body:not(.skin-timeless):not(.skin-minerva) .mw-parser-output .id-lock-free a,body:not(.skin-timeless):not(.skin-minerva) .mw-parser-output .id-lock-limited a,body:not(.skin-timeless):not(.skin-minerva) .mw-parser-output .id-lock-registration a,body:not(.skin-timeless):not(.skin-minerva) .mw-parser-output .id-lock-subscription a,body:not(.skin-timeless):not(.skin-minerva) .mw-parser-output .cs1-ws-icon a{background-size:contain;padding:0 1em 0 0}.mw-parser-output .cs1-code{color:inherit;background:inherit;border:none;padding:inherit}.mw-parser-output .cs1-hidden-error{display:none;color:var(--color-error,#d33)}.mw-parser-output .cs1-visible-error{color:var(--color-error,#d33)}.mw-parser-output .cs1-maint{display:none;color:#085;margin-left:0.3em}.mw-parser-output .cs1-kern-left{padding-left:0.2em}.mw-parser-output .cs1-kern-right{padding-right:0.2em}.mw-parser-output .citation .mw-selflink{font-weight:inherit}@media screen{.mw-parser-output .cs1-format{font-size:95%}html.skin-theme-clientpref-night .mw-parser-output .cs1-maint{color:#18911f}}@media screen and (prefers-color-scheme:dark){html.skin-theme-clientpref-os .mw-parser-output .cs1-maint{color:#18911f}}</style><cite id="CITEREFJennifer_L._Hellier2015" class="citation book cs1">Jennifer L. Hellier, ed. (2015). The brain, the nervous system, and their diseases. 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Dober Publications. p. 33. <a href="/wiki/ISBN_(identifier)" class="mw-redirect" title="ISBN (identifier)">ISBN</a> <a href="/wiki/Special:BookSources/978-0-486-40297-0" title="Special:BookSources/978-0-486-40297-0"><bdi>978-0-486-40297-0</bdi></a>. <q>According to Wilbur, he and his brother discovered the birds' method of lateral control one day while observing a flight of pigeons. [...] 'Although we intently watched birds fly in a hope of learning something from them,' [Orville] wrote in 1941, 'I cannot think of anything that was first learned in that way.'</q></cite><span title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Abook&rft.genre=book&rft.btitle=Wilbur+and+Orville%3A+A+Biography+of+the+Wright+Brothers&rft.pages=33&rft.pub=Dober+Publications&rft.date=1998&rft.isbn=978-0-486-40297-0&rft.aulast=Howard&rft.aufirst=Fred&rfr_id=info%3Asid%2Fen.wikipedia.org%3ABiomimetics" class="Z3988"> </li> <li id="cite_note-Vincent2006-10">^ <a href="#cite_ref-Vincent2006_10-0">a</a> <a href="#cite_ref-Vincent2006_10-1">b</a> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1238218222"><cite id="CITEREFVincentBogatyreva,_Olga_A.Bogatyrev,_Nikolaj_R.Bowyer,_Adrian2006" class="citation journal cs1">Vincent, Julian F.V.; Bogatyreva, Olga A.; Bogatyrev, Nikolaj R.; Bowyer, Adrian; Pahl, Anja-Karina (21 August 2006). <a rel="nofollow" class="external text" href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1664643">"Biomimetics: its practice and theory"</a>. 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Schmitt, Como People of the Past"</a>. Connie Sullivan, Como History Article. Archived from <a rel="nofollow" class="external text" href="https://sites.google.com/a/comogreenvillage.info/como-history/home/people-of-the-past-documents/como-people-of-the-past/otto-h-schmitt">the original</a> on 2013-10-07. Retrieved 2012-09-25. <q>He developed the trigger by studying the nerves in squid and trying to engineer a device that replicated the natural system by which squid nerves propagate.</q></cite><span title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Abook&rft.genre=unknown&rft.btitle=Otto+H.+Schmitt%2C+Como+People+of+the+Past&rft.pub=Connie+Sullivan%2C+Como+History+Article&rft_id=https%3A%2F%2Fsites.google.com%2Fa%2Fcomogreenvillage.info%2Fcomo-history%2Fhome%2Fpeople-of-the-past-documents%2Fcomo-people-of-the-past%2Fotto-h-schmitt&rfr_id=info%3Asid%2Fen.wikipedia.org%3ABiomimetics" class="Z3988"> </li> <li id="cite_note-12"><a href="#cite_ref-12">^</a> In Appreciation, A Lifetime of Connections: Otto Herbert Schmitt, 1913 - 1998 </li> <li id="cite_note-vincent-2009-13"><a href="#cite_ref-vincent-2009_13-0">^</a> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1238218222"><cite id="CITEREFVincent2009" class="citation journal cs1">Vincent, Julian F. 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Third Int. Biophysics Congress. 1969. Some interesting and useful biomimetic transforms. p. 297. </li> <li id="cite_note-15"><a href="#cite_ref-15">^</a> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1238218222"><cite id="CITEREFSoanesHawker2008" class="citation book cs1">Soanes, Catherine; Hawker, Sara (2008). Compact Oxford English Dictionary. 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Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine. 223 (8): 919–939. <a href="/wiki/Doi_(identifier)" class="mw-redirect" title="Doi (identifier)">doi</a>:<a rel="nofollow" class="external text" href="https://doi.org/10.1243%2F09544119JEIM561">10.1243/09544119JEIM561</a>. <a href="/wiki/PMID_(identifier)" class="mw-redirect" title="PMID (identifier)">PMID</a> <a rel="nofollow" class="external text" href="https://pubmed.ncbi.nlm.nih.gov/20092091">20092091</a>. <a href="/wiki/S2CID_(identifier)" class="mw-redirect" title="S2CID (identifier)">S2CID</a> <a rel="nofollow" class="external text" href="https://api.semanticscholar.org/CorpusID:21895651">21895651</a>.</cite><span title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.jtitle=Proceedings+of+the+Institution+of+Mechanical+Engineers%2C+Part+H%3A+Journal+of+Engineering+in+Medicine&rft.atitle=Biomimetics+%E2%80%94+a+review&rft.volume=223&rft.issue=8&rft.pages=919-939&rft.date=2009&rft_id=https%3A%2F%2Fapi.semanticscholar.org%2FCorpusID%3A21895651%23id-name%3DS2CID&rft_id=info%3Apmid%2F20092091&rft_id=info%3Adoi%2F10.1243%2F09544119JEIM561&rft.aulast=Vincent&rft.aufirst=JFV&rfr_id=info%3Asid%2Fen.wikipedia.org%3ABiomimetics" class="Z3988"> </li> <li id="cite_note-17"><a href="#cite_ref-17">^</a> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1238218222"><cite id="CITEREFMerrill1982" class="citation thesis cs1">Merrill, Connie Lange (1982). <a rel="nofollow" class="external text" href="https://scholarship.rice.edu/handle/1911/15707">Biomimicry of the Dioxygen Active Site in the Copper Proteins Hemocyanin and Cytochrome Oxidase</a> (PhD thesis). 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Nano Letters. 3 (3): 413–417. <a href="/wiki/Bibcode_(identifier)" class="mw-redirect" title="Bibcode (identifier)">Bibcode</a>:<a rel="nofollow" class="external text" href="https://ui.adsabs.harvard.edu/abs/2003NanoL...3..413D">2003NanoL...3..413D</a>. <a href="/wiki/Doi_(identifier)" class="mw-redirect" title="Doi (identifier)">doi</a>:<a rel="nofollow" class="external text" href="https://doi.org/10.1021%2Fnl034004o">10.1021/nl034004o</a>.</cite><span title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.jtitle=Nano+Letters&rft.atitle=Organization+of+Metallic+Nanoparticles+Using+Tobacco+Mosaic+Virus+Templates&rft.volume=3&rft.issue=3&rft.pages=413-417&rft.date=2003-03&rft_id=info%3Adoi%2F10.1021%2Fnl034004o&rft_id=info%3Abibcode%2F2003NanoL...3..413D&rft.aulast=Dujardin&rft.aufirst=Erik&rft.au=Peet%2C+Charlie&rft.au=Stubbs%2C+Gerald&rft.au=Culver%2C+James+N.&rft.au=Mann%2C+Stephen&rfr_id=info%3Asid%2Fen.wikipedia.org%3ABiomimetics" class="Z3988"> </li> <li id="cite_note-Shenton-138"><a href="#cite_ref-Shenton_138-0">^</a> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1238218222"><cite id="CITEREFDouglasYoung1999" class="citation journal cs1">Douglas, Trevor; Young, Mark (June 1999). "Virus Particles as Templates for Materials Synthesis". Advanced Materials. 11 (8): 679–681. <a href="/wiki/Bibcode_(identifier)" class="mw-redirect" title="Bibcode (identifier)">Bibcode</a>:<a rel="nofollow" class="external text" href="https://ui.adsabs.harvard.edu/abs/1999AdM....11..679D">1999AdM....11..679D</a>. <a href="/wiki/Doi_(identifier)" class="mw-redirect" title="Doi (identifier)">doi</a>:<a rel="nofollow" class="external text" href="https://doi.org/10.1002%2F%28SICI%291521-4095%28199906%2911%3A8%3C679%3A%3AAID-ADMA679%3E3.0.CO%3B2-J">10.1002/(SICI)1521-4095(199906)11:8<679::AID-ADMA679>3.0.CO;2-J</a>.</cite><span title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.jtitle=Advanced+Materials&rft.atitle=Virus+Particles+as+Templates+for+Materials+Synthesis&rft.volume=11&rft.issue=8&rft.pages=679-681&rft.date=1999-06&rft_id=info%3Adoi%2F10.1002%2F%28SICI%291521-4095%28199906%2911%3A8%3C679%3A%3AAID-ADMA679%3E3.0.CO%3B2-J&rft_id=info%3Abibcode%2F1999AdM....11..679D&rft.aulast=Douglas&rft.aufirst=Trevor&rft.au=Young%2C+Mark&rfr_id=info%3Asid%2Fen.wikipedia.org%3ABiomimetics" class="Z3988"> </li> <li id="cite_note-139"><a href="#cite_ref-139">^</a> <link rel="mw-deduplicated-inline-style" href="mw-data:TemplateStyles:r1238218222"><cite id="CITEREFYamashitaHayashiHara2004" class="citation journal cs1">Yamashita, Ichiro; Hayashi, Junko; Hara, Masahiko (September 2004). "Bio-template Synthesis of Uniform CdSe Nanoparticles Using Cage-shaped Protein, Apoferritin". Chemistry Letters. 33 (9): 1158–1159. <a href="/wiki/Doi_(identifier)" class="mw-redirect" title="Doi (identifier)">doi</a>:<a rel="nofollow" class="external text" href="https://doi.org/10.1246%2Fcl.2004.1158">10.1246/cl.2004.1158</a>.</cite><span title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.jtitle=Chemistry+Letters&rft.atitle=Bio-template+Synthesis+of+Uniform+CdSe+Nanoparticles+Using+Cage-shaped+Protein%2C+Apoferritin&rft.volume=33&rft.issue=9&rft.pages=1158-1159&rft.date=2004-09&rft_id=info%3Adoi%2F10.1246%2Fcl.2004.1158&rft.aulast=Yamashita&rft.aufirst=Ichiro&rft.au=Hayashi%2C+Junko&rft.au=Hara%2C+Masahiko&rfr_id=info%3Asid%2Fen.wikipedia.org%3ABiomimetics" class="Z3988"> </li> </ol></div> <div class="mw-heading mw-heading2"><h2 id="Further_reading">Further reading</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=25" title="Edit section: Further reading">edit</a>]</div> <ul><li>Benyus, J. M. (2001). Along Came a Spider. Sierra, 86(4), 46–47.</li> <li>Hargroves, K. D. & Smith, M. H. (2006). Innovation inspired by nature Biomimicry. Ecos, (129), 27–28.</li> <li>Marshall, A. (2009). Wild Design: The Ecomimicry Project, North Atlantic Books: Berkeley.</li> <li>Passino, Kevin M. (2004). Biomimicry for Optimization, Control, and Automation. Springer.</li> <li>Pyper, W. (2006). Emulating nature: The rise of industrial ecology. Ecos, (129), 22–26.</li> <li>Smith, J. (2007). It's only natural. The Ecologist, 37(8), 52–55.</li> <li><a href="/wiki/D%27Arcy_Wentworth_Thompson" title="D'Arcy Wentworth Thompson">Thompson, D'Arcy W.</a>, On Growth and Form. Dover 1992 reprint of 1942 2nd ed. (1st ed., 1917).</li> <li><a href="/wiki/Steven_Vogel" title="Steven Vogel">Vogel, S.</a> (2000). Cats' Paws and Catapults: Mechanical Worlds of Nature and People. Norton.</li></ul> <div class="mw-heading mw-heading2"><h2 id="External_links">External links</h2>[<a href="/w/index.php?title=Biomimetics&action=edit&section=26" title="Edit section: External links">edit</a>]</div> <ul><li><a rel="nofollow" class="external text" href="https://www.youtube.com/user/MITbiomimetics">Biomimetics MIT</a></li> <li><a rel="nofollow" class="external text" href="https://web.archive.org/web/20081026212411/http://www.scribemedia.org/2008/10/22/float-like-a-butterfly-with-janine-benyus/">Sex, Velcro and Biomimicry with Janine Benyus</a></li> <li><a rel="nofollow" class="external text" href="http://www.ted.com/talks/janine_benyus_biomimicry_in_action.html">Janine Benyus: Biomimicry in Action</a> <a rel="nofollow" class="external text" href="https://web.archive.org/web/20100403043953/http://www.ted.com/talks/janine_benyus_biomimicry_in_action.html">Archived</a> 2010-04-03 at the <a href="/wiki/Wayback_Machine" title="Wayback Machine">Wayback Machine</a> from TED 2009</li> <li><a rel="nofollow" class="external text" href="https://web.archive.org/web/20080321210423/http://ngm.nationalgeographic.com/2008/04/biomimetics/clark-photography">Design by Nature - National Geographic</a></li> <li><a rel="nofollow" class="external text" href="http://www.ted.com/talks/michael_pawlyn_using_nature_s_genius_in_architecture.html">Michael Pawlyn: Using nature's genius in architecture</a> from TED 2010</li> <li><a rel="nofollow" class="external text" href="http://www.ted.com/talks/robert_full_on_engineering_and_evolution.html">Robert Full shows how human engineers can learn from animals' tricks</a> from TED 2002</li> <li><a rel="nofollow" class="external text" href="https://archive.today/20130102112425/http://www.eveningnews.com/blogs/2009/11/08/fastdraw/entry5577007.shtml">The Fast Draw: Biomimicry</a> from CBS News</li></ul> <div class="navbox-styles"><style data-mw-deduplicate="TemplateStyles:r1129693374">.mw-parser-output .hlist dl,.mw-parser-output .hlist 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title="Fermentation">Fermentation</a></li> <li><a href="/wiki/Gene" title="Gene">Gene</a></li> <li><a href="/wiki/Plasmid" title="Plasmid">Plasmid</a></li> <li><a href="/wiki/Protein" title="Protein">Protein</a></li> <li><a href="/wiki/Selective_breeding" title="Selective breeding">Selective breeding</a></li></ul> </div></td></tr><tr><th scope="row" class="navbox-group" style="width:1%">General concepts</th><td class="navbox-list-with-group navbox-list navbox-even" style="width:100%;padding:0"><div style="padding:0 0.25em"> <ul><li><a href="/wiki/Biotechnology_industrial_park" class="mw-redirect" title="Biotechnology industrial park">Biotechnology industrial park</a></li> <li><a href="/wiki/Biotechnology_products" class="mw-redirect" title="Biotechnology products">Biotechnology products</a></li> <li><a href="/wiki/Biotechnology_law" class="mw-redirect" title="Biotechnology law">Biotechnology law</a></li> <li><a href="/wiki/Green_Revolution" title="Green Revolution">Green Revolution</a></li> <li><a href="/wiki/Human_Genome_Project" title="Human Genome Project">Human Genome Project</a></li> <li><a href="/wiki/Pharmaceutical_company" class="mw-redirect" title="Pharmaceutical company">Pharmaceutical company</a></li></ul> </div></td></tr><tr><th scope="row" class="navbox-group" style="width:1%">Basic techniques and tools</th><td class="navbox-list-with-group navbox-list navbox-odd" style="width:100%;padding:0"><div style="padding:0 0.25em"></div><table class="nowraplinks navbox-subgroup" style="border-spacing:0"><tbody><tr><th scope="row" class="navbox-group" style="width:1%">Biology field</th><td class="navbox-list-with-group navbox-list navbox-odd" style="width:100%;padding:0"><div style="padding:0 0.25em"> <ul><li><a href="/wiki/Bioreactor" title="Bioreactor">Bioreactor</a></li> <li><a href="/wiki/Cell_culture" title="Cell culture">Cell culture</a></li> <li><a href="/wiki/Cultured_meat" title="Cultured meat">Cultured meat</a></li> <li><a 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title="Chromatography">Chromatography</a></li> <li><a href="/wiki/Kidney_dialysis" title="Kidney dialysis">Kidney dialysis</a></li> <li><a href="/wiki/Electrophoresis" title="Electrophoresis">Electrophoresis</a></li> <li><a href="/wiki/Extraction_(chemistry)" title="Extraction (chemistry)">Extraction</a></li> <li><a href="/wiki/Fed-batch_culture" title="Fed-batch culture">Fed Batch</a></li> <li><a href="/wiki/Filtration" title="Filtration">Filtration</a></li> <li><a href="/wiki/Plug_flow_reactor_model" title="Plug flow reactor model">PFR</a></li> <li><a href="/wiki/Sedimentation" title="Sedimentation">Sedimentation</a></li></ul> </div></td></tr></tbody></table><div></div></td></tr><tr><th scope="row" class="navbox-group" style="width:1%">Applications</th><td class="navbox-list-with-group navbox-list navbox-odd" style="width:100%;padding:0"><div style="padding:0 0.25em"> <ul><li><a href="/wiki/Animal_cell_culture" class="mw-redirect" title="Animal cell culture">Animal cell 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