Transdermal Drug
Delivery
Biosignal
Sensors
We adapt to
your business.
We adapt to
your business.
Mimetics' Tailored Process makes innovation through a customized approach. we provides sustainable and creative solutions through flexible product development, professional consulting, innovative partnership building, and customized product delivery.
Organ Tissue
Adhesive
Structural Color
List of Academic Papers
Lee, Jihyun, et al. "Artificial Octopus-Limb-Like Adhesive Patches for Cupping-Driven Transdermal Delivery with Nanoscale Control of Stratum Corneum." ACS nano (2024).
Lee, Yeon Soo, et al. "Softened double-layer octopus-like adhesive with high adaptability for enhanced dynamic dry and wet adhesion." Chemical Engineering Journal 468 (2023): 143792.
Song, Seo Won, et al. "Hierarchically porous hydrogel electrolyte prepared from interpenetrating polymer networks for flexible Zn-Air batteries." Energy Storage Materials 60 (2023): 102802.
Lee, Yeon Soo, et al. "A biodegradable bioinspired oil-coated adhesive film for enhanced wet adhesion." Surfaces and Interfaces 35 (2022): 102415.
Hwang, Gui Won, et al. "Soft microdenticles on artificial octopus sucker enable extraordinary adaptability and wet adhesion on diverse nonflat surfaces." Advanced Science 9.31 (2022): 2202978.
Kim, Da Wan, et al. "Conformably skin-adherent piezoelectric patch with bioinspired hierarchically arrayed microsuckers enables physical energy amplification." ACS Energy Letters 7.5 (2022): 1820-1827.
Lee, Jihyun, et al. "Ultra-intimate hydrogel hybrid skin patch with asymmetric elastomeric spatula-like cylinders." Chemical Engineering Journal 444 (2022): 136581.
Kim, Da Wan, et al. "Electrostatic–Mechanical Synergistic In Situ Multiscale Tissue Adhesion for Sustainable Residue‐Free Bioelectronics Interfaces." Advanced Materials 34.5 (2022): 2105338.
Min, Hyeongho, et al. "Tough Carbon Nanotube‐Implanted Bioinspired Three‐Dimensional Electrical Adhesive for Isotropically Stretchable Water‐Repellent Bioelectronics." Advanced Functional Materials 32.8 (2022): 2107285.
Min, Hyeongho, et al. "Enhanced biocompatibility and multidirectional wet adhesion of insect-like synergistic wrinkled pillars with microcavities." Chemical Engineering Journal 429 (2022): 132467.
Lee, Heon Joon, et al. "An electronically perceptive bioinspired soft wet-adhesion actuator with carbon nanotube-based strain sensors." Acs Nano 15.9 (2021): 14137-14148.
Jang, Siyeon, et al. "A hierarchically tailored wrinkled three-dimensional foam for enhanced elastic supercapacitor electrodes." Nano Letters 21.16 (2021): 7079-7085.
Song, Jin Ho, et al. "Wet soft bio-adhesion of insect-inspired polymeric oil-loadable perforated microcylinders." Chemical Engineering Journal 423 (2021): 130194.
Baik, Sangyul, et al. "Diving beetle–like miniaturized plungers with reversible, rapid biofluid capturing for machine learning–based care of skin disease." Science Advances 7.25 (2021): eabf5695.
Jang, Siyeon, et al. "Printable wet-resistive textile strain sensors using bead-blended composite ink for robustly integrative wearable electronics." Composites Part B: Engineering 210 (2021): 108674.
Baik, Sangyul, et al. "Bioinspired microsphere-embedded adhesive architectures for an electrothermally actuating transport device of dry/wet pliable surfaces." ACS Applied Materials & Interfaces 13.5 (2021): 6930-6940.
Chun, Sungwoo, et al. "A Hierarchical 3D Graphene Nanocomposite Foam for Extremely Tough, Non‐Wettable, and Elastic Conductor." Advanced Materials Interfaces 7.14 (2020): 2000354.
Min, Hyeongho, et al. "Highly air/water-permeable hierarchical mesh architectures for stretchable underwater electronic skin patches." ACS applied materials & interfaces 12.12 (2020): 14425-14432.
Lee, Jihyun, et al. "Intrinsically strain‐insensitive, hyperelastic temperature‐sensing fiber with compressed micro‐wrinkles for integrated textronics." Advanced Materials Technologies 5.5 (2020): 2000073.
Chun, Sungwoo, Changhyun Pang, and Sung Beom Cho. "A micropillar‐assisted versatile strategy for highly sensitive and efficient triboelectric energy generation under in‐plane stimuli." Advanced Materials 32.2 (2020): 1905539.
Choi, Seunghoon, et al. "Conductive hierarchical hairy fibers for highly sensitive, stretchable, and water‐resistant multimodal gesture‐distinguishable sensor, VR applications." Advanced Functional Materials 29.50 (2019): 1905808.
Kim, Jiwon, et al. "Snail‐inspired dry adhesive with embedded microstructures for enhancement of energy dissipation." Advanced Materials Technologies 4.11 (2019): 1900316.
Chun, Sungwoo, et al. "High-output and bending-tolerant triboelectric nanogenerator based on an interlocked array of surface-functionalized indium tin oxide nanohelixes." ACS Energy Letters 4.7 (2019): 1748-1754.
Baik, Sangyul, et al. "Capillarity-enhanced organ-attachable adhesive with highly drainable wrinkled octopus-inspired architectures." ACS applied materials & interfaces 11.29 (2019): 25674-25681.
Chun, Sungwoo, et al. "Self-powered pressure-and vibration-sensitive tactile sensors for learning technique-based neural finger skin." Nano letters 19.5 (2019): 3305-3312.
Chun, Sungwoo, Jiwon Kim, and Changhyun Pang. "A transparent, glue-free, skin-attachable graphene pressure sensor with micropillars for skin-elasticity measurement." Nanotechnology 30.33 (2019): 335501.
Chun, Sungwoo, et al. "Single-layer graphene-based transparent and flexible multifunctional electronics for self-charging power and touch-sensing systems." ACS applied materials & interfaces 11.9 (2019): 9301-9308.
Chun, Sungwoo, et al. "Water-resistant and skin-adhesive wearable electronics using graphene fabric sensor with octopus-inspired microsuckers." ACS applied materials & interfaces 11.18 (2019): 16951-16957.
장시연, et al. "Carbon-based, Ultraelastic, Hierarchically Coated Fiber Strain Sensors with Crack-controllable Beads." 한국고분자학회 학술대회 연구논문 초록집 44.1 (2019): 150-150.
Chun, Sungwoo, et al. "Bioinspired hairy skin electronics for detecting the direction and incident angle of airflow." ACS applied materials & interfaces 11.14 (2019): 13608-13615.
Baik, Sangyul, et al. "Bioinspired adhesive architectures: from skin patch to integrated bioelectronics." Advanced Materials 31.34 (2019): 1803309.
Kim, Da Wan, et al. "Highly permeable skin patch with conductive hierarchical architectures inspired by amphibians and octopi for omnidirectionally enhanced wet adhesion." Advanced Functional Materials 29.13 (2019): 1807614.
Min, Hyeongho, et al. "Magnetically-Programmable Cylindrical Microparticles by Facile Reaping Method." Macromolecular Research 26.12 (2018): 1108-1114.
Chun, Sungwoo, et al. "Conductive and stretchable adhesive electronics with miniaturized octopus‐like suckers against dry/wet skin for biosignal monitoring." Advanced Functional Materials 28.52 (2018): 1805224.
Baik, Sangyul, et al. "Highly adaptable and biocompatible octopus‐like adhesive patches with meniscus‐controlled unfoldable 3D microtips for underwater surface and hairy skin." Advanced Science 5.8 (2018): 1800100.
Baik, Sangyul, et al. "A wet-tolerant adhesive patch inspired by protuberances in suction cups of octopi." Nature 546.7658 (2017): 396-400.
Park, Youngjin, et al. "Microtopography‐guided conductive patterns of liquid‐driven graphene nanoplatelet networks for stretchable and skin‐conformal sensor array." Advanced materials 29.21 (2017): 1606453.
List of Academic Papers
Lee, Jihyun, et al. "Artificial Octopus-Limb-Like Adhesive Patches for Cupping-Driven Transdermal Delivery with Nanoscale Control of Stratum Corneum." ACS nano (2024).
Lee, Yeon Soo, et al. "Softened double-layer octopus-like adhesive with high adaptability for enhanced dynamic dry and wet adhesion." Chemical Engineering Journal 468 (2023): 143792.
Song, Seo Won, et al. "Hierarchically porous hydrogel electrolyte prepared from interpenetrating polymer networks for flexible Zn-Air batteries." Energy Storage Materials 60 (2023): 102802.
Lee, Yeon Soo, et al. "A biodegradable bioinspired oil-coated adhesive film for enhanced wet adhesion." Surfaces and Interfaces 35 (2022): 102415.
Hwang, Gui Won, et al. "Soft microdenticles on artificial octopus sucker enable extraordinary adaptability and wet adhesion on diverse nonflat surfaces." Advanced Science 9.31 (2022): 2202978.
Kim, Da Wan, et al. "Conformably skin-adherent piezoelectric patch with bioinspired hierarchically arrayed microsuckers enables physical energy amplification." ACS Energy Letters 7.5 (2022): 1820-1827.
Lee, Jihyun, et al. "Ultra-intimate hydrogel hybrid skin patch with asymmetric elastomeric spatula-like cylinders." Chemical Engineering Journal 444 (2022): 136581.
Kim, Da Wan, et al. "Electrostatic–Mechanical Synergistic In Situ Multiscale Tissue Adhesion for Sustainable Residue‐Free Bioelectronics Interfaces." Advanced Materials 34.5 (2022): 2105338.
Min, Hyeongho, et al. "Tough Carbon Nanotube‐Implanted Bioinspired Three‐Dimensional Electrical Adhesive for Isotropically Stretchable Water‐Repellent Bioelectronics." Advanced Functional Materials 32.8 (2022): 2107285.
Min, Hyeongho, et al. "Enhanced biocompatibility and multidirectional wet adhesion of insect-like synergistic wrinkled pillars with microcavities." Chemical Engineering Journal 429 (2022): 132467.
Lee, Heon Joon, et al. "An electronically perceptive bioinspired soft wet-adhesion actuator with carbon nanotube-based strain sensors." Acs Nano 15.9 (2021): 14137-14148.
Jang, Siyeon, et al. "A hierarchically tailored wrinkled three-dimensional foam for enhanced elastic supercapacitor electrodes." Nano Letters 21.16 (2021): 7079-7085.
Song, Jin Ho, et al. "Wet soft bio-adhesion of insect-inspired polymeric oil-loadable perforated microcylinders." Chemical Engineering Journal 423 (2021): 130194.
Baik, Sangyul, et al. "Diving beetle–like miniaturized plungers with reversible, rapid biofluid capturing for machine learning–based care of skin disease." Science Advances 7.25 (2021): eabf5695.
Jang, Siyeon, et al. "Printable wet-resistive textile strain sensors using bead-blended composite ink for robustly integrative wearable electronics." Composites Part B: Engineering 210 (2021): 108674.
Baik, Sangyul, et al. "Bioinspired microsphere-embedded adhesive architectures for an electrothermally actuating transport device of dry/wet pliable surfaces." ACS Applied Materials & Interfaces 13.5 (2021): 6930-6940.
Chun, Sungwoo, et al. "A Hierarchical 3D Graphene Nanocomposite Foam for Extremely Tough, Non‐Wettable, and Elastic Conductor." Advanced Materials Interfaces 7.14 (2020): 2000354.
Min, Hyeongho, et al. "Highly air/water-permeable hierarchical mesh architectures for stretchable underwater electronic skin patches." ACS applied materials & interfaces 12.12 (2020): 14425-14432.
Lee, Jihyun, et al. "Intrinsically strain‐insensitive, hyperelastic temperature‐sensing fiber with compressed micro‐wrinkles for integrated textronics." Advanced Materials Technologies 5.5 (2020): 2000073.
Chun, Sungwoo, Changhyun Pang, and Sung Beom Cho. "A micropillar‐assisted versatile strategy for highly sensitive and efficient triboelectric energy generation under in‐plane stimuli." Advanced Materials 32.2 (2020): 1905539.
Choi, Seunghoon, et al. "Conductive hierarchical hairy fibers for highly sensitive, stretchable, and water‐resistant multimodal gesture‐distinguishable sensor, VR applications." Advanced Functional Materials 29.50 (2019): 1905808.
Kim, Jiwon, et al. "Snail‐inspired dry adhesive with embedded microstructures for enhancement of energy dissipation." Advanced Materials Technologies 4.11 (2019): 1900316.
Chun, Sungwoo, et al. "High-output and bending-tolerant triboelectric nanogenerator based on an interlocked array of surface-functionalized indium tin oxide nanohelixes." ACS Energy Letters 4.7 (2019): 1748-1754.
Baik, Sangyul, et al. "Capillarity-enhanced organ-attachable adhesive with highly drainable wrinkled octopus-inspired architectures." ACS applied materials & interfaces 11.29 (2019): 25674-25681.
Chun, Sungwoo, et al. "Self-powered pressure-and vibration-sensitive tactile sensors for learning technique-based neural finger skin." Nano letters 19.5 (2019): 3305-3312.
Chun, Sungwoo, Jiwon Kim, and Changhyun Pang. "A transparent, glue-free, skin-attachable graphene pressure sensor with micropillars for skin-elasticity measurement." Nanotechnology 30.33 (2019): 335501.
Chun, Sungwoo, et al. "Single-layer graphene-based transparent and flexible multifunctional electronics for self-charging power and touch-sensing systems." ACS applied materials & interfaces 11.9 (2019): 9301-9308.
Chun, Sungwoo, et al. "Water-resistant and skin-adhesive wearable electronics using graphene fabric sensor with octopus-inspired microsuckers." ACS applied materials & interfaces 11.18 (2019): 16951-16957.
장시연, et al. "Carbon-based, Ultraelastic, Hierarchically Coated Fiber Strain Sensors with Crack-controllable Beads." 한국고분자학회 학술대회 연구논문 초록집 44.1 (2019): 150-150.
Chun, Sungwoo, et al. "Bioinspired hairy skin electronics for detecting the direction and incident angle of airflow." ACS applied materials & interfaces 11.14 (2019): 13608-13615.
Baik, Sangyul, et al. "Bioinspired adhesive architectures: from skin patch to integrated bioelectronics." Advanced Materials 31.34 (2019): 1803309.
Kim, Da Wan, et al. "Highly permeable skin patch with conductive hierarchical architectures inspired by amphibians and octopi for omnidirectionally enhanced wet adhesion." Advanced Functional Materials 29.13 (2019): 1807614.
Min, Hyeongho, et al. "Magnetically-Programmable Cylindrical Microparticles by Facile Reaping Method." Macromolecular Research 26.12 (2018): 1108-1114.
Chun, Sungwoo, et al. "Conductive and stretchable adhesive electronics with miniaturized octopus‐like suckers against dry/wet skin for biosignal monitoring." Advanced Functional Materials 28.52 (2018): 1805224.
Baik, Sangyul, et al. "Highly adaptable and biocompatible octopus‐like adhesive patches with meniscus‐controlled unfoldable 3D microtips for underwater surface and hairy skin." Advanced Science 5.8 (2018): 1800100.
Baik, Sangyul, et al. "A wet-tolerant adhesive patch inspired by protuberances in suction cups of octopi." Nature 546.7658 (2017): 396-400.
Park, Youngjin, et al. "Microtopography‐guided conductive patterns of liquid‐driven graphene nanoplatelet networks for stretchable and skin‐conformal sensor array." Advanced materials 29.21 (2017): 1606453.
List of Academic Papers
Lee, Jihyun, et al. "Artificial Octopus-Limb-Like Adhesive Patches for Cupping-Driven Transdermal Delivery with Nanoscale Control of Stratum Corneum." ACS nano (2024).
Lee, Yeon Soo, et al. "Softened double-layer octopus-like adhesive with high adaptability for enhanced dynamic dry and wet adhesion." Chemical Engineering Journal 468 (2023): 143792.
Song, Seo Won, et al. "Hierarchically porous hydrogel electrolyte prepared from interpenetrating polymer networks for flexible Zn-Air batteries." Energy Storage Materials 60 (2023): 102802.
Lee, Yeon Soo, et al. "A biodegradable bioinspired oil-coated adhesive film for enhanced wet adhesion." Surfaces and Interfaces 35 (2022): 102415.
Hwang, Gui Won, et al. "Soft microdenticles on artificial octopus sucker enable extraordinary adaptability and wet adhesion on diverse nonflat surfaces." Advanced Science 9.31 (2022): 2202978.
Kim, Da Wan, et al. "Conformably skin-adherent piezoelectric patch with bioinspired hierarchically arrayed microsuckers enables physical energy amplification." ACS Energy Letters 7.5 (2022): 1820-1827.
Lee, Jihyun, et al. "Ultra-intimate hydrogel hybrid skin patch with asymmetric elastomeric spatula-like cylinders." Chemical Engineering Journal 444 (2022): 136581.
Kim, Da Wan, et al. "Electrostatic–Mechanical Synergistic In Situ Multiscale Tissue Adhesion for Sustainable Residue‐Free Bioelectronics Interfaces." Advanced Materials 34.5 (2022): 2105338.
Min, Hyeongho, et al. "Tough Carbon Nanotube‐Implanted Bioinspired Three‐Dimensional Electrical Adhesive for Isotropically Stretchable Water‐Repellent Bioelectronics." Advanced Functional Materials 32.8 (2022): 2107285.
Min, Hyeongho, et al. "Enhanced biocompatibility and multidirectional wet adhesion of insect-like synergistic wrinkled pillars with microcavities." Chemical Engineering Journal 429 (2022): 132467.
Lee, Heon Joon, et al. "An electronically perceptive bioinspired soft wet-adhesion actuator with carbon nanotube-based strain sensors." Acs Nano 15.9 (2021): 14137-14148.
Jang, Siyeon, et al. "A hierarchically tailored wrinkled three-dimensional foam for enhanced elastic supercapacitor electrodes." Nano Letters 21.16 (2021): 7079-7085.
Song, Jin Ho, et al. "Wet soft bio-adhesion of insect-inspired polymeric oil-loadable perforated microcylinders." Chemical Engineering Journal 423 (2021): 130194.
Baik, Sangyul, et al. "Diving beetle–like miniaturized plungers with reversible, rapid biofluid capturing for machine learning–based care of skin disease." Science Advances 7.25 (2021): eabf5695.
Jang, Siyeon, et al. "Printable wet-resistive textile strain sensors using bead-blended composite ink for robustly integrative wearable electronics." Composites Part B: Engineering 210 (2021): 108674.
Baik, Sangyul, et al. "Bioinspired microsphere-embedded adhesive architectures for an electrothermally actuating transport device of dry/wet pliable surfaces." ACS Applied Materials & Interfaces 13.5 (2021): 6930-6940.
Chun, Sungwoo, et al. "A Hierarchical 3D Graphene Nanocomposite Foam for Extremely Tough, Non‐Wettable, and Elastic Conductor." Advanced Materials Interfaces 7.14 (2020): 2000354.
Min, Hyeongho, et al. "Highly air/water-permeable hierarchical mesh architectures for stretchable underwater electronic skin patches." ACS applied materials & interfaces 12.12 (2020): 14425-14432.
Lee, Jihyun, et al. "Intrinsically strain‐insensitive, hyperelastic temperature‐sensing fiber with compressed micro‐wrinkles for integrated textronics." Advanced Materials Technologies 5.5 (2020): 2000073.
Chun, Sungwoo, Changhyun Pang, and Sung Beom Cho. "A micropillar‐assisted versatile strategy for highly sensitive and efficient triboelectric energy generation under in‐plane stimuli." Advanced Materials 32.2 (2020): 1905539.
Choi, Seunghoon, et al. "Conductive hierarchical hairy fibers for highly sensitive, stretchable, and water‐resistant multimodal gesture‐distinguishable sensor, VR applications." Advanced Functional Materials 29.50 (2019): 1905808.
Kim, Jiwon, et al. "Snail‐inspired dry adhesive with embedded microstructures for enhancement of energy dissipation." Advanced Materials Technologies 4.11 (2019): 1900316.
Chun, Sungwoo, et al. "High-output and bending-tolerant triboelectric nanogenerator based on an interlocked array of surface-functionalized indium tin oxide nanohelixes." ACS Energy Letters 4.7 (2019): 1748-1754.
Baik, Sangyul, et al. "Capillarity-enhanced organ-attachable adhesive with highly drainable wrinkled octopus-inspired architectures." ACS applied materials & interfaces 11.29 (2019): 25674-25681.
Chun, Sungwoo, et al. "Self-powered pressure-and vibration-sensitive tactile sensors for learning technique-based neural finger skin." Nano letters 19.5 (2019): 3305-3312.
Chun, Sungwoo, Jiwon Kim, and Changhyun Pang. "A transparent, glue-free, skin-attachable graphene pressure sensor with micropillars for skin-elasticity measurement." Nanotechnology 30.33 (2019): 335501.
Chun, Sungwoo, et al. "Single-layer graphene-based transparent and flexible multifunctional electronics for self-charging power and touch-sensing systems." ACS applied materials & interfaces 11.9 (2019): 9301-9308.
Chun, Sungwoo, et al. "Water-resistant and skin-adhesive wearable electronics using graphene fabric sensor with octopus-inspired microsuckers." ACS applied materials & interfaces 11.18 (2019): 16951-16957.
장시연, et al. "Carbon-based, Ultraelastic, Hierarchically Coated Fiber Strain Sensors with Crack-controllable Beads." 한국고분자학회 학술대회 연구논문 초록집 44.1 (2019): 150-150.
Chun, Sungwoo, et al. "Bioinspired hairy skin electronics for detecting the direction and incident angle of airflow." ACS applied materials & interfaces 11.14 (2019): 13608-13615.
Baik, Sangyul, et al. "Bioinspired adhesive architectures: from skin patch to integrated bioelectronics." Advanced Materials 31.34 (2019): 1803309.
Kim, Da Wan, et al. "Highly permeable skin patch with conductive hierarchical architectures inspired by amphibians and octopi for omnidirectionally enhanced wet adhesion." Advanced Functional Materials 29.13 (2019): 1807614.
Min, Hyeongho, et al. "Magnetically-Programmable Cylindrical Microparticles by Facile Reaping Method." Macromolecular Research 26.12 (2018): 1108-1114.
Chun, Sungwoo, et al. "Conductive and stretchable adhesive electronics with miniaturized octopus‐like suckers against dry/wet skin for biosignal monitoring." Advanced Functional Materials 28.52 (2018): 1805224.
Baik, Sangyul, et al. "Highly adaptable and biocompatible octopus‐like adhesive patches with meniscus‐controlled unfoldable 3D microtips for underwater surface and hairy skin." Advanced Science 5.8 (2018): 1800100.
Baik, Sangyul, et al. "A wet-tolerant adhesive patch inspired by protuberances in suction cups of octopi." Nature 546.7658 (2017): 396-400.
Park, Youngjin, et al. "Microtopography‐guided conductive patterns of liquid‐driven graphene nanoplatelet networks for stretchable and skin‐conformal sensor array." Advanced materials 29.21 (2017): 1606453.
List of Academic Papers
Lee, Jihyun, et al. "Artificial Octopus-Limb-Like Adhesive Patches for Cupping-Driven Transdermal Delivery with Nanoscale Control of Stratum Corneum." ACS nano (2024).
Lee, Yeon Soo, et al. "Softened double-layer octopus-like adhesive with high adaptability for enhanced dynamic dry and wet adhesion." Chemical Engineering Journal 468 (2023): 143792.
Song, Seo Won, et al. "Hierarchically porous hydrogel electrolyte prepared from interpenetrating polymer networks for flexible Zn-Air batteries." Energy Storage Materials 60 (2023): 102802.
Lee, Yeon Soo, et al. "A biodegradable bioinspired oil-coated adhesive film for enhanced wet adhesion." Surfaces and Interfaces 35 (2022): 102415.
Hwang, Gui Won, et al. "Soft microdenticles on artificial octopus sucker enable extraordinary adaptability and wet adhesion on diverse nonflat surfaces." Advanced Science 9.31 (2022): 2202978.
Kim, Da Wan, et al. "Conformably skin-adherent piezoelectric patch with bioinspired hierarchically arrayed microsuckers enables physical energy amplification." ACS Energy Letters 7.5 (2022): 1820-1827.
Lee, Jihyun, et al. "Ultra-intimate hydrogel hybrid skin patch with asymmetric elastomeric spatula-like cylinders." Chemical Engineering Journal 444 (2022): 136581.
Kim, Da Wan, et al. "Electrostatic–Mechanical Synergistic In Situ Multiscale Tissue Adhesion for Sustainable Residue‐Free Bioelectronics Interfaces." Advanced Materials 34.5 (2022): 2105338.
Min, Hyeongho, et al. "Tough Carbon Nanotube‐Implanted Bioinspired Three‐Dimensional Electrical Adhesive for Isotropically Stretchable Water‐Repellent Bioelectronics." Advanced Functional Materials 32.8 (2022): 2107285.
Min, Hyeongho, et al. "Enhanced biocompatibility and multidirectional wet adhesion of insect-like synergistic wrinkled pillars with microcavities." Chemical Engineering Journal 429 (2022): 132467.
Lee, Heon Joon, et al. "An electronically perceptive bioinspired soft wet-adhesion actuator with carbon nanotube-based strain sensors." Acs Nano 15.9 (2021): 14137-14148.
Jang, Siyeon, et al. "A hierarchically tailored wrinkled three-dimensional foam for enhanced elastic supercapacitor electrodes." Nano Letters 21.16 (2021): 7079-7085.
Song, Jin Ho, et al. "Wet soft bio-adhesion of insect-inspired polymeric oil-loadable perforated microcylinders." Chemical Engineering Journal 423 (2021): 130194.
Baik, Sangyul, et al. "Diving beetle–like miniaturized plungers with reversible, rapid biofluid capturing for machine learning–based care of skin disease." Science Advances 7.25 (2021): eabf5695.
Jang, Siyeon, et al. "Printable wet-resistive textile strain sensors using bead-blended composite ink for robustly integrative wearable electronics." Composites Part B: Engineering 210 (2021): 108674.
Baik, Sangyul, et al. "Bioinspired microsphere-embedded adhesive architectures for an electrothermally actuating transport device of dry/wet pliable surfaces." ACS Applied Materials & Interfaces 13.5 (2021): 6930-6940.
Chun, Sungwoo, et al. "A Hierarchical 3D Graphene Nanocomposite Foam for Extremely Tough, Non‐Wettable, and Elastic Conductor." Advanced Materials Interfaces 7.14 (2020): 2000354.
Min, Hyeongho, et al. "Highly air/water-permeable hierarchical mesh architectures for stretchable underwater electronic skin patches." ACS applied materials & interfaces 12.12 (2020): 14425-14432.
Lee, Jihyun, et al. "Intrinsically strain‐insensitive, hyperelastic temperature‐sensing fiber with compressed micro‐wrinkles for integrated textronics." Advanced Materials Technologies 5.5 (2020): 2000073.
Chun, Sungwoo, Changhyun Pang, and Sung Beom Cho. "A micropillar‐assisted versatile strategy for highly sensitive and efficient triboelectric energy generation under in‐plane stimuli." Advanced Materials 32.2 (2020): 1905539.
Choi, Seunghoon, et al. "Conductive hierarchical hairy fibers for highly sensitive, stretchable, and water‐resistant multimodal gesture‐distinguishable sensor, VR applications." Advanced Functional Materials 29.50 (2019): 1905808.
Kim, Jiwon, et al. "Snail‐inspired dry adhesive with embedded microstructures for enhancement of energy dissipation." Advanced Materials Technologies 4.11 (2019): 1900316.
Chun, Sungwoo, et al. "High-output and bending-tolerant triboelectric nanogenerator based on an interlocked array of surface-functionalized indium tin oxide nanohelixes." ACS Energy Letters 4.7 (2019): 1748-1754.
Baik, Sangyul, et al. "Capillarity-enhanced organ-attachable adhesive with highly drainable wrinkled octopus-inspired architectures." ACS applied materials & interfaces 11.29 (2019): 25674-25681.
Chun, Sungwoo, et al. "Self-powered pressure-and vibration-sensitive tactile sensors for learning technique-based neural finger skin." Nano letters 19.5 (2019): 3305-3312.
Chun, Sungwoo, Jiwon Kim, and Changhyun Pang. "A transparent, glue-free, skin-attachable graphene pressure sensor with micropillars for skin-elasticity measurement." Nanotechnology 30.33 (2019): 335501.
Chun, Sungwoo, et al. "Single-layer graphene-based transparent and flexible multifunctional electronics for self-charging power and touch-sensing systems." ACS applied materials & interfaces 11.9 (2019): 9301-9308.
Chun, Sungwoo, et al. "Water-resistant and skin-adhesive wearable electronics using graphene fabric sensor with octopus-inspired microsuckers." ACS applied materials & interfaces 11.18 (2019): 16951-16957.
장시연, et al. "Carbon-based, Ultraelastic, Hierarchically Coated Fiber Strain Sensors with Crack-controllable Beads." 한국고분자학회 학술대회 연구논문 초록집 44.1 (2019): 150-150.
Chun, Sungwoo, et al. "Bioinspired hairy skin electronics for detecting the direction and incident angle of airflow." ACS applied materials & interfaces 11.14 (2019): 13608-13615.
Baik, Sangyul, et al. "Bioinspired adhesive architectures: from skin patch to integrated bioelectronics." Advanced Materials 31.34 (2019): 1803309.
Kim, Da Wan, et al. "Highly permeable skin patch with conductive hierarchical architectures inspired by amphibians and octopi for omnidirectionally enhanced wet adhesion." Advanced Functional Materials 29.13 (2019): 1807614.
Min, Hyeongho, et al. "Magnetically-Programmable Cylindrical Microparticles by Facile Reaping Method." Macromolecular Research 26.12 (2018): 1108-1114.
Chun, Sungwoo, et al. "Conductive and stretchable adhesive electronics with miniaturized octopus‐like suckers against dry/wet skin for biosignal monitoring." Advanced Functional Materials 28.52 (2018): 1805224.
Baik, Sangyul, et al. "Highly adaptable and biocompatible octopus‐like adhesive patches with meniscus‐controlled unfoldable 3D microtips for underwater surface and hairy skin." Advanced Science 5.8 (2018): 1800100.
Baik, Sangyul, et al. "A wet-tolerant adhesive patch inspired by protuberances in suction cups of octopi." Nature 546.7658 (2017): 396-400.
Park, Youngjin, et al. "Microtopography‐guided conductive patterns of liquid‐driven graphene nanoplatelet networks for stretchable and skin‐conformal sensor array." Advanced materials 29.21 (2017): 1606453.
We adapt to
your business.
Mimetics' process is tailored for every customer, creating innovations that are as individualized as our clients. We provide sustainable and creative solutions through flexible product development, expert consulting, innovative partnerships, and customized product offerings to meet the needs of our customers.
We adapt to
your business.
Mimetics' process is tailored for every customer, creating innovations that are as individualized as our clients. We provide sustainable and creative solutions through flexible product development, expert consulting, innovative partnerships, and customized product offerings to meet the needs of our customers.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
The strong suction capability of an Octopus is produced through a combination of pressure reduction and capillary action. This multifaceted approach creates very strong adhesion and stable attachment—even on slippery surfaces. We are actively researching and developing various products to replicate and leverage this innovative natural technology, starting with our skin ampoule patches.
Amplifying the Suction Effect
With Capillary Force
Amplifying the Suction Effect
With Capillary Force
Amplifying the Suction Effect
With Capillary Force
Inside an octopus sucker are small, capillary-rich structures called papillae that line the inner surface. Thanks to the domed shape of the sucker, when it's placed on a surface, it creates an enclosed space. When the octopus contracts the muscles around it's sucker, the pressure in the enclosed space decreases. This pressure reduction combines with capillary action in the papillae to create excellent adhesion between the sucker and the surface.
Inside an octopus sucker are small, capillary-rich structures called papillae that line the inner surface. Thanks to the domed shape of the sucker, when it's placed on a surface, it creates an enclosed space. When the octopus contracts the muscles around it's sucker, the pressure in the enclosed space decreases. This pressure reduction combines with capillary action in the papillae to create excellent adhesion between the sucker and the surface.
Inside an octopus sucker are small, capillary-rich structures called papillae that line the inner surface. Thanks to the domed shape of the sucker, when it's placed on a surface, it creates an enclosed space. When the octopus contracts the muscles around it's sucker, the pressure in the enclosed space decreases. This pressure reduction combines with capillary action in the papillae to create excellent adhesion between the sucker and the surface.
Triple-Duty Tentacles
Triple-Duty Tentacles
Triple-Duty Tentacles
Octopuses are covered with suckers that combine sensory and motor functions. Each sucker is comprised of a central hole, surrounded by a ring of muscles. These suckers play a crucial role in tasting food, manipulating objects, and providing strong suction power.
Octopuses are covered with suckers that combine sensory and motor functions. Each sucker is comprised of a central hole, surrounded by a ring of muscles. These suckers play a crucial role in tasting food, manipulating objects, and providing strong suction power.
Octopuses are covered with suckers that combine sensory and motor functions. Each sucker is comprised of a central hole, surrounded by a ring of muscles. These suckers play a crucial role in tasting food, manipulating objects, and providing strong suction power.
Applicable Industry Sectors
Transdermal Drug
Delivery
Organ Tissue
Adhesive
Sensor
Robot Arm
Transdermal
Drug Delivery
Organ Tissue
Adhesive
Sensor
Robot Arm
Applicable Industry Sectors
Applicable Industry Sectors
We are developing technologies to harness the shear adhesion and dispersion capabilities that have evolved in beetles. This approach makes transdermal drug delivery more efficient and opens up new possibilities in precision electronic interfaces and medical applications. Combined with a capillary-force-assisted suction effect, this advancement is primed for use in skin diagnostics, electronic devices, and even as a tissue adhesive.
We are developing technologies to harness the shear adhesion and dispersion capabilities that have evolved in beetles. This approach makes transdermal drug delivery more efficient and opens up new possibilities in precision electronic interfaces and medical applications. Combined with a capillary-force-assisted suction effect, this advancement is primed for use in skin diagnostics, electronic devices, and even as a tissue adhesive.
We are developing technologies to harness the shear adhesion and dispersion capabilities that have evolved in beetles. This approach makes transdermal drug delivery more efficient and opens up new possibilities in precision electronic interfaces and medical applications. Combined with a capillary-force-assisted suction effect, this advancement is primed for use in skin diagnostics, electronic devices, and even as a tissue adhesive.
We are developing technologies to harness the shear adhesion and dispersion capabilities that have evolved in beetles. This approach makes transdermal drug delivery more efficient and opens up new possibilities in precision electronic interfaces and medical applications. Combined with a capillary-force-assisted suction effect, this advancement is primed for use in skin diagnostics, electronic devices, and even as a tissue adhesive.
Capilary Force
Capilary Force
Capilary Force
Frogs can adhere to slippery and rough surfaces not only thanks to their specialized toe pads, but also due to the unique characteristics of the skin on their belly, thighs, and abdomen. They have hydrophobic skin that maintains moisture, while preventing water absorption. Frogs utilize suction force when feeding, especially using their tongue to leap towards and capture prey.
Frogs can adhere to slippery and rough surfaces not only thanks to their specialized toe pads, but also due to the unique characteristics of the skin on their belly, thighs, and abdomen. They have hydrophobic skin that maintains moisture, while preventing water absorption. Frogs utilize suction force when feeding, especially using their tongue to leap towards and capture prey.
Frogs can adhere to slippery and rough surfaces not only thanks to their specialized toe pads, but also due to the unique characteristics of the skin on their belly, thighs, and abdomen. They have hydrophobic skin that maintains moisture, while preventing water absorption. Frogs utilize suction force when feeding, especially using their tongue to leap towards and capture prey.
Frog Sole Microstructure
Frog Sole Microstructure
Frog Sole Microstructure
The surface of a frog's sole has a fine texture, which increases surface contact, enhances friction, and prevents slippage. Additionally, fine hairs and pores can absorb or expel water, maintaining the sole's surface or reducing slippage underwater.
The surface of a frog's sole has a fine texture, which increases surface contact, enhances friction, and prevents slippage. Additionally, fine hairs and pores can absorb or expel water, maintaining the sole's surface or reducing slippage underwater.
The surface of a frog's sole has a fine texture, which increases surface contact, enhances friction, and prevents slippage. Additionally, fine hairs and pores can absorb or expel water, maintaining the sole's surface or reducing slippage underwater.
Applicable Industry Sectors
Applicable Industry Sectors
Transdermal Drug
Delivery
Organ Tissue
Adhesive
Wearable
Electronics
Transdermal
Drug Delivery
Organ Tissue
Adhesive
Wearable
Electronics
With technology derived from the unique structures found in frog feet, we are innovating around transdermal drug delivery and electronic devices. Our technology enables efficient current transmission through close contact with the skin and is ideal for sensitive, precision touch interfaces. With these developments, Mimetics is extending its exploration beyond cosmetics to the electronic equipment industry.
With technology derived from the unique structures found in frog feet, we are innovating around transdermal drug delivery and electronic devices. Our technology enables efficient current transmission through close contact with the skin and is ideal for sensitive, precision touch interfaces. With these developments, Mimetics is extending its exploration beyond cosmetics to the electronic equipment industry.
With technology derived from the unique structures found in frog feet, we are innovating around transdermal drug delivery and electronic devices. Our technology enables efficient current transmission through close contact with the skin and is ideal for sensitive, precision touch interfaces. With these developments, Mimetics is extending its exploration beyond cosmetics to the electronic equipment industry.
Chameleon biology harnesses the interaction between light wavelengths and skin grid patterns. By mirroring the unique properties of Chameleon skin, Mimetics is creating breakthrough technologies—like color-changing films that can adapt to diverse environments. The applications for these technologies range from camouflage and decoration, to safety signalling and beyond. We are committed to exploring new design and functional material development using this innovative approach.
Chameleon biology harnesses the interaction between light wavelengths and skin grid patterns. By mirroring the unique properties of Chameleon skin, Mimetics is creating breakthrough technologies—like color-changing films that can adapt to diverse environments. The applications for these technologies range from camouflage and decoration, to safety signalling and beyond. We are committed to exploring new design and functional material development using this innovative approach.
Chameleon biology harnesses the interaction between light wavelengths and skin grid patterns. By mirroring the unique properties of Chameleon skin, Mimetics is creating breakthrough technologies—like color-changing films that can adapt to diverse environments. The applications for these technologies range from camouflage and decoration, to safety signalling and beyond. We are committed to exploring new design and functional material development using this innovative approach.
Interaction B/W Wavelength of Light
Interaction B/W Wavelength of Light
Interaction B/W Wavelength of Light
The outermost layer of chameleon skin contains special pigment-filled cells called chromatophores, which the animal can expand or contract. Below these cells, there are layers of nano-crystals or guanine crystals that form a grid structure. These layers work together to impart color to the animal.
The outermost layer of chameleon skin contains special pigment-filled cells called chromatophores, which the animal can expand or contract. Below these cells, there are layers of nano-crystals or guanine crystals that form a grid structure. These layers work together to impart color to the animal.
The outermost layer of chameleon skin contains special pigment-filled cells called chromatophores, which the animal can expand or contract. Below these cells, there are layers of nano-crystals or guanine crystals that form a grid structure. These layers work together to impart color to the animal.
Pattern of Skin Lattice
Pattern of Skin Lattice
Pattern of Skin Lattice
The grid structure interacts with light waves, causing interference. When the chameleon relaxes or contracts its skin, the spacing between the nano-crystals changes, altering the interference pattern, and consequently, the reflected color on the skin.
The grid structure interacts with light waves, causing interference. When the chameleon relaxes or contracts its skin, the spacing between the nano-crystals changes, altering the interference pattern, and consequently, the reflected color on the skin.
The grid structure interacts with light waves, causing interference. When the chameleon relaxes or contracts its skin, the spacing between the nano-crystals changes, altering the interference pattern, and consequently, the reflected color on the skin.
Applicable Industry Sectors
Applicable Industry Sectors
Applicable Industry Sectors
Transdermal Drug
Delivery
Transdermal Drug
Delivery
Structural Color
Structural
Color
Structural
Color
Transdermal Drug
Delivery
Organ Tissue
Adhesive
Diagnosis of
Skin
Wearable Electronics
Transdermal Drug
Delivery
Organ Tissue
Adhesive
Diagnosis of
Skin
Wearable Electronics
Capillary Assisted Suction Effect
Capillary Assisted Suction Effect
Capillary Assisted Suction Effect
The water beetle possesses a unique ability to harvest water from the air in misty early mornings. The beetle's hydrophobic grooves prevent the spread of water, creating a collection gradient. Over time, tiny droplets merge to form larger droplets that the beetle can use.
The water beetle possesses a unique ability to harvest water from the air in misty early mornings. The beetle's hydrophobic grooves prevent the spread of water, creating a collection gradient. Over time, tiny droplets merge to form larger droplets that the beetle can use.
The water beetle possesses a unique ability to harvest water from the air in misty early mornings. The beetle's hydrophobic grooves prevent the spread of water, creating a collection gradient. Over time, tiny droplets merge to form larger droplets that the beetle can use.
Shear Adhesion Force
Shear Adhesion Force
Shear Adhesion Force
Shear adhesion is the force that resists the sliding motion of one surface over another. The fine hairs or bristles on the water beetle's feet create a large surface area. When pressed against a surface, these hairs generate friction and shear adhesion, enabling resistance to slipping.
Shear adhesion is the force that resists the sliding motion of one surface over another. The fine hairs or bristles on the water beetle's feet create a large surface area. When pressed against a surface, these hairs generate friction and shear adhesion, enabling resistance to slipping.
Shear adhesion is the force that resists the sliding motion of one surface over another. The fine hairs or bristles on the water beetle's feet create a large surface area. When pressed against a surface, these hairs generate friction and shear adhesion, enabling resistance to slipping.
Applicable Industry Sectors
Applicable Industry Sectors
Transdermal
Drug Delivery
Organ Tissue
Adhesive
Sensor
Robot Arm
Transdermal Drug
Delivery
Organ Tissue
Adhesive
Diagnosis of
Skin
Wearable
Electronics
Inside an octopus sucker are small, capillary-rich structures called papillae that line the inner surface. Thanks to the domed shape of the sucker, when it's placed on a surface, it creates an enclosed space. When the octopus contracts the muscles around it's sucker, the pressure in the enclosed space decreases. This pressure reduction combines with capillary action in the papillae to create excellent adhesion between the sucker and the surface.
Inside an octopus sucker are small, capillary-rich structures called papillae that line the inner surface. Thanks to the domed shape of the sucker, when it's placed on a surface, it creates an enclosed space. When the octopus contracts the muscles around it's sucker, the pressure in the enclosed space decreases. This pressure reduction combines with capillary action in the papillae to create excellent adhesion between the sucker and the surface.
Amplifying the Suction Effect
With Capillary Force
Amplifying the Suction Effect
With Capillary Force
Triple-Duty Tentacles
Triple-Duty Tentacles
Octopuses are covered with suckers that combine sensory and motor functions. Each sucker is comprised of a central hole, surrounded by a ring of muscles. These suckers play a crucial role in tasting food, manipulating objects, and providing strong suction power.
Octopuses are covered with suckers that combine sensory and motor functions. Each sucker is comprised of a central hole, surrounded by a ring of muscles. These suckers play a crucial role in tasting food, manipulating objects, and providing strong suction power.
Applicable
Industry Sectors
Applicable
Industry Sectors
Capilary Assisted
Suction Effect
Capilary Assisted
Suction Effect
The water beetle possesses a unique ability to harvest water from the air in misty early mornings. The beetle's hydrophobic grooves prevent the spread of water, creating a collection gradient. Over time, tiny droplets merge to form larger droplets that the beetle can use.
The water beetle possesses a unique ability to harvest water from the air in misty early mornings. The beetle's hydrophobic grooves prevent the spread of water, creating a collection gradient. Over time, tiny droplets merge to form larger droplets that the beetle can use.
Shear Adhesion Force
Shear Adhesion Force
Shear adhesion is the force that resists the sliding motion of one surface over another. The fine hairs or bristles on the water beetle's feet create a large surface area. When pressed against a surface, these hairs generate friction and shear adhesion, enabling resistance to slipping.
Shear adhesion is the force that resists the sliding motion of one surface over another. The fine hairs or bristles on the water beetle's feet create a large surface area. When pressed against a surface, these hairs generate friction and shear adhesion, enabling resistance to slipping.
Applicable
Industry Sectors
Applicable
Industry Sectors
With technology derived from the unique structures found in frog feet, we are innovating around transdermal drug delivery and electronic devices. Our technology enables efficient current transmission through close contact with the skin and is ideal for sensitive, precision touch interfaces. With these developments, Mimetics is extending its exploration beyond cosmetics to the electronic equipment industry.
With technology derived from the unique structures found in frog feet, we are innovating around transdermal drug delivery and electronic devices. Our technology enables efficient current transmission through close contact with the skin and is ideal for sensitive, precision touch interfaces. With these developments, Mimetics is extending its exploration beyond cosmetics to the electronic equipment industry.
Chameleon biology harnesses the interaction between light wavelengths and skin grid patterns. By mirroring the unique properties of Chameleon skin, Mimetics is creating breakthrough technologies—like color-changing films that can adapt to diverse environments. The applications for these technologies range from camouflage and decoration, to safety signalling and beyond. We are committed to exploring new design and functional material development using this innovative approach.
Chameleon biology harnesses the interaction between light wavelengths and skin grid patterns. By mirroring the unique properties of Chameleon skin, Mimetics is creating breakthrough technologies—like color-changing films that can adapt to diverse environments. The applications for these technologies range from camouflage and decoration, to safety signalling and beyond. We are committed to exploring new design and functional material development using this innovative approach.
Capilary Force
Capilary Force
Frogs can adhere to slippery and rough surfaces not only thanks to their specialized toe pads, but also due to the unique characteristics of the skin on their belly, thighs, and abdomen. They have hydrophobic skin that maintains moisture, while preventing water absorption. Frogs utilize suction force when feeding, especially using their tongue to leap towards and capture prey.
Frogs can adhere to slippery and rough surfaces not only thanks to their specialized toe pads, but also due to the unique characteristics of the skin on their belly, thighs, and abdomen. They have hydrophobic skin that maintains moisture, while preventing water absorption. Frogs utilize suction force when feeding, especially using their tongue to leap towards and capture prey.
Frog Sole Microstructure
Frog Sole Microstructure
The surface of a frog's sole has a fine texture, which increases surface contact, enhances friction, and prevents slippage. Additionally, fine hairs and pores can absorb or expel water, maintaining the sole's surface or reducing slippage underwater.
The surface of a frog's sole has a fine texture, which increases surface contact, enhances friction, and prevents slippage. Additionally, fine hairs and pores can absorb or expel water, maintaining the sole's surface or reducing slippage underwater.
Applicable
Industry Sectors
Applicable
Industry Sectors
Interaction B/W
Wavelength of Light
Interaction B/W
Wavelength of Light
The outermost layer of chameleon skin contains special pigment-filled cells called chromatophores, which the animal can expand or contract. Below these cells, there are layers of nano-crystals or guanine crystals that form a grid structure. These layers work together to impart color to the animal.
The outermost layer of chameleon skin contains special pigment-filled cells called chromatophores, which the animal can expand or contract. Below these cells, there are layers of nano-crystals or guanine crystals that form a grid structure. These layers work together to impart color to the animal.
Pattern of Skin Lattice
Pattern of Skin Lattice
The grid structure interacts with light waves, causing interference. When the chameleon relaxes or contracts its skin, the spacing between the nano-crystals changes, altering the interference pattern, and consequently, the reflected color on the skin.
The grid structure interacts with light waves, causing interference. When the chameleon relaxes or contracts its skin, the spacing between the nano-crystals changes, altering the interference pattern, and consequently, the reflected color on the skin.
Applicable
Industry Sectors
Applicable
Industry Sectors
We adapt to
your business.
Mimetics' Tailored Process makes innovation through a customized approach. we provides sustainable and creative solutions through flexible product development, professional consulting, innovative partnership building,
and customized product delivery.
We adapt to
your business.
Mimetics' Tailored Process makes innovation through a customized approach. we provides sustainable and creative solutions through flexible product development, professional consulting, innovative partnership building,
and customized product delivery.
World Leading
Biomimetic Technology
Mimetics is home to the leading-edge of biomimetic technologies,
developed through our extensive and enduring exploration of nature.
World Leading
Biomimetic Technology
Mimetics is home to the leading-edge of biomimetic technologies,
developed through our extensive and enduring exploration of nature.
World Leading
Biomimetic Technology
Mimetics is home to the leading-edge of biomimetic technologies,
developed through our extensive and enduring exploration of nature.
World Leading
Biomimetic Technology
Mimetics is home to the leading-edge of biomimetic technologies, developed through our extensive and enduring exploration of nature.
Mimetics Co., Ltd.
Nature, Mimetics, and You
—Let's Innovate Together.
#1210/1211, 156, Gwanggyo-ro, Yeongtong-gu, Suwon-si,
Gyeonggi-do, Republic of Korea 16506
Mimetics Co., Ltd.
Nature, Mimetics, and You
—Let's Innovate Together.
#1210/1211, 156, Gwanggyo-ro, Yeongtong-gu, Suwon-si,
Gyeonggi-do, Republic of Korea 16506
Mimetics Co., Ltd.
Nature, Mimetics, and You
—Let's Innovate Together.
#1210/1211, 156, Gwanggyo-ro, Yeongtong-gu, Suwon-si,
Gyeonggi-do, Republic of Korea 16506
Mimetics Co., Ltd.
Nature, Mimetics, and You
—Let's Innovate Together.
#1210/1211, 156, Gwanggyo-ro, Yeongtong-gu, Suwon-si,
Gyeonggi-do, Republic of Korea 16506