Bionic microchannels for step lifting transpiration

Those various cross-sectional vessels in trees transfer water to as high as 100 meters, but the traditional fabrication methods limit the manufacturing of those vessels, resulting in the non-availability of those bionic microchannels. Herein, we fabricate those bionic microchannels with various cross-sections by employing projection micro-stereolithography (PµSL) based 3D printing technique. The circumradius of bionic microchannels (pentagonal, square, triangle, and five-pointed star) can be as small as 100 μm with precisely fabricated sharp corners. What’s more, those bionic microchannels demonstrate marvelous microfluidic performance with strong precursor effects enabled by their sharp corners. Most significantly, those special properties of our bionic microchannels enable them outstanding step lifting performance to transport water to tens of millimeters, though the water can only be transported to at most 20 mm for a single bionic microchannel. The mimicked transpiration based on the step lifting of water from bionic microchannels is also achieved. Those precisely fabricated, low-cost, various cross-sectional bionic microchannels promise applications as microfluidic chips, long-distance unpowered water transportation, step lifting, mimicked transpiration, and so on.

[1]  Wenzhao Zhou,et al.  Tailoring mechanical properties of PμSL 3D-printed structures via size effect , 2022, International Journal of Extreme Manufacturing.

[2]  Xi Yuan,et al.  Self-shrinking soft demoulding for complex high-aspect-ratio microchannels , 2022, Nature Communications.

[3]  Zhongxu Lian,et al.  Bioinspired materials for droplet manipulation: Principles, methods and applications , 2022, Droplet.

[4]  Z. Dong,et al.  Three-Dimensional Open Water Microchannel Transpiration Mimetics. , 2022, ACS applied materials & interfaces.

[5]  Shiguo Zhang,et al.  Inorganic crosslinked supramolecular binder with fast Self-Healing for high performance silicon based anodes in Lithium-Ion batteries. , 2022, Journal of colloid and interface science.

[6]  Ce Zhang,et al.  Two-dimensional ultrathin networked CoP derived from Co(OH)2 as efficient electrocatalyst for hydrogen evolution , 2022, Advanced Composites and Hybrid Materials.

[7]  Zhaolong Wang,et al.  3D Printable Silicone Rubber for Long-Lasting and Weather-Resistant Wearable Devices , 2022, ACS Applied Polymer Materials.

[8]  Zhaolong Wang,et al.  3D printed hydrogel for soft thermo-responsive smart window , 2022, International Journal of Extreme Manufacturing.

[9]  Yongping Chen,et al.  Underwater Unidirectional Cellular Fluidics. , 2022, ACS applied materials & interfaces.

[10]  F. Chen,et al.  Underwater gas self-transportation along femtosecond laser-written open superhydrophobic surface microchannels (<100 µm) for bubble/gas manipulation , 2021, International Journal of Extreme Manufacturing.

[11]  H. Duan,et al.  3D printed ultra-fast photothermal responsive shape memory hydrogel for microrobot , 2021, International Journal of Extreme Manufacturing.

[12]  Yahua Liu,et al.  Three-dimensional capillary ratchet-induced liquid directional steering , 2021, Science.

[13]  O. Pybus,et al.  Viral infection and transmission in a large, well-traced outbreak caused by the SARS-CoV-2 Delta variant , 2021, Nature communications.

[14]  H. Duan,et al.  3D printed super-anti-freezing self-adhesive human-machine interface , 2021, Materials Today Physics.

[15]  H. Duan,et al.  3D-Printed Bioinspired Cassie-Baxter Wettability for Controllable Microdroplet Manipulation. , 2020, ACS applied materials & interfaces.

[16]  Qiang Zhang,et al.  3D printing of multi-scalable structures via high penetration near-infrared photopolymerization , 2020, Nature Communications.

[17]  Tak-Sing Wong,et al.  Compact nanoscale textures reduce contact time of bouncing droplets , 2020, Science Advances.

[18]  P. Cheng,et al.  An experimental study of a nearly perfect absorber made from a natural hyperbolic material for harvesting solar energy , 2020 .

[19]  Xiangnan He,et al.  Projection micro stereolithography based 3D printing and its applications , 2020, International Journal of Extreme Manufacturing.

[20]  Mark A. Skylar-Scott,et al.  Voxelated soft matter via multimaterial multinozzle 3D printing , 2019, Nature.

[21]  Z. Dong,et al.  Bioinspired inner microstructured tube controlled capillary rise , 2019, Proceedings of the National Academy of Sciences.

[22]  J. Voldman,et al.  Microfluidics in structured multimaterial fibers , 2018, Proceedings of the National Academy of Sciences.

[23]  Yi Zhang,et al.  Ultrafast water harvesting and transport in hierarchical microchannels , 2018, Nature Materials.

[24]  Zhongze Gu,et al.  3D Printing of Bioinspired Liquid Superrepellent Structures , 2018, Advanced materials.

[25]  J. Lewis,et al.  3D Printing of Customized Li‐Ion Batteries with Thick Electrodes , 2018, Advanced materials.

[26]  Jakob A. Faber,et al.  3D printing of robotic soft actuators with programmable bioinspired architectures , 2018, Nature Communications.

[27]  N. Miljkovic,et al.  Exploring the Role of Habitat on the Wettability of Cicada Wings. , 2017, ACS applied materials & interfaces.

[28]  Dishit P. Parekh,et al.  3D printing of liquid metals as fugitive inks for fabrication of 3D microfluidic channels. , 2016, Lab on a chip.

[29]  Deyuan Zhang,et al.  Continuous directional water transport on the peristome surface of Nepenthes alata , 2016, Nature.

[30]  Yong He,et al.  A facile and low-cost micro fabrication material: flash foam , 2015, Scientific Reports.

[31]  X. Duan,et al.  Two-photon polymerization microfabrication of hydrogels: an advanced 3D printing technology for tissue engineering and drug delivery. , 2015, Chemical Society reviews.

[32]  D. Beebe,et al.  The present and future role of microfluidics in biomedical research , 2014, Nature.

[33]  C. Thaulow,et al.  Surface Structure and Wetting Characteristics of Collembola Cuticles , 2014, PloS one.

[34]  G. Watson,et al.  Fouling of nanostructured insect cuticle: adhesion of natural and artificial contaminants , 2011, Biofouling.

[35]  I. Mudawar,et al.  Analytical heat diffusion models for different micro-channel heat sink cross-sectional geometries , 2010 .

[36]  T. Wheeler,et al.  The transpiration of water at negative pressures in a synthetic tree , 2008, Nature.

[37]  W. Jong,et al.  Flows in rectangular microchannels driven by capillary force and gravity , 2007 .

[38]  Frantisek Svec,et al.  Injection molded microfluidic chips featuring integrated interconnects. , 2006, Lab on a chip.

[39]  Kristen L. Helton,et al.  Microfluidic Overview of Global Health Issues Microfluidic Diagnostic Technologies for Global Public Health , 2006 .

[40]  Rustem F Ismagilov,et al.  Formation of Arrayed Droplets by Soft Lithography and Two‐Phase Fluid Flow, and Application in Protein Crystallization , 2004, Advanced materials.

[41]  George W. Koch,et al.  The limits to tree height , 2004, Nature.

[42]  I. Mezić,et al.  Chaotic Mixer for Microchannels , 2002, Science.

[43]  Wilhelm Barthlott,et al.  Wettability and Contaminability of Insect Wings as a Function of Their Surface Sculptures , 1996 .

[44]  Z. Liu,et al.  Ultrahigh broadband absorption in metamaterials with electric and magnetic polaritons enabled by multiple materials , 2022, International Journal of Heat and Mass Transfer.

[45]  Yongan Huang,et al.  Programmable robotized ‘transfer-and-jet’ printing for large, 3D curved electronics on complex surfaces , 2021, International Journal of Extreme Manufacturing.

[46]  D. Beebe,et al.  Physics and applications of microfluidics in biology. , 2002, Annual review of biomedical engineering.