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2. Pneumatic programmable superrepellent surfaces

Author

Songtao Hu, Xiaobao Cao, Tom Reddyhoff, Xijia Ding, Xi Shi, Daniele Dini, Andrew J. deMello, Zhike Peng, and Zuankai Wang

Subjects
Descriptive and experimental mechanics, QC120-168.85
Abstract

Abstract Morphological transformation of surface structures is widely manifested in nature and highly preferred for many applications such as wetting interaction; however, in situ tuning of artificial morphologies independent of smart responsive materials remains elusive. Here, with the aid of microfluidics, we develop a pneumatic programmable superrepellent surface by tailoring conventional wetting materials (e.g., polydimethylsiloxane) with embedded flexible chambers connecting a microfluidic system, thus realizing a morphological transformation for enhanced liquid repellency based on a nature‐inspired rigid‐flexible hybrid principle (i.e., triggering symmetry breaking and oscillator coupling mechanisms). The enhancement degree can be in situ tuned within around 300 ms owing to pneumatically controllable chamber morphologies. We also demonstrate that the surface can be freely programmed to achieve elaborated morphological pathways and gradients for preferred droplet manipulation such as directional rolling and bouncing. Our study highlights the potential of an in situ morphological transformation to realize tunable wettability and provides a programmable level of droplet control by intellectualizing conventional wetting materials.

Published
2022
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3. Continuous Isotropic-Nematic Transition in Amyloid Fibril Suspensions Driven by Thermophoresis

Author

Daniele Vigolo, Jianguo Zhao, Stephan Handschin, Xiaobao Cao, Andrew J. deMello, and Raffaele Mezzenga

Subjects
Medicine, Science
Abstract

The isotropic and nematic (I + N) coexistence for rod-like colloids is a signature of the first-order thermodynamics nature of this phase transition. However, in the case of amyloid fibrils, the biphasic region is too small to be experimentally detected, due to their extremely high aspect ratio. Herein, we study the thermophoretic behaviour of fluorescently labelled β-lactoglobulin amyloid fibrils by inducing a temperature gradient across a microfluidic channel. We discover that fibrils accumulate towards the hot side of the channel at the temperature range studied, thus presenting a negative Soret coefficient. By exploiting this thermophoretic behaviour, we show that it becomes possible to induce a continuous I-N transition with the I and N phases at the extremities of the channel, starting from an initially single N phase, by generating an appropriate concentration gradient along the width of the microchannel. Accordingly, we introduce a new methodology to control liquid crystal phase transitions in anisotropic colloidal suspensions. Because the induced order-order transitions are achieved under stationary conditions, this may have important implications in both applied colloidal science, such as in separation and fractionation of colloids, as well as in fundamental soft condensed matter, by widening the accessibility of target regions in the phase diagrams.

Published
2017
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5. Towards an active droplet-based microfluidic platform for programmable fluid handling

Author

Xiaobao Cao, Tomas Buryska, Tianjin Yang, Jing Wang, Peter Fischer, Aaron Streets, Stavros Stavrakis, and Andrew deMello

Subjects
Biomedical Engineering, Bioengineering, General Chemistry, Biochemistry
Abstract

Droplet-based microfluidic systems have emerged as powerful alternatives to conventional high throughput screening platforms, due to their operational flexibility, high-throughput nature and ability to efficiently process small fluid volumes. However, the challenges associated with performing bespoke operations on user-defined droplets often limit their utility in screening applications that involve complex workflows. To this end, the marriage of droplet- and valve-based microfluidic technologies offers the prospect of balancing the controllability of droplet manipulations and analytical throughput. In this spirit, we present a microfluidic platform that combines the capabilities of integrated microvalve technology with droplet-based sample compartmentalization to realize a highly adaptable programmable fluid handling functionality. The microfluidic device consists of a programmable formulator linked to an automated droplet generation device and storage array. The formulator leverages multiple inputs coupled to a mixing ring to produce combinatorial solution mixtures, with a peristaltic pump enabling titration of reagents into the ring with picoliter resolution. The platform allows for the execution of user-defined reaction protocols within an array of storage chambers by consecutively merging programmable sequences of pL-volume droplets containing specified reagents. The precision in formulating solutions with small differences in concentration is perfectly suited for the accurate estimation of kinetic parameters. The utility of our platform is showcased through the performance of enzymatic kinetic measurements of beta-galactosidase and horseradish peroxidase with fluorogenic substrates. The presented platform provides for a range of automated manipulations and paves the way for a more diverse range of droplet-based biological experiments., Lab on a Chip, 23 (8), ISSN:1473-0197, ISSN:1473-0189

Published
2023

6. Programmable Control of Multiscale Droplets using V-Valves

Author

Tian Xue, Ankit Jain, Xiaobao Cao, David Hess, Stavros Stavrakis, and Andrew de Mello

Subjects
titration, on-demand, droplets, Mechanics of Materials, microfluidics, dilution, General Materials Science, Industrial and Manufacturing Engineering
Abstract

Contemporary droplet-based microfluidic platforms generate large numbers of sub-nanoliter (, Advanced Materials Technologies, 8 (7), ISSN:2365-709X

Published
2023

7. Multi-compartment supracapsules made from nano-containers towards programmable release

Author

Minghan Hu, Nico Reichholf, Yanming Xia, Laura Alvarez, Xiaobao Cao, Shenglin Ma, Andrew J. deMello, and Lucio Isa

Subjects
Nanocapsules, Mechanics of Materials, Process Chemistry and Technology, Capsules, General Materials Science, Electrical and Electronic Engineering, Nanostructures
Abstract

The assembly of nanomaterials into suprastructures offers the possibility to fabricate larger scale functional materials, whose inner structure strongly influences their functionality for a vast range of applications. In spite of the many current strategies, achieving multi-compartment structures in a targeted and versatile way remains highly challenging. Here, we describe a controllable and straightforward route to create uniform suprastructured materials with a multi-compartmentalized architecture by confining primary nanocapsules into droplets using a cross-junction microfluidic device. Following solvent evaporation from the droplets, the nanocapsules spontaneously assemble into precisely sized multi-compartment particles, which we term supracapsules. Thanks to the process, each spatially separated nanocapsule unit retains its cargo and functionalities within the resulting supracapsules. However, new collective properties emerge, and, particularly, programmable release profiles that are distinct from those of single-compartment capsules. Finally, the suprastructures can be disassembled into single-compartment units by applying ultra-sonication, switching their release to a burst-release mode. These findings open up exciting opportunities to fabricate multi-compartment suprastructures incorporating diverse functionalities for materials with emerging properties., Materials Horizons, 9 (6), ISSN:2051-6347, ISSN:2051-6355

Published
2022
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8. Microfluid Switching-Induced Transient Refractive Interface

Author

Jiukai Tang, Guangyu Qiu, Xiaobao Cao, Andrew deMello, and Jing Wang

Subjects
Fluid Flow and Transfer Processes, Refractometry, Process Chemistry and Technology, Microfluidics, Hydrodynamics, Bioengineering, Microfluidic Analytical Techniques, Instrumentation
Abstract

The laminar flow interface (LFI) developed at low Reynolds numbers is one of the most prominent features of microscale flows and has been employed in a diverse range of optofluidic applications. The formation of LFIs usually requires the manipulation of multiple streams within a microchannel using a complex hydrodynamic pumping system. Herein, we present a new type of LFI that is generated by fluid switching within a three-dimensional (3D) microlens-incorporating microfluidic chip (3D-MIMC). Since Poiseuille flows exhibit a parabolic velocity profile, the LFI is cone-like in shape and acts as a transient refractive interface (TRI), which is sensitive to the refractive index (

Published
2022

9. PDMS-PUA bi-directional replication technology and its applications

Author

Jian Jin, Zhong Wang, Jun Wu, ZhenHua Yu, XiaoBao Cao, and XuDi Wang

Subjects
Electrical and Electronic Engineering, Engineering (miscellaneous), Atomic and Molecular Physics, and Optics
Abstract

Polydimethylsiloxane (PDMS) and polyurethane acrylate (PUA) are excellent pattern transfer materials. In this study, PDMS-PUA bi-directional replication technology is explored using the PDMS grating as a template, and relevant technical issues are discussed in detail. Special surface treatment and process optimization are applied to solve the problems of demolding, PDMS polymerization inhibition, and substrate flatness. Further experiments show that the technology can be employed to replicate nanoscale structures and has the potential value of prolonging the longevity of the original template. Additionally, utilizing the advantage of the high elasticity of PDMS materials, two applications of bi-directional replication technology are demonstrated. One is to increase the line-density of the grating by stretching, and the experimental results show that the line-density of the grating increased by 26.6%. The other one is to fabricate the convex grating. Compared with the original planar PDMS grating, the resolution of the first-order diffraction spectrum of the convex grating at the focal point has been greatly improved. Since this technology requires simple equipment, and PDMS and PUA are reusable, it has the advantages of low cost, simplicity, and rapid fabrication. The two application examples also indicate that the technology has good application value.

Published
2022

10. Flexibility-Patterned Liquid-Repelling Surfaces

Author

Xi Shi, Tom Reddyhoff, Daniele Dini, Zhike Peng, Songtao Hu, Andrew J. deMello, Xiaobao Cao, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Technology, Materials science, Materials Science, Evaporation, 3D printing, Materials Science, Multidisciplinary, Rigidity (psychology), Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, 09 Engineering, liquid evaporation, liquid repellency, General Materials Science, Redistribution (chemistry), Nanoscience & Nanotechnology, CONTACT TIME, Flexibility (engineering), Science & Technology, LOTUS, business.industry, Oscillation, DROPLET, artificial surface, droplet impact, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Science & Technology - Other Topics, LASER, Wetting, 03 Chemical Sciences, 0210 nano-technology, business, Reduction (mathematics)
Abstract

Droplets impacting solid surfaces is ubiquitous in nature and of practical importance in numerous industrial applications. For liquid-repelling applications, rigidity-based asymmetric redistribution and flexibility-based structural oscillation strategies have been proven on artificial surfaces; however, these are limited by strict impacting positioning. Here, we show that the gap between these two strategies can be bridged by a flexibility-patterned design similar to a trampoline park. Such a flexibility-patterned design is realized by three-dimensional projection micro-stereolithography and is shown to enhance liquid repellency in terms of droplet impalement resistance and contact time reduction. This is the first demonstration of the synergistic effect obtained by a hybrid solution that exploits asymmetric redistribution and structural oscillation in liquid-repelling applications, paving the rigidity-flexibility cooperative way of wettability tuning. Also, the flexibility-patterned surface is applied to accelerate liquid evaporation.

Published
2021
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11. Measuring Airborne Antibiotic Resistance Genes in Swiss Cities via a DNA-Enabled Electrochemical Chip-Based Sensor

Author

Bei Liu, Fuze Jiang, Yile Tao, Tong Zheng, Yang Yue, Viktoria Tepper, Xiaobao Cao, and Jing Wang

Subjects
air pollution, antibiotic resistance genes, electrochemical biosensor, bioaerosols, General Medicine
Abstract

Antibiotic resistance genes (ARGs) as an emerging airborne pollutants are a significant and growing concern for public and environmental health. Accurate surveillance and quantitation of low-dose ARGs in the air have become critical in providing evidence-based public risk assessment for population health management. With this work, we introduced a portable and sensitive electrochemical (EC) bioanalytical platform for detecting airborne ARGs, which relied on the EC current response of surface-initiated ARGs hybridization. These low-cost chips for EC ARGs sensing exhibited good thermal (25∼60 °C) and long-term stability (6 days). The prototype of the biosensor system demonstrated an ultralow limit of detection (7.4 fM) and excellent anti-interference performance. For the first time, an EC sensor was applied successfully to identify and quantitate two types of ARGs (floR and bla-TEM genes) from real-world PM2.5 (particulate matter with aerodynamic diameters less than 2.5 μm) samples. Results for PM2.5 collected from Bern (urban area), Basel (suburban area), Zürich (urban area), Sion (airport highway area), and Rigi (rural and high-altitude area) in Switzerland were obtained, in favorable agreement with gel electrophoresis analysis. The results indicated that our EC biosensor offered a reliable and attractive alternative to the current methods for airborne ARG detection. ISSN:2690-0645

Published
2022

12. Laminar Flow-Based Fiber Fabrication and Encoding via Two-Photon Lithography

Author

Jing Wang, Songtao Hu, Stavros Stavrakis, Shangkun Li, Andrew J. deMello, Peter Fischer, Xiaobao Cao, and Quan Gao

Subjects
Materials science, business.industry, Microfluidics, Laminar flow, Multiphoton lithography, law.invention, chemistry.chemical_compound, Monomer, chemistry, Polymerization, law, Particle, Optoelectronics, General Materials Science, Fiber, Photolithography, business
Abstract

In recent years, flow photolithography (FL) has emerged as a powerful synthetic tool for the creation of barcoded microparticles with complex morphologies and chemical compositions which have been shown to be useful in a range of multiplexed bioassay applications. More specifically, FL has been highly successful in producing micron-sized, encoded particles of bespoke shape, size, and color. That said, to date, FL has been restricted to generating barcoded microparticles and has lacked the ability to produce hybrid fibers which are structurally and spectrally encoded. To this end, we herein present a method that combines a continuous flow microfluidic system with two-photon polymerization (2PP) to fabricate microscale-encoded fibers and Janus strips in a high-throughput manner. Specifically, two co-flow liquid streams containing a monomer and initiator are introduced through a Y-shape channel to form a stable interface in the center of a microfluidic channel. The flow containing the (fluorescently labeled) monomer is then patterned by scanning the voxel of the 2PP laser across the interface to selectively polymerize different regions of the forming fiber/particle. Such a process allows for rapid spectral encoding at the single fiber level, with the resulting structurally coded fibers having obvious application in the fields of security identification and anticounterfeiting.

Published
2020
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13. DropCRISPR: A LAMP-Cas12a based digital method for ultrasensitive detection of nucleic acid

Author

Hui Wu, Xiaobao Cao, Yingchao Meng, Daniel Richards, Jian Wu, Zhangying Ye, and Andrew J. deMello

Subjects
Salmonella typhimurium, Molecular Diagnostic Techniques, Nucleic Acids, Electrochemistry, Biomedical Engineering, Biophysics, General Medicine, Biosensing Techniques, CRISPR-Cas Systems, Nucleic Acid Amplification Techniques, Biotechnology
Abstract

Since their discovery, CRISPR/Cas systems have been extensively exploited in nucleic acid biosensing. However, the vast majority of contemporary platforms offer only qualitative detection of nucleic acid, and fail to realize ultrasensitive quantitative detection. Herein, we report a digital droplet-based platform (DropCRISPR), which combines loop-mediated isothermal amplification (LAMP) with CRISPR/Cas12a to realize ultrasensitive and quantitative detection of nucleic acids. This is achieved through a novel two-step microfluidic system which combines droplet LAMP with a picoinjector capable of injecting the required CRISPR/Cas12a reagents into each droplet. This method circumvents the temperature incompatibilities of LAMP and CRISPR/Cas12a and avoids mutual interference between amplification reaction and CRISPR detection. Ultrasensitive detection (at fM level) was achieved for a model plasmid containing the invA gene of Salmonella typhimurium (St), with detection down to 10

Published
2022

14. Rigid-flexible hybrid surfaces for water-repelling and abrasion-resisting

Author

Songtao Hu, Weifeng Huang, Jinbang Li, Tom Reddyhoff, Xiaobao Cao, Xi Shi, Zhike Peng, Andrew Demello, and Daniele Dini

Subjects
Mechanical Engineering, abrasion, surface, hydrophobic, droplet impact, Surfaces, Coatings and Films
Abstract

Droplets impacting solid superhydrophobic surfaces is appealing not only because of scientific interests but also for technological applications such as water-repelling. Recent studies have designed artificial surfaces in a rigid-flexible hybrid mode to combine asymmetric redistribution and structural oscillation water-repelling principles, resolving strict impacting positioning; however, this is limited by weak mechanical durability. Here we propose a rigid-flexible hybrid surface (RFS) design as a matrix of concave flexible trampolines barred by convex rigid stripes. Such a surface exhibits a 20.1% contact time reduction via the structural oscillation of flexible trampolines, and even to break through the theoretical inertial-capillary limit via the asymmetric redistribution induced by rigid stripes. Moreover, the surface is shown to retain the above water-repelling after 1,000 abrasion cycles against oilstones under a normal load as high as 0.2 N.mm(-1). This is the first demonstration of RFSs for synchronous waterproof and wearproof, approaching real-world applications of liquid-repelling., Friction, ISSN:2223-7704, ISSN:2223-7690

Published
2022
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16. Replicating the Cynandra opis Butterfly's Structural Color for Bioinspired Bigrating Color Filters

Author

Xiaobao Cao, Ying Du, Yujia Guo, Guohang Hu, Ming Zhang, Lu Wang, Jiangtao Zhou, Quan Gao, Peter Fischer, Jing Wang, Stavros Stavrakis, and Andrew deMello

Subjects
Photons, Light, Mechanics of Materials, Mechanical Engineering, Animals, Color, General Materials Science, Butterflies, Nanostructures
Abstract

Multilayer grating structures, such as those found on the wings of the butterfly Cynandra opis, are able to interact with light to generate structural coloration. When illuminated and viewed at defined angles, such structural color is characterized by exceptional purity and brightness. To provide further insight into the mechanism of structural coloration, two-photon laser lithography is used to fabricate bioinspired bigrating nanostructures, whose optical properties may be controlled by variation of the height and period of the grating features. Through the use of both spectral measurements and finite-element method simulations, herein specific feature dimensions are identified that due to the combined effects of multilayer interference and diffraction generate excellent spectral characteristics and high color purity over the entire visible range. Additionally, it is demonstrated that variation of feature period and/or height plays a central role in controlling both hue and purity. Importantly, such tuneable bigrating structures are of significant utility in color filtering applications.

Published
2021

17. Self-aligned 3D microlenses in a chip fabricated with two-photon stereolithography for highly sensitive absorbance measurement

Author

Xiaobao Cao, Jiukai Tang, Yang Yue, Jean Schmitt, Jing Wang, Guangyu Qiu, and Xiaole Zhang

Subjects
Detection limit, Analyte, Materials science, business.industry, 010401 analytical chemistry, Microfluidics, Biomedical Engineering, Bioengineering, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Chip, 01 natural sciences, Biochemistry, 0104 chemical sciences, law.invention, Absorbance, law, Miniaturization, Optoelectronics, 0210 nano-technology, business, Stereolithography, Optical path length
Abstract

Absorbance measurement is a widely used method to quantify the concentration of an analyte. The integration of absorbance analysis in microfluidic chips could significantly reduce the sample consumption and contribute to the system miniaturization. However, the sensitivity and limit of detection (LoD) of analysis in microfluidic chips with conventional configuration need improvements due to the limited optical pathway and unregulated light propagation. In this work, a 3D-microlens-incorporating microfluidic chip (3D-MIMC) with a greatly extended detection channel was innovatively fabricated using two-photon stereolithography. The fabrication was optimized with a proposed hierarchical modular printing strategy. Due to the incorporation of 3D microlenses, the light coupling efficiency and the signal-to-noise ratio (SNR) were respectively improved approximately 9 and 4 times. An equivalent optical path length (EOL) of 62.9 mm was achieved in a 3.7 μl detection channel for testing tartrazine samples. As a result, the sensitivity and LoD of the 3D-MIMC assay were correspondingly improved by one order of magnitude, compared with those of the 96-well plate assay. Notably, the 3D-MIMC has the potential to be integrated into a general microanalysis platform for multiple applications.

Published
2020
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19. An addressable electrowetting valve for centrifugal microfluidics

Author

Yanming Xia, Chao Song, Yingchao Meng, Peng Xue, Andrew J. deMello, Quan Gao, Stavros Stavrakis, Shenglin Ma, and Xiaobao Cao

Subjects
Materials Chemistry, Metals and Alloys, Electrical and Electronic Engineering, Condensed Matter Physics, Instrumentation, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Published
2022
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20. Biomimetic water-repelling surfaces with robustly flexible structures

Author

Tom Reddyhoff, Songtao Hu, Xi Shi, Daniele Dini, Zhike Peng, Xiaobao Cao, Andrew J. deMello, Jinbang Li, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Surface (mathematics), Technology, biomimetic surface, Materials science, Materials Science, friction, Mechanical engineering, Rigidity (psychology), Materials Science, Multidisciplinary, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, 09 Engineering, ENERGY, Robustness (computer science), liquid repellency, General Materials Science, Nanoscience & Nanotechnology, Microscale chemistry, CONTACT TIME, Flexibility (engineering), Science & Technology, Oscillation, DROPLET, 3D printing, Tribology, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Shear (sheet metal), droplet transport, Science & Technology - Other Topics, 0210 nano-technology, 03 Chemical Sciences
Abstract

Biomimetic liquid-repelling surfaces have been the subject of considerable scientific research and technological application. To design such surfaces, a flexibility-based oscillation strategy has been shown to resolve the problem of liquid-surface positioning encountered by the previous, rigidity-based asymmetry strategy; however, its usage is limited by weak mechanical robustness and confined repellency enhancement. Here, we design a flexible surface comprising mesoscale heads and microscale spring sets, in analogy to the mushroomlike geometry discovered on springtail cuticles, and then realize this through three-dimensional projection microstereolithography. Such a surface exhibits strong mechanical robustness against ubiquitous normal and shear compression and even endures tribological friction. Simultaneously, the surface elevates water repellency for impacting droplets by enhancing impalement resistance and reducing contact time, partially reaching an improvement of ∼80% via structural tilting movements. This is the first demonstration of flexible interfacial structures to robustly endure tribological friction as well as to promote water repellency, approaching real-world applications of water repelling. Also, a flexibility gradient is created on the surface to directionally manipulate droplets, paving the way for droplet transport.

Published
2021

21. In Situ Visualization of the Structural Evolution and Alignment of Lyotropic Liquid Crystals in Confined Flow

Author

Marianne Liebi, Xiaobao Cao, Viviane Lutz-Bueno, Martin Andersson, Roland Kádár, and A. Rodríguez-Palomo

Subjects
Materials science, scanning small angle X-ray scattering, lyotropic liquid crystals, microfluidics, nanostructures, rheology, self-assembly, X-ray imaging, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biomaterials, Physics::Fluid Dynamics, Lamellar phase, Liquid crystal, General Materials Science, Lamellar structure, Shear thinning, Hexagonal phase, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Shear rate, Shear (sheet metal), Condensed Matter::Soft Condensed Matter, Chemical physics, Lyotropic liquid crystal, 0210 nano-technology, Biotechnology
Abstract

Self-assembled materials such as lyotropic liquid crystals offer a wide variety of structures and applications by tuning the composition. Understanding materials behavior under flow and the induced alignment is wanted in order to tailor structure related properties. A method to visualize the structure and anisotropy of ordered systems in situ under dynamic conditions is presented where flow-induced nanostructural alignment in microfluidic channels is observed by scanning small angle X-ray scattering in hexagonal and lamellar self-assembled phases. In the hexagonal phase, the material in regions with high extensional flow exhibits orientation perpendicular to the flow and is oriented in the flow direction only in regions with a high enough shear rate. For the lamellar phase, a flow-induced morphological transition occurs from aligned lamellae toward multilamellar vesicles. However, the vesicles do not withstand the mechanical forces and break in extended lamellae in regions with high shear rates. This evolution of nanostructure with different shear rates can be correlated with a shear thinning viscosity curve with different slopes. The results demonstrate new fundamental knowledge about the structuring of liquid crystals under flow. The methodology widens the quantitative investigation of complex structures and identifies important mechanisms of reorientation and structural changes., Small, 17 (7), ISSN:1613-6810, ISSN:1613-6829

Published
2021

22. A sample-in-digital-answer-out system for rapid detection and quantitation of infectious pathogens in bodily fluids

Author

Stavros Stavrakis, Andrew J. deMello, Jaebum Choo, Chen Zhu, Zhiyang Li, Haowen Yang, Nongyue He, Philip D. Howes, and Xiaobao Cao

Subjects
DNA, Bacterial, 0301 basic medicine, Time Factors, Nucleic acid quantitation, Computer science, Point-of-Care Systems, Microfluidics, Recombinase Polymerase Amplification, 01 natural sciences, Biochemistry, Fluorescence, Analytical Chemistry, 03 medical and health sciences, Cartridge, Limit of Detection, Lab-On-A-Chip Devices, Humans, Tuberculosis, Saliva, business.industry, 010401 analytical chemistry, Pipette, Equipment Design, Mycobacterium tuberculosis, Molecular diagnostics, DNA extraction, 0104 chemical sciences, Standard curve, 030104 developmental biology, business, Computer hardware
Abstract

A variety of automated sample-in-answer-out systems for in vitro molecular diagnostics have been presented and even commercialized. Although efficient in operation, they are incapable of quantifying targets, since quantitation based on analog analytical methods (via standard curve analysis) is complex, expensive, and challenging. To address this issue, herein, we describe an integrated sample-in-digital-answer-out (SIDAO) diagnostic system incorporating DNA extraction and digital recombinase polymerase amplification, which enables rapid and quantitative nucleic acid analysis from bodily fluids within a disposable cartridge. Inside the cartridge, reagents are pre-stored in sterilized tubes, with an automated pipetting module allowing facile liquid transfer. For digital analysis, we fabricate a simple, single-layer polydimethylsiloxane microfluidic device and develop a novel and simple sample compartmentalization strategy. Sample solution is partitioned into an array of 40,044 fL-volume microwells by sealing the microfluidic device through the application of mechanical pressure. The entire analysis is performed in a portable, fully automated instrument. We evaluate the quantitative capabilities of the system by analyzing Mycobacterium tuberculosis genomic DNA from both spiked saliva and serum samples, and demonstrate excellent analytical accuracy and specificity. This SIDAO system provides a promising diagnostic platform for quantitative nucleic acid testing at the point-of-care. Graphical abstract ᅟ.

Published
2018
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23. An optofluidic system with integrated microlens arrays for parallel imaging flow cytometry

Author

Stavros Stavrakis, Jaebum Choo, Andrew J. deMello, Gregor Holzner, Xiaobao Cao, and Ying Du

Subjects
Image formation, Computer science, Biomedical Engineering, Magnification, Bioengineering, Field of view, 02 engineering and technology, 01 natural sciences, Biochemistry, Flow cytometry, Reduction (complexity), Jurkat Cells, Optics, medicine, Humans, Lenses, Microlens, medicine.diagnostic_test, business.industry, Optical Imaging, 010401 analytical chemistry, Resolution (electron density), Equipment Design, General Chemistry, Flow Cytometry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Parallel imaging, 0210 nano-technology, business
Abstract

In recent years, high-speed imaging has become increasingly effective for the rapid analysis of single cells in flowing environments. Single cell imaging methods typically incorporate a minimum magnification of 10× when extracting sizing and morphological information. Although information content may be significantly enhanced by increasing magnification, this is accompanied by a corresponding reduction in field of view, and thus a decrease in the number of cells assayed per unit time. Accordingly, the acquisition of high resolution data from wide field views remains an unsolved challenge. To address this issue, we present an optofluidic flow cytometer integrating a refractive, microlens array (MLA) for imaging cells at high linear velocities, whilst maximizing the number of cells per field of view. To achieve this, we adopt an elasto-inertial approach for cell focusing within an array of parallel microfluidic channels, each equipped with a microlens. We characterize the optical performance of the microlenses in terms of image formation, magnification and resolution using both ray-tracing simulations and experimental measurements. Results demonstrate that the optofluidic platform can efficiently count and magnify micron-sized objects up to 4 times. Finally, we demonstrate the capabilities of the platform as an imaging flow cyclometer, demonstrating the efficient discrimination of hB and Jurkat cells at throughputs up to 50 000 cells per second.

Published
2018
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24. Oscillatory Viscoelastic Microfluidics for Efficient Focusing and Separation of Nanoscale Species

Author

Daniel van Leeuwen, Andrew J. deMello, Bogdan Mateescu, Stavros Stavrakis, Mohammad Asghari, Xiaobao Cao, and Mahmut Kamil Aslan

Subjects
Materials science, Surface Properties, Viscosity, Microfluidics, General Engineering, viscoelastic microfluidics, extracellular vesicles, oscillatory flow, exosomes, Brownian motion, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, Microfluidic Analytical Techniques, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Extracellular vesicles, Bacteriophage lambda, Viscoelasticity, 0104 chemical sciences, Biological species, DNA, Viral, Particle, General Materials Science, Particle Size, 0210 nano-technology, Nanoscopic scale, Oscillatory flow
Abstract

The ability to precisely control particle migration within microfluidic systems is essential for focusing, separating, counting, and detecting a wide range of biological species. To date, viscoelastic microfluidic systems have primarily been applied to the focusing, separation, and isolation of micrometer-sized species, with their use in nanoparticle manipulations being underdeveloped and underexplored, due to issues related to nanoparticle diffusivity and a need for extended channel lengths. To overcome such issues, we herein present sheathless oscillatory viscoelastic microfluidics as a method for focusing and separating both micrometer and sub-micrometer species. To highlight the efficacy of our approach, we segment our study into three size regimes, namely, micrometer (where characteristic particle dimensions are above 1 μm), sub-micrometer (where characteristic dimensions are between 1 μm and 100 nm), and nano (where characteristic dimensions are below 100 nm) regimes. Based on the ability to successfully manipulate particles in all these regimes, we demonstrate the successful isolation of p-bodies from biofluids (in the micrometer regime), the focusing of λ-DNA (in the sub-micrometer regime), and the focusing of extracellular vesicles (in the nanoregime). Finally, we characterize the physics underlying viscoelastic microflows using a dimensionless number that relates the lateral velocity (due to elastic effects) to the diffusion constant of the species within the viscoelastic carrier fluid. Based on the ability to precisely manipulate species in all three regimes, we expect that sheathless oscillatory viscoelastic microfluidics may be used to good effect in a range of biological and life science applications.

Published
2020

25. Liquid repellency enhancement through flexible microstructures

Author

Daniele Dini, Songtao Hu, Xi Shi, Xiaobao Cao, Debashis Puhan, Tom Reddyhoff, Jing Wang, Zhike Peng, Sorin-Cristian Vladescu, Andrew J. deMello, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Multidisciplinary, Materials science, Applied Sciences and Engineering, Contact time, Materials Science, Metamaterial, SciAdv r-articles, Nanotechnology, Microstructure, Maskless lithography, Research Articles, Research Article
Abstract

Artificial liquid-repellent surfaces have attracted substantial scientific and industrial attention with a focus on creating functional topological features; however, the role of the underlying structures has been overlooked. Recent developments in micro-nanofabrication allow us now to construct a skin-muscle type system combining interfacial liquid repellence atop a mechanically functional structure. Specifically, we design surfaces comprising bioinspired, mushroom-like repelling heads and spring-like flexible supports, which are realized by three-dimensional direct laser lithography. The flexible supports elevate liquid repellency by resisting droplet impalement and reducing contact time. This, previously unknown, use of spring-like flexible supports to enhance liquid repellency provides an excellent level of control over droplet manipulation. Moreover, this extends repellent microstructure research from statics to dynamics and is envisioned to yield functionalities and possibilities by linking functional surfaces and mechanical metamaterials., Science Advances, 6 (32), ISSN:2375-2548

Published
2020

26. Self-Compensating Liquid-Repellent Surfaces with Stratified Morphology

Author

Debashis Puhan, Sorin-Cristian Vladescu, Xiaobao Cao, Tom Reddyhoff, Andrew J. deMello, Daniele Dini, Qian Wang, Zhike Peng, Xi Shi, Songtao Hu, Hu, Songtao [0000-0002-8405-3788], Puhan, Debashis [0000-0002-7353-8528], deMello, Andrew J [0000-0003-1943-1356], Dini, Daniele [0000-0002-5518-499X], Apollo - University of Cambridge Repository, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Technology, Science & Technology, Materials science, Fabrication, Artificial surface, Materials Science, 3D laser lithography, friction, Materials Science, Multidisciplinary, Nanotechnology, artificial surface, 09 Engineering, Contact angle, WEAR, mechanical robustness, liquid repellency, Science & Technology - Other Topics, LASER, General Materials Science, Nanoscience & Nanotechnology, 03 Chemical Sciences, Maskless lithography, ANTIREFLECTION
Abstract

Artificial liquid-repellent surfaces have recently attracted vast scientific attention; however, achieving mechanical robustness remains a formidable challenge before industrialization can be realized. To this end, inspired by plateaus in geological landscapes, a self-compensating strategy is developed to pave the way for the synthesis of durable repellent surfaces. This self-compensating surface comprises tall hydrophobic structural elements, which can repel liquid droplets. When these elements are damaged, they expose shorter structural elements that also suspend the droplets and thus preserve interfacial repellency. An example of this plateau-inspired stratified surface was created by three-dimensional (3D) direct laser lithography micro-nano fabrication. Even after being subjected to serious frictional damage, it maintained static repellency to water with a contact angle above 147° and was simultaneously able to endure high pressures arising from droplet impacts. Extending the scope of nature-inspired functional surfaces from conventional biomimetics to geological landscapes, this work demonstrates that the plateau-inspired self-compensating strategy can provide an unprecedented level of robustness in terms of sustained liquid repellency.

Published
2020
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27. Growing and Shaping Metal–Organic Framework Single Crystals at the Millimeter Scale

Author

Alessandro Sorrenti, Josep Puigmartí-Luis, Xiaobao Cao, Semih Sevim, Andrew J. deMello, Lewis S. Jones, and Carlos Martí-Gastaldo

Subjects
Chemistry, Scale (chemistry), Crystal growth, Nanotechnology, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, law.invention, Colloid and Surface Chemistry, Simulated microgravity, law, Metal-organic framework, Crystallization, Crystal habit, Biomineralization
Abstract

Controlling and understanding the mechanisms that harness crystallization processes is of utmost importance in contemporary materials science and, in particular, in the realm of reticular solids where it still remains a great challenge. In this work, we show that environments mimicking microgravity conditions can harness the size and shape of functional biogenic crystals such as peptide-based metal–organic frameworks (MOFs). In particular, we demonstrate formation of the largest single crystals with controlled nonequilibrium shapes of peptide-based MOFs reported to date (e.g., those featuring curved crystal habits), as opposed to the typical polyhedral microcrystals obtained under bulk crystallization conditions. Such unique nonequilibrium morphologies arise from the interplay between the diffusion-controlled supply of precursors in simulated microgravity environments and the physical constraints imposed during crystal growth. In fact, our method mimics two main strategies of morphogenesis in biomineralization, i.e., spatial and morphological control, both being largely unexplored in the field of self-assembled functional materials. The presented results may open new opportunities to study and understand fundamental questions of relevance to materials science, such as how the size and shape of artificial crystals can influence their properties and functions while providing a strategy to tailor the size and shape of peptide-based MOF single crystals to specific applications.

Published
2020
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28. A Counter Propagating Lens-Mirror System for Ultrahigh Throughput Single Droplet Detection

Author

Ying Du, Jordan Van Wyk, Andrew J. deMello, Jing Wang, Andreas M. Küffner, Paolo Arosio, Peter Fischer, Xiaobao Cao, and Stavros Stavrakis

Subjects
Photon, Materials science, Microfluidics, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, Biomaterials, law, Lab-On-A-Chip Devices, General Materials Science, Throughput (business), Photons, Parabolic reflector, business.industry, Detector, Optical Devices, General Chemistry, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Lens (optics), Optoelectronics, droplets, fluorescence, microfluidics, optics, single‐cell, 0210 nano-technology, business, Excitation, Biotechnology, Communication channel
Abstract

Fluorescence-based detection schemes provide for multiparameter analysis in a broad range of applications in the chemical and biological sciences. Toward the realization of fully portable analysis systems, microfluidic devices integrating diverse functional components have been implemented in a range of out-of-lab environments. That said, there still exits an unmet and recognized need for miniaturized, low-cost, and sensitive optical detection systems, which provide not only for efficient molecular excitation, but also enhanced photon collection capabilities. To this end, an optofluidic platform that is adept at enhancing fluorescence light collection from microfluidic channels is presented. The central component of the detection module is a monolithic parabolic mirror located directly above the microfluidic channel, which acts to enhance the number of emitted photons reflected toward the detector. In addition, two-photon polymerization is used to print a microscale-lens below the microfluidic flow channel and directly opposite the mirror, to enhance the delivery of excitation radiation into the channel. Using such an approach, it is demonstrated that fluorescence signals can be enhanced by over two orders of magnitude, with component parallelization enabling the detection of pL-volume droplets at rates up to 40 000 droplets per second.

Published
2019

29. Oscillatory Viscoelastic Microfluidics for Efficient Focusing and Separation of Nanoscale Species

Author

Daniel van Leeuwen, Andrew J. deMello, Bogdan Mateescu, Mohammad Asghari, Xiaobao Cao, and Stavros Stavrakis

Subjects
Physics::Fluid Dynamics, Materials science, Microfluidics, Nano, Particle, Nanoparticle, Nanotechnology, Thermal diffusivity, Fick's laws of diffusion, Nanoscopic scale, Viscoelasticity
Abstract

The ability to precisely control particle migration within microfluidic systems is essential for focusing, separating, counting and detecting a wide range of biological species. To date, viscoelastic microfluidic systems have primarily been applied to the focusing, separation and isolation of micron-sized species, with their use in nanoparticle manipulations being underdeveloped and underexplored, due to issues related to nanoparticle diffusivity and a need for extended channel lengths. To overcome such issues, we herein present sheathless oscillatory viscoelastic microfluidics as a method for focusing and separating both micron and sub-micron species. To highlight the efficacy of our approach, we segment our study into three size regimes, namely micron (where characteristic particle dimensions are above 1 μm), sub-micron (where characteristic dimensions are between 1 μm and 100 nm) and nano (where characteristic dimensions are below 100 nm) regimes. Based on the ability to successfully manipulate particles in all these regimes, we demonstrate the successful isolation of p-bodies from biofluids (in the micron regime), the focusing of λ-DNA (in the sub-micron regime) and the focusing of extracellular vesicles (in the nano-regime). Finally, we characterize the physics underlying viscoelastic microflows using a dimensionless number that relates the lateral velocity (due to elastic effects) to the diffusion constant of the species within the viscoelastic carrier fluid. Based on the ability to precisely manipulate species in all three regimes, we expect that sheathless oscillatory viscoelastic microfluidics will provide for significant new opportunities in a range of biological and life science applications.

Published
2019
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30. Three-dimensional printed surfaces inspired by bi-Gaussian stratified plateaus

Author

Xi Shi, Xiaobao Cao, Weifeng Huang, Daniele Dini, Tom Reddyhoff, Zhike Peng, Songtao Hu, Debashis Puhan, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Surface (mathematics), stratified morphology, 0306 Physical Chemistry (incl. Structural), Materials science, Artificial surface, Gaussian, 3D laser lithography, 0904 Chemical Engineering, wettability, Geometry, 02 engineering and technology, 0303 Macromolecular and Materials Chemistry, artificial surface, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, symbols.namesake, symbols, General Materials Science, Wetting, droplet manipulation, Nanoscience & Nanotechnology, 0210 nano-technology, Maskless lithography
Abstract

Wettability of artificial surfaces is attracting increasing attention for its relevant technological applications. Functional performance is often achieved by mimicking the topographical structures found in natural flora and fauna; however, surface attributes inspired by geological landscapes have so far escaped attention. We reproduced a stratified morphology of plateaus with a bi-Gaussian height distribution using a three-dimensional direct laser lithography. The plateau-inspired artificial surface exhibits a hydrophobic behavior even if fabricated from a hydrophilic material, giving rise to a new wetting mechanism that divides the well-known macroscopic Wenzel and Cassie states into four substates. We have also successfully applied the plateau-inspired structure to droplet manipulation.

Published
2019

31. A Micromolding Method for Transparent and Flexible Thin‐Film Supercapacitors and Hybrid Supercapacitors

Author

Xiaobao Cao, Runyu Yan, Markus Niederberger, Andrew J. deMello, Liu Tian, Haijian Huang, and Long Pan

Subjects
Materials science, Oxide, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Energy storage, law.invention, Biomaterials, chemistry.chemical_compound, law, Nano, Electrochemistry, Thin film, Supercapacitor, Graphene, business.industry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, chemistry, Electrode, Optoelectronics, 0210 nano-technology, business, Current density
Abstract

Thin‐film supercapacitors are promising candidates for energy storage in wearable electronics due to their mechanical flexibility, high power density, long cycling life, and fast‐charging capability. In addition to all of these features, device transparency would open up completely new opportunities in wearable devices, virtual reality or in heads‐up displays for vehicle navigation. Here a method is introduced for micromolding Ag/porous carbon and Ag/NixFeyOz@reduced graphene oxide (rGO) into grid‐like patterns on polyethylene terephthalate foils to produce transparent thin‐film supercapacitors and hybrid supercapacitors. The supercapacitor delivers a high areal capacitance of 226.8 µF cm−2 at a current density of 3 µA cm−2 and with a transparency of 70.6%. The cycling stability is preserved even after 1000 cycles under intense bending. A hybrid supercapacitor is additionally fabricated by integrating two electrodes of Ag/porous carbon and Ag/NixFeyOz@rGO. It offers an areal capacitance of 282.1 µF cm−2 at a current density of 3 µA cm−2, a transparency of 73.3% and the areal capacitance only decreases slightly under bending. This work indicates that micromolding of nano‐ and micro‐sized powders represents a powerful method for preparing regular electrode patterns, which are fundamental for the development of transparent energy storage devices.

Published
2020
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32. Single Droplet Detection: A Counter Propagating Lens‐Mirror System for Ultrahigh Throughput Single Droplet Detection (Small 20/2020)

Author

Ying Du, Paolo Arosio, Jing Wang, Peter M. Fischer, Stavros Stavrakis, Andrew J. deMello, Xiaobao Cao, Jordan Van Wyk, and Andreas M. Küffner

Subjects
Biomaterials, Lens (optics), Materials science, Optics, law, business.industry, Microfluidics, General Materials Science, General Chemistry, business, Throughput (business), Biotechnology, law.invention
Published
2020
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33. Enhanced versatility of fluid control in centrifugal microfluidic platforms using two degrees of freedom

Author

Katherine S. Elvira, Andrew J. deMello, and Xiaobao Cao

Subjects
Flexibility (engineering), Engineering, business.industry, 010401 analytical chemistry, Microfluidics, Biomedical Engineering, Bioengineering, Control engineering, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, 0104 chemical sciences, Two degrees of freedom, Fluid control, Technical innovation, Flow switching, Fluid dynamics, 0210 nano-technology, business, Servo
Abstract

Centrifugal microfluidic platforms have significant potential in commercial applications because of their operational flexibility and minimal external infrastructure requirements. However, the dynamic and real-time control of fluid flow within traditional centrifugal microfluidic platforms is problematic. To address this significant limitation, we propose a two degrees of freedom platform, in which a digital servo is located at each end of an arm driven by a motor. This allows for reversible inward pumping between multiple chambers with perfect efficiency. Furthermore, the addition of a second degree of freedom allows position-based pressure controlled burst valves to be accessed and operated in an independent fashion. To demonstrate the efficacy of this technical innovation, we show rapid and configurable flow switching between three target chambers within a centrifugal microfluidic device., Lab on a Chip, 16 (7), ISSN:1473-0197, ISSN:1473-0189

Published
2016
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34. Ice Shear Fracture on Nanowires with Different Wetting States

Author

Xiaobao Cao, Wang Shengkun, Chengyu Jiang, Yang He, Wei Tian, Yongcun Hao, Jin Xie, and Weizheng Yuan

Subjects
Materials science, Shear (geology), Wetting transition, Nanowire, Ice adhesion, General Materials Science, Nanotechnology, Wetting, Composite material, Contact area, Nanoscopic scale
Abstract

Understanding the function of nanoscale structure morphology in ice adhesion properties is important in deicing applications. The correlation between ice adhesion and nanowire morphology as well as the corresponding ice shear fracture mechanism are presented for the first time. Ice adhesion on nanowires was measured using a tangential ice-detaching instrument that was developed in-house. Stress analysis was performed using a COMSOL software. Nanowire surface shifted from Wenzel to Cassie transition and Cassie wetting states when the nanowire length was increased. Tangential ice-detaching forces were greater on the hydrophilic surface than those on the hydrophobic surface. Ice-ice internal shear fracture occurred on the ice and force probe contact area at the Wenzel state or on the ice and nanowire contact area at Cassie transition and Cassie state. Different lengths of nanowires caused different wetting states; thus, different fracture areas were formed, which resulted in different tangential ice-detaching forces. This paper presents a new way of tailoring surface ice adhesion via rational design of nanowire morphology with different wetting states.

Published
2014
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35. Reducing ice adhesion by hierarchical micro-nano-pillars

Author

Xiaobao Cao, Chengyu Jiang, Chen Jun, Yang He, Wei Tian, and Weizheng Yuan

Subjects
Materials science, Nano, Micro nano, General Physics and Astronomy, Ice adhesion, Nanotechnology, Surfaces and Interfaces, General Chemistry, Texture (crystalline), Wetting, Condensed Matter Physics, Surfaces, Coatings and Films, Smooth surface
Abstract

This study aimed to elucidate the role of bio-inspired texture geometry in wettability and ice adhesion. Micro/nano pillars with different geometric parameters were first designed and fabricated, and ice adhesions on textured surfaces were then measured using an apparatus developed in-house. The surface with hierarchical micro-nano-pillars herein had the least ice adhesion, which was far less than the surface with micro-pillars and smooth surface without any structure (MN

Published
2014
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36. Liquid repellency enhancement through flexible microstructures.

Author

Songtao Hu, Xiaobao Cao, Reddyhoff, Tom, Puhan, Debashis, Vladescu, Sorin-Cristian, Jing Wang, Xi Shi, Zhike Peng, deMello, Andrew J., and Dini, Daniele

Subjects
*ANTIREFLECTIVE coatings, *PHYSICAL sciences, *MATERIALS science, *MICROSTRUCTURE, *LIFE sciences, *VIBRATION (Mechanics)
Abstract

The article reports on science research based on material's science which discusses about artificial liquid-repellent surfaces have attracted substantial scientific and industrial attention with a focus on creating functional topological features. It informs about developments in micro-nanofabrication allow us now to construct a skin-muscle type system combining interfacial liquid repellence atop a mechanically functional structure.

Published
2020
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37. High response speed microfluidic ice valves with enhanced thermal conductivity and a movable refrigeration source

Author

Weichao Wu, Chaorun Si, Xiaobao Cao, and Songtao Hu

Subjects
Multidisciplinary, Materials science, Fabrication, 010401 analytical chemistry, Microfluidics, Structural biology, Chemical engineering, Refrigeration, Mechanical engineering, Response time, 02 engineering and technology, 021001 nanoscience & nanotechnology, Thermal conduction, 01 natural sciences, Article, 0104 chemical sciences, Thermal conductivity, Thermoelectric effect, Current (fluid), 0210 nano-technology, FOS: Chemical engineering
Abstract

Due to their ease of fabrication, facile use and low cost, ice valves have great potential for use in microfluidic platforms. For this to be possible, a rapid response speed is key and hence there is still much scope for improvement in current ice valve technology. Therefore, in this study, an ice valve with enhanced thermal conductivity and a movable refrigeration source has been developed. An embedded aluminium cylinder is used to dramatically enhance the heat conduction performance of the microfluidic platform and a movable thermoelectric unit eliminates the thermal inertia, resulting in a faster cooling process. The proposed ice valve achieves very short closing times (0.37 s at 10 μL/min) and also operates at high flow rates (1150 μL/min). Furthermore, the response time of the valve decreased by a factor of 8 when compared to current state of the art technology., Scientific Reports, 7, ISSN:2045-2322

Published
2017

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