A facile route for preparation of gradient wettability surface on copper substrate with contact angle changing from 90.3°to4.2°was developed.The Cu(OH)2 nanoribbon arrays were electrochemically deposited o...A facile route for preparation of gradient wettability surface on copper substrate with contact angle changing from 90.3°to4.2°was developed.The Cu(OH)2 nanoribbon arrays were electrochemically deposited on copper foil via a modified anodization technology,and the growth degree and density of the Cu(OH)2 arrays may be controlled varying with position along the substrate by slowly adding aqueous solution of KOH into the two-electrode cell of an anodization system to form the gradient surface.The prepared surface was water resistant and thermal stable,which could keep its gradient wetting property after being immersed in water bath at 100℃ for 10 h.The results of scanning electron microscopy(SEM),X-ray diffraction(XRD) and X-ray photoelectron spectroscopy(XPS) demonstrate that the distribution of Cu(OH)2 nanoribbon arrays on copper surface are responsible for the gradient wettability.展开更多
Thermoregulatory textiles,leveraging high-emissivity structural materials,have arisen as a promising candidate for personal cooling management;however,their advancement has been hindered by the underperformed water mo...Thermoregulatory textiles,leveraging high-emissivity structural materials,have arisen as a promising candidate for personal cooling management;however,their advancement has been hindered by the underperformed water moisture transportation capacity,which impacts on their thermophysiological comfort.Herein,we designed a wettability-gradient-induced-diode(WGID)membrane achieving by MXene-engineered electrospun technology,which could facilitate heat dissipation and moisture-wicking transportation.As a result,the obtained WGID membrane could obtain a cooling temperature of 1.5℃ in the“dry”state,and 7.1℃ in the“wet”state,which was ascribed to its high emissivity of 96.40%in the MIR range,superior thermal conductivity of 0.3349 W m^(-1) K^(-1)(based on radiation-and conduction-controlled mechanisms),and unidirectional moisture transportation property.The proposed design offers an approach for meticulously engineering electrospun membranes with enhanced heat dissipation and moisture transportation,thereby paving the way for developing more efficient and comfortable thermoregulatory textiles in a high-humidity microenvironment.展开更多
The self-driven behavior of droplets on a functionalized surface,coupled with wetting gradient and wedge patterns,is systematically investigated using molecular dynamics(MD)simulations.The effects of key factors,inclu...The self-driven behavior of droplets on a functionalized surface,coupled with wetting gradient and wedge patterns,is systematically investigated using molecular dynamics(MD)simulations.The effects of key factors,including wedge angle,wettability,and wetting gradient,on the droplet self-driving effect is revealed from the nanoscale.Results indicate that the maximum velocity of droplets on hydrophobic wedge-shaped surfaces increases with the wedge angle,accompanied by a rapid attenuation of driving force;however,the average velocity decreases with the increased wedge angle.Conversely,droplet movement on hydrophilic wedge-shaped surfaces follows the opposite trend,particularly in terms of average velocity compared to the hydrophobic case.Both wedge-shaped and composite gradient wedge-shaped surfaces are found to induce droplet motion,with droplets exhibiting higher speeds and distances on hydrophobic surfaces compared to hydrophilic surfaces,regardless of surface type.Importantly,the inclusion of wettability gradients significantly influences droplet motion,with hydrophobic composite gradient wedge-shaped surfaces showing considerable improvements in droplet speed and distance compared to their hydrophilic counterparts.By combining suitable wettability gradients with wedge-shaped surfaces,the limitations inherent in the wettability gradient range and wedge-shaped configuration can be mitigated,thereby enhancing droplet speed and distance.The findings presented in this paper offer valuable insights for the design of advanced functional surfaces tailored for manipulating droplets in real-world applications.展开更多
The impact of underwater bubbles on solid surfaces with a gradient wettability is important for fundamental science and technological applications. Despite progress in the translational motion of underwater bubbles on...The impact of underwater bubbles on solid surfaces with a gradient wettability is important for fundamental science and technological applications. Despite progress in the translational motion of underwater bubbles on asymmetric surface, a fundamental dynamic understanding of asymmetrical bounce behavior of the underwater bubble needs to be further improved.Herein, we investigate asymmetrical bounce of underwater bubbles after impacting the wettability gradient copper mesh surface.Asymmetrical bounce of the underwater bubble on the wettability gradient mesh(WGM) surface is composed by asymmetrical spread in the spread process and asymmetrical recoil in the recoil process, which induce the unidirectional movement behavior.Additionally, effective bubble-size manipulation can be easily implemented due to different volumes of bubbles remaining at different locations of WGM surface. We envision that this work will provide a new understanding of asymmetrical bounce behavior of the underwater bubble on the wettability gradient surface, and propose a novel and feasible strategy for constructing the underwater bubble manipulation system.展开更多
The study of a droplet spreading on a circular cylinder under gravity was carried out using the pseudo-potential lattice Boltzmann high-density ratios multiphase model with a non-ideal Peng–Robinson equation of state...The study of a droplet spreading on a circular cylinder under gravity was carried out using the pseudo-potential lattice Boltzmann high-density ratios multiphase model with a non-ideal Peng–Robinson equation of state. The calculation results indicate that the motion of the droplet on the cylinder can be divided into three stages: spreading, sliding, and aggregating.The contact length and contact time of a droplet on a cylindrical surface can be affected by factors such as the wettability gradient of the cylindrical wall, the Bond number, and droplet size. Furthermore, phase diagrams showing the relationship between Bond number, cylinder wall wettability gradient, and contact time as well as maximum contact length for three different droplet sizes are given. A theoretical foundation for additional research into the heat and mass transfer process between the droplet and the cylinder can be established by comprehending the variable rules of maximum contact length and contact time.展开更多
Regenerative fuel cells can operate alternately as an electrolyzer and as a fuel cell,frequently involving water as a reactant or product.Modifying the electrode surface to manipulate water can prevent electrode flood...Regenerative fuel cells can operate alternately as an electrolyzer and as a fuel cell,frequently involving water as a reactant or product.Modifying the electrode surface to manipulate water can prevent electrode flooding and enhance the electrode's mass transfer efficiency by facilitating better contact with gaseous reactants.However,conventional electrodes face difficulties in allowing water droplets to penetrate in a single direction leaving electrodes.In this work to address this issue,a wettability gradient electrode is designed and fabricated for efficient water manipulation in regenerative fuel cells.The findings demonstrate that the water removal strategy in the electrolyzer mode yields the highest ammonia yield and Faradaic efficiency of 3.39×10-10 mol s-1 cm-2 and 0.49%,respectively.Furthermore,in the fuel cell mode,the discharging process sustains for approximately 20.5 h,which is six times longer than the conventional strategy.The ability to sustain the discharging process for extended periods is particularly advantageous in regenerative fuel cells,as it enables the cells to operate for longer periods without the need for regeneration.展开更多
To investigate the microscopicmechanism underlying the influence of surface-chemical gradient on heat andmass recovery,a molecular dynamicsmodel including droplet condensation and transport process has been developed ...To investigate the microscopicmechanism underlying the influence of surface-chemical gradient on heat andmass recovery,a molecular dynamicsmodel including droplet condensation and transport process has been developed to examine heat and mass recovery performance.This work aimed at identify optimal conditions for enhancing heat and mass recovery through the combination of wettability gradient and nanopore transport.For comprehensive analysis,the structure in the simulation was categorized into three distinct groups:a homogeneous structure,a small wettability gradient,and a large wettability gradient.The homogeneous surface demonstrated low efficiency in heat and mass transfer,as evidenced by filmwise condensation.In contrast,the surface with a small wettability gradient experienced a transition from dropwise condensation to filmwise condensation,resulting in a gradual decrease in the efficiency of vapor heat and mass transfer.Only a large wettability gradient could achieve periodic and efficient dropwise condensation heat and mass transfer which was attributed to the rapid droplet coalescence and transport to the nanopore after condensing on the cold surface.展开更多
Excessive exudate at wound sites increases treatment difficulty and severely decelerates the healing process.In wound exu-date management,dressings with unidirectional liquid transport capability have exhibited enormo...Excessive exudate at wound sites increases treatment difficulty and severely decelerates the healing process.In wound exu-date management,dressings with unidirectional liquid transport capability have exhibited enormous potential.However,it remains challenging to improve the one-way liquid transport efficiency.Herein,a trilayered fibrous dressing is constructed by sequentially electrospinning polyurethane(PU)and polyvinylidene fluoride(PVDF)onto cotton fabric.Through hot pressing,a stable wettability gradient is formed across the PVDF/PU/cotton dressing due to the melting and bridging of PU nanofib-ers.The trilayered dressing exhibited rapid unidirectional transport with water penetrating from the hydrophobic side to the hydrophilic side in 6 s.The hydrostatic pressure from the hydrophilic side to the hydrophobic side is 569%higher than that from the hydrophobic side to the hydrophilic side,indicating that the dressing has a profound unidirectional conductivity.In vivo experiments demonstrates that the trilayered dressing can accelerate the wound healing process,especially in the early stages of wound occurrence,by quickly draining the excessive exudate.This study provides a new method to construct wound dressings with wettability gradients,which are advantageous for efficient exudate removal.展开更多
Loop heat pipes(LHPs),as high-efficiency heat dissipation components,are considered to be superior thermal conductors beyond any known materials.To apply LHPs to mobile electronics,a small,thin and compact system need...Loop heat pipes(LHPs),as high-efficiency heat dissipation components,are considered to be superior thermal conductors beyond any known materials.To apply LHPs to mobile electronics,a small,thin and compact system needs to be designed.However,with the trend of miniaturization,the heat transfer performance of LHPs degrades rapidly due to the significant increase of working fluid backflow resistance.This work aims to propose an effective solution to this problem.In this work,the surface wettability gradient(SWG)is introduced into the ultra-thin LHP,and the influence of SWG on mass and heat transfer performance is studied comprehensively by using a transient three-dimensional numerical model.It is observed that the SWG can significantly increase the vapor-liquid circulation efficiency and improve heat transfer performance.Numerical experiments have been performed to compare the two kinds of LHPs with and without SWG.At the heat load of 4–6 W,the start-up time for LHP with SWG is shortened by 11.5%and the thermal resistance is reduced by about 44.3%,compared with the LHP without SWG.This work provides a solution for the performance-degradation problem caused by miniaturization,as a numerical reference for experiments.展开更多
Controllable transportation of bubbles in surfactant or aqueous is very important in daily chemical products,food fermentation,mineral flotation and other fields.However,bubbles are mainly dominated by buoyancy and mo...Controllable transportation of bubbles in surfactant or aqueous is very important in daily chemical products,food fermentation,mineral flotation and other fields.However,bubbles are mainly dominated by buoyancy and move upward in solution,which makes the manipulation of bubbles difficult.Although some progress has been made in controlling underwater bubbles,achieving continuous transportation and collection of underwater bubbles without relying on external forces is still a great challenge.To this end,we bionically designed a flexible polydimethylsiloxane(PDMS)porous surface with dual-Janus characteristics.Namely,a porous PDMS membrane integrating structural gradient and wettability gradient realizes the underwater anti-buoyancy unidirectional transportation of bubbles without external force input,and possesses the capability of underwater gas anti-buoyancy transportation and storage.This work provides inspiration and direction for the development and design of underwater gas transportation and storage devices and provides innovative thinking for the implementation of seabed carbon dioxide storage technology.展开更多
基金Project(S2012010010417)supported by the Guangdong Natural Science Foundation,ChinaProject(20130172110008)supported by the Specialized Research Fund for the Doctoral Program of Higher Education of China
文摘A facile route for preparation of gradient wettability surface on copper substrate with contact angle changing from 90.3°to4.2°was developed.The Cu(OH)2 nanoribbon arrays were electrochemically deposited on copper foil via a modified anodization technology,and the growth degree and density of the Cu(OH)2 arrays may be controlled varying with position along the substrate by slowly adding aqueous solution of KOH into the two-electrode cell of an anodization system to form the gradient surface.The prepared surface was water resistant and thermal stable,which could keep its gradient wetting property after being immersed in water bath at 100℃ for 10 h.The results of scanning electron microscopy(SEM),X-ray diffraction(XRD) and X-ray photoelectron spectroscopy(XPS) demonstrate that the distribution of Cu(OH)2 nanoribbon arrays on copper surface are responsible for the gradient wettability.
基金financial support from the National Natural Science Foundation of China(“Study of Multi-Responsive Shape Memory Polyurethane Nanocomposites Inspired by Natural Fibers”,Grant No.51673162)Startup Grant of CityU(“Laboratory of Wearable Materials for Healthcare”,Grant No.9380116).CityU PhD Scholarship.
文摘Thermoregulatory textiles,leveraging high-emissivity structural materials,have arisen as a promising candidate for personal cooling management;however,their advancement has been hindered by the underperformed water moisture transportation capacity,which impacts on their thermophysiological comfort.Herein,we designed a wettability-gradient-induced-diode(WGID)membrane achieving by MXene-engineered electrospun technology,which could facilitate heat dissipation and moisture-wicking transportation.As a result,the obtained WGID membrane could obtain a cooling temperature of 1.5℃ in the“dry”state,and 7.1℃ in the“wet”state,which was ascribed to its high emissivity of 96.40%in the MIR range,superior thermal conductivity of 0.3349 W m^(-1) K^(-1)(based on radiation-and conduction-controlled mechanisms),and unidirectional moisture transportation property.The proposed design offers an approach for meticulously engineering electrospun membranes with enhanced heat dissipation and moisture transportation,thereby paving the way for developing more efficient and comfortable thermoregulatory textiles in a high-humidity microenvironment.
基金supported by the National Natural Science Foundation of China(No.52206073)the University Outstanding Youth Fund Project of Anhui Province(Nos.2022AH020028 and 2022AH030037)+2 种基金the Natural Science Foundation of Anhui Province(Nos.1908085QF292 and 2308085ME173)Anhui Province Outstanding Young Talents Support Program(No.gxyqZD2022058)Guangdong Basic and Applied Basic Research Foundation(Nos.2024A1515011379 and 2023A1515110613).
文摘The self-driven behavior of droplets on a functionalized surface,coupled with wetting gradient and wedge patterns,is systematically investigated using molecular dynamics(MD)simulations.The effects of key factors,including wedge angle,wettability,and wetting gradient,on the droplet self-driving effect is revealed from the nanoscale.Results indicate that the maximum velocity of droplets on hydrophobic wedge-shaped surfaces increases with the wedge angle,accompanied by a rapid attenuation of driving force;however,the average velocity decreases with the increased wedge angle.Conversely,droplet movement on hydrophilic wedge-shaped surfaces follows the opposite trend,particularly in terms of average velocity compared to the hydrophobic case.Both wedge-shaped and composite gradient wedge-shaped surfaces are found to induce droplet motion,with droplets exhibiting higher speeds and distances on hydrophobic surfaces compared to hydrophilic surfaces,regardless of surface type.Importantly,the inclusion of wettability gradients significantly influences droplet motion,with hydrophobic composite gradient wedge-shaped surfaces showing considerable improvements in droplet speed and distance compared to their hydrophilic counterparts.By combining suitable wettability gradients with wedge-shaped surfaces,the limitations inherent in the wettability gradient range and wedge-shaped configuration can be mitigated,thereby enhancing droplet speed and distance.The findings presented in this paper offer valuable insights for the design of advanced functional surfaces tailored for manipulating droplets in real-world applications.
基金supported by the China Postdoctoral Science Foundation (2021TQ0023, 2022TQ0022, 2022M720012)the National Natural Science Foundation of China (52303143, 22005015,22105014)+5 种基金the National Key R&D Program of China (2019YFB1309702)Beijing Young Talent Support ProgramTianmushan Laboratory Research Project (TK2023C018)Beijing Nova Program (20220484213)the 111Projectthe Fundamental Research Funds for the Central Universities。
文摘The impact of underwater bubbles on solid surfaces with a gradient wettability is important for fundamental science and technological applications. Despite progress in the translational motion of underwater bubbles on asymmetric surface, a fundamental dynamic understanding of asymmetrical bounce behavior of the underwater bubble needs to be further improved.Herein, we investigate asymmetrical bounce of underwater bubbles after impacting the wettability gradient copper mesh surface.Asymmetrical bounce of the underwater bubble on the wettability gradient mesh(WGM) surface is composed by asymmetrical spread in the spread process and asymmetrical recoil in the recoil process, which induce the unidirectional movement behavior.Additionally, effective bubble-size manipulation can be easily implemented due to different volumes of bubbles remaining at different locations of WGM surface. We envision that this work will provide a new understanding of asymmetrical bounce behavior of the underwater bubble on the wettability gradient surface, and propose a novel and feasible strategy for constructing the underwater bubble manipulation system.
文摘The study of a droplet spreading on a circular cylinder under gravity was carried out using the pseudo-potential lattice Boltzmann high-density ratios multiphase model with a non-ideal Peng–Robinson equation of state. The calculation results indicate that the motion of the droplet on the cylinder can be divided into three stages: spreading, sliding, and aggregating.The contact length and contact time of a droplet on a cylindrical surface can be affected by factors such as the wettability gradient of the cylindrical wall, the Bond number, and droplet size. Furthermore, phase diagrams showing the relationship between Bond number, cylinder wall wettability gradient, and contact time as well as maximum contact length for three different droplet sizes are given. A theoretical foundation for additional research into the heat and mass transfer process between the droplet and the cylinder can be established by comprehending the variable rules of maximum contact length and contact time.
基金supported by a grant from the National Natural Science Foundation of China(52161160333)a grant from the Research Grants Council of the Hong Kong Special Administrative Region,China(N_PolyU559/21)a grant from the Research Institute for Sports Science and Technology at The Hong Kong Polytechnic University(CD5L).
文摘Regenerative fuel cells can operate alternately as an electrolyzer and as a fuel cell,frequently involving water as a reactant or product.Modifying the electrode surface to manipulate water can prevent electrode flooding and enhance the electrode's mass transfer efficiency by facilitating better contact with gaseous reactants.However,conventional electrodes face difficulties in allowing water droplets to penetrate in a single direction leaving electrodes.In this work to address this issue,a wettability gradient electrode is designed and fabricated for efficient water manipulation in regenerative fuel cells.The findings demonstrate that the water removal strategy in the electrolyzer mode yields the highest ammonia yield and Faradaic efficiency of 3.39×10-10 mol s-1 cm-2 and 0.49%,respectively.Furthermore,in the fuel cell mode,the discharging process sustains for approximately 20.5 h,which is six times longer than the conventional strategy.The ability to sustain the discharging process for extended periods is particularly advantageous in regenerative fuel cells,as it enables the cells to operate for longer periods without the need for regeneration.
基金supported by the National Natural Science Foundation of China(No.52206093)the University Outstanding Youth Fund Project of Anhui Province(Nos.2022AH020028 and 2022AH030037)+2 种基金the Natural Science Foundation of Anhui Province(Nos.1908085QF292 and 2308085ME173)Anhui Province Outstanding Young Talents Support Program(No.gxyqZD2022058)Guangdong Basic and Applied Basic Research Foundation(Nos.2024A1515011379 and 2023A1515110613).
文摘To investigate the microscopicmechanism underlying the influence of surface-chemical gradient on heat andmass recovery,a molecular dynamicsmodel including droplet condensation and transport process has been developed to examine heat and mass recovery performance.This work aimed at identify optimal conditions for enhancing heat and mass recovery through the combination of wettability gradient and nanopore transport.For comprehensive analysis,the structure in the simulation was categorized into three distinct groups:a homogeneous structure,a small wettability gradient,and a large wettability gradient.The homogeneous surface demonstrated low efficiency in heat and mass transfer,as evidenced by filmwise condensation.In contrast,the surface with a small wettability gradient experienced a transition from dropwise condensation to filmwise condensation,resulting in a gradual decrease in the efficiency of vapor heat and mass transfer.Only a large wettability gradient could achieve periodic and efficient dropwise condensation heat and mass transfer which was attributed to the rapid droplet coalescence and transport to the nanopore after condensing on the cold surface.
基金supported by a grant from the National Natural Science Foundation of China(51973195)Zhejiang Provincial Key Research and Development Program(2020C03042)“Ten Thousand Plan”-Zhejiang Provincial High Level Talents Special Support Plan(2020R52023).
文摘Excessive exudate at wound sites increases treatment difficulty and severely decelerates the healing process.In wound exu-date management,dressings with unidirectional liquid transport capability have exhibited enormous potential.However,it remains challenging to improve the one-way liquid transport efficiency.Herein,a trilayered fibrous dressing is constructed by sequentially electrospinning polyurethane(PU)and polyvinylidene fluoride(PVDF)onto cotton fabric.Through hot pressing,a stable wettability gradient is formed across the PVDF/PU/cotton dressing due to the melting and bridging of PU nanofib-ers.The trilayered dressing exhibited rapid unidirectional transport with water penetrating from the hydrophobic side to the hydrophilic side in 6 s.The hydrostatic pressure from the hydrophilic side to the hydrophobic side is 569%higher than that from the hydrophobic side to the hydrophilic side,indicating that the dressing has a profound unidirectional conductivity.In vivo experiments demonstrates that the trilayered dressing can accelerate the wound healing process,especially in the early stages of wound occurrence,by quickly draining the excessive exudate.This study provides a new method to construct wound dressings with wettability gradients,which are advantageous for efficient exudate removal.
基金financial supports from the Science and Technology Innovation Commission of Shenzhen(Grant No.JCYJ20190809154007586)National Key Research and Development Program of China(Grant No.2017YFE0120800)+1 种基金National Natural Science Foundation of China(Grant No.U20A20241 and No.51702277)Science and Technology Development Fund of the Macao Special Administrative Region(Grant No.FDCT/013/2017/AMJ)。
文摘Loop heat pipes(LHPs),as high-efficiency heat dissipation components,are considered to be superior thermal conductors beyond any known materials.To apply LHPs to mobile electronics,a small,thin and compact system needs to be designed.However,with the trend of miniaturization,the heat transfer performance of LHPs degrades rapidly due to the significant increase of working fluid backflow resistance.This work aims to propose an effective solution to this problem.In this work,the surface wettability gradient(SWG)is introduced into the ultra-thin LHP,and the influence of SWG on mass and heat transfer performance is studied comprehensively by using a transient three-dimensional numerical model.It is observed that the SWG can significantly increase the vapor-liquid circulation efficiency and improve heat transfer performance.Numerical experiments have been performed to compare the two kinds of LHPs with and without SWG.At the heat load of 4–6 W,the start-up time for LHP with SWG is shortened by 11.5%and the thermal resistance is reduced by about 44.3%,compared with the LHP without SWG.This work provides a solution for the performance-degradation problem caused by miniaturization,as a numerical reference for experiments.
基金supported by the National Natural Science Foundation of China (22105014,21871020,52303143)the China Postdoctoral Science Foundation (2020M680296,2022T150035,2021TQ0023)+4 种基金the High-level Talent Project of Shenyang Ligong Universitythe Special fund of Basic Scientific Research Expenses for Undergraduate Universities in Liaoning Province (LJ212410144077,LJ212410144072)the Beijing Young Talent Support Programthe 111 Projectthe Fundamental Research Funds for the Central Universities。
文摘Controllable transportation of bubbles in surfactant or aqueous is very important in daily chemical products,food fermentation,mineral flotation and other fields.However,bubbles are mainly dominated by buoyancy and move upward in solution,which makes the manipulation of bubbles difficult.Although some progress has been made in controlling underwater bubbles,achieving continuous transportation and collection of underwater bubbles without relying on external forces is still a great challenge.To this end,we bionically designed a flexible polydimethylsiloxane(PDMS)porous surface with dual-Janus characteristics.Namely,a porous PDMS membrane integrating structural gradient and wettability gradient realizes the underwater anti-buoyancy unidirectional transportation of bubbles without external force input,and possesses the capability of underwater gas anti-buoyancy transportation and storage.This work provides inspiration and direction for the development and design of underwater gas transportation and storage devices and provides innovative thinking for the implementation of seabed carbon dioxide storage technology.
