Your search keyword '"Electrocapillarity"' showing total 312 results

1. Electrocapillarity‐Induced Hurricane‐in‐a‐Tube Enables the Generation and Patterning of Liquid Metal Droplets.

Author

Song, Chunlei, Tao, Xianzan, Chen, Yicheng, Mao, Kaihao, Tao, Ye, Ge, Zhenyou, Wen, Hongyan, Chen, Gaofeng, Li, Biao, Xue, Rui, Jiang, Xikai, Zheng, Xu, and Ren, Yukun

Subjects

*LIQUID metals, *COMPOSITE materials, *INTERFACIAL tension, *SURFACE tension, *ELECTRIC currents

Abstract

Room‐temperature liquid metal droplets (LMDs) are a promising material for various applications in soft robotics, active droplets, and biomedical devices. However, controllable and high‐throughput production of LMDs remains challenging due to their high surface tension and density. Here, a novel strategy is presented to produce LMDs by combining electric field‐induced electrocapillary flow with an external flow field. The basic mechanism is that the electrocapillary flow induced at the LMD/electrolyte interface forms a vortex ring in the electrolyte, creating a hurricane‐like effect in the tube, which in turn causes the liquid metal to deform and eventually pinch off into small droplets. It is demonstrated that droplet size and generation frequency can be controlled precisely by adjusting the applied electric current, flow rate, and surfactant concentration, establishing a relationship between radius and experimental parameters through dimensionless analysis. More importantly, this strategy can handle pendant droplets and facilitate programmable droplet patterning. Leveraging established relationships, flexible control over droplet size and spacing during patterning is attained. Furthermore, an iontronic pressure‐sensitive device based on LMDs and hydrogel is developed to showcase the versatility of the approach. This technique opens up new opportunities for fabricating soft circuits, composite materials, and other functional devices with LMDs. [ABSTRACT FROM AUTHOR]

Published

2024

2. A general mass transfer equation for gas-evolving electrodes.

Author

Haverkort, J.W.

Subjects

*MASS transfer, *NATURAL heat convection, *WATER electrolysis, *MARANGONI effect, *ELECTRODES, *MICROBUBBLES, *DISSOLVED air flotation (Water purification)

Abstract

Poor mass transport to or from vertical gas-evolving electrodes can adversely impact energy efficiency and product purity in the production of hydrogen, chlorine, and various metals. A proper description that combines natural convection with micromixing of growing, coalescing, and departing bubbles is presently lacking. This work develops a simple, physically sound analytical model that includes the influence of bubble size, flow regime, and bubble surface coverage. By comprehensively reviewing mass transfer measurements from the water electrolysis literature, we observe that the surface coverage of oxygen bubbles increases much more strongly with increasing current density than an often-used square root scaling predicts. Strong differences are observed in the degree of micromixing of hydrogen and oxygen bubbles in alkaline and acidic electrolytes. These varied results can all be explained by a combination of electrocapillarity, and coalescence induced by either a high surface coverage or Marangoni flows. [Display omitted] • A simple formula for adding micromixing and natural convection is derived. • A single micromixing parameter between 0 and 5 describes all literature data. • Micromixing is strongest for oxygen in alkaline and hydrogen in acidic electrolytes. • Marangoni forces are attractive in this case, causing coalescence and larger bubbles. • Bubble coverage increases with the square/square root of current for oxygen/hydrogen. [ABSTRACT FROM AUTHOR]

Published

2024

3. Electrowetting of Carbon‐based Materials for Advanced Electrochemical Technologies.

Author

Papaderakis, Athanasios A., Leketas, Mantas, Wei, Zixuan, Hwang, Imgon, Carbone, Paola, Juel, Anne, and Dryfe, Robert A. W.

Subjects

CARBON-based materials, CARBON nanofibers, ENERGY conversion, ELECTRIC fields, SURFACE tension, WETTING

Abstract

Wetting phenomena underpin a plethora of key processes occurring in nature and artificial systems. Subtle control over wetting can boost the performance of devices with applications in diverse technologies, spanning electrochemical energy conversion, storage, and capacitive deionization to variable micro‐/nano‐fluidics platforms and electro(nano)tribology. A common characteristic of these systems is their operation under application of an electric field that induces a series of electrochemical processes that can impact wetting. The dependence of wetting on the applied potential bias is referred to as electrowetting. Carbon‐based materials hold a central role as both active electrodes and additives in such systems due to their distinct physicochemical properties and versatile characteristics. Deciphering the mechanisms of electrowetting on carbon in contact with electrolytes of varied types and compositions requires the fundamental understanding of the underlying processes taking place at the carbon/electrolyte interface. Simultaneously, a systematic investigation of electrowetting can often provide significant insights into the properties of the interface. In this concept article, we discuss the latest advances in the area along with the current challenges and future directions of this recently revived research topic. [ABSTRACT FROM AUTHOR]

Published

2024

4. Electrowetting of Carbon‐based Materials for Advanced Electrochemical Technologies

Author

Dr. Athanasios A. Papaderakis, Mantas Leketas, Dr. Zixuan Wei, Dr. Imgon Hwang, Prof. Paola Carbone, Prof. Anne Juel, and Prof. Robert A. W. Dryfe

Subjects

electrowetting, electrocapillarity, wettability, surface tension, carbon, Industrial electrochemistry, TP250-261, Chemistry, QD1-999

Abstract

Abstract Wetting phenomena underpin a plethora of key processes occurring in nature and artificial systems. Subtle control over wetting can boost the performance of devices with applications in diverse technologies, spanning electrochemical energy conversion, storage, and capacitive deionization to variable micro‐/nano‐fluidics platforms and electro(nano)tribology. A common characteristic of these systems is their operation under application of an electric field that induces a series of electrochemical processes that can impact wetting. The dependence of wetting on the applied potential bias is referred to as electrowetting. Carbon‐based materials hold a central role as both active electrodes and additives in such systems due to their distinct physicochemical properties and versatile characteristics. Deciphering the mechanisms of electrowetting on carbon in contact with electrolytes of varied types and compositions requires the fundamental understanding of the underlying processes taking place at the carbon/electrolyte interface. Simultaneously, a systematic investigation of electrowetting can often provide significant insights into the properties of the interface. In this concept article, we discuss the latest advances in the area along with the current challenges and future directions of this recently revived research topic.

Published

2024

5. Investigating the electrowetting of silver‐based gas‐diffusion electrodes during oxygen reduction reaction with electrochemical and optical methods.

Author

Bienen, Fabian, Paulisch, Melanie C., Mager, Thorben, Osiewacz, Jens, Nazari, Manigah, Osenberg, Markus, Ellendorff, Barbara, Turek, Thomas, Nieken, Ulrich, Manke, Ingo, and Friedrich, K. Andreas

Subjects

*OXYGEN reduction, *ELECTROCHEMICAL electrodes, *DIFFUSION, *ELECTROLYSIS, *CURRENT density (Electromagnetism)

Abstract

Porous gas‐diffusion electrodes (GDEs) are widely used in electrochemical applications where a gaseous reactant is converted to a target product. Important applications for silver‐based GDEs are the chlor‐alkali and the CO2 electrolysis processes in which silver catalyzes the oxygen‐ or carbon dioxide reduction reaction. The wetting of the porous GDEs is of utmost importance for the achieved performance of the electrode: a completely dry electrode will result in low current densities due to the reduced active surface area while on the other hand, a completely flooded electrode will deteriorate the access of the gaseous reactant. Therefore, we investigated silver‐based GDEs for the oxygen reduction reaction with different amounts of the hydrophobic agent polytetrafluoroethylene (PTFE) and analyzed the potential‐induced wetting behavior (electrowetting). The electrolyte breakthrough was recorded by a digital microscope and subsequently evaluated via imaging analysis of the observed breached electrolyte droplets. In order to characterize the wetting state during transition to the steady‐state, we applied electrochemical impedance spectroscopy measurements and retrieved the double‐layer capacitance. Our results indicate that a higher overvoltage facilitates the breakthrough of electrolytes through the gas‐diffusion electrode. Surprisingly, a faster breakthrough of electrolyte was observed for electrodes with higher PTFE content. Porometry measurements revealed that the GDE with low PTFE content has a monomodal pore size distribution, whereas electrodes with higher PTFE amount exhibit a bimodal pore size distribution. In GDEs with monomodal pore size distribution the time in which the double layer capacitance is leveling off correlates with the breakthrough time of the electrolyte. In summary, we emphasize that the wetting of GDEs is a complex interplay of the applied potential, electrode composition, and resulting porous structure which requires further advanced measurements and analysis considering the parameters affecting the wetting behavior as a whole. [ABSTRACT FROM AUTHOR]

Published

2023

6. Investigating the electrowetting of silver‐based gas‐diffusion electrodes during oxygen reduction reaction with electrochemical and optical methods

Author

Fabian Bienen, Melanie C. Paulisch, Thorben Mager, Jens Osiewacz, Manigah Nazari, Markus Osenberg, Barbara Ellendorff, Thomas Turek, Ulrich Nieken, Ingo Manke, and K. Andreas Friedrich

Subjects

electrocapillarity, electrochemical impedance spectroscopy, electrowetting, gas‐diffusion electrode, imaging analysis, oxygen reduction reaction (ORR), Industrial electrochemistry, TP250-261, Chemistry, QD1-999

Abstract

Abstract Porous gas‐diffusion electrodes (GDEs) are widely used in electrochemical applications where a gaseous reactant is converted to a target product. Important applications for silver‐based GDEs are the chlor‐alkali and the CO2 electrolysis processes in which silver catalyzes the oxygen‐ or carbon dioxide reduction reaction. The wetting of the porous GDEs is of utmost importance for the achieved performance of the electrode: a completely dry electrode will result in low current densities due to the reduced active surface area while on the other hand, a completely flooded electrode will deteriorate the access of the gaseous reactant. Therefore, we investigated silver‐based GDEs for the oxygen reduction reaction with different amounts of the hydrophobic agent polytetrafluoroethylene (PTFE) and analyzed the potential‐induced wetting behavior (electrowetting). The electrolyte breakthrough was recorded by a digital microscope and subsequently evaluated via imaging analysis of the observed breached electrolyte droplets. In order to characterize the wetting state during transition to the steady‐state, we applied electrochemical impedance spectroscopy measurements and retrieved the double‐layer capacitance. Our results indicate that a higher overvoltage facilitates the breakthrough of electrolytes through the gas‐diffusion electrode. Surprisingly, a faster breakthrough of electrolyte was observed for electrodes with higher PTFE content. Porometry measurements revealed that the GDE with low PTFE content has a monomodal pore size distribution, whereas electrodes with higher PTFE amount exhibit a bimodal pore size distribution. In GDEs with monomodal pore size distribution the time in which the double layer capacitance is leveling off correlates with the breakthrough time of the electrolyte. In summary, we emphasize that the wetting of GDEs is a complex interplay of the applied potential, electrode composition, and resulting porous structure which requires further advanced measurements and analysis considering the parameters affecting the wetting behavior as a whole.

Published

2023

7. Directed transfer of liquid metal droplets between electrodes

Author

(0000-0002-7918-7474) Mutschke, G., Weier, T., (0000-0002-7918-7474) Mutschke, G., and Weier, T.

Abstract

Electric fields offer an easy means to manipulate liquid metal droplets. Now, directed droplet transfer between immersed electrodes is achieved in an alkaline electrolyte without electrical short-circuit.

Published

2024

8. Miscellaneous and Open Questions

Author

Gräfe, Wolfgang and Gräfe, Wolfgang

Published

2015

9. Electrocapillary effect in liquid films with an electrically charged interface

Author

Shantharama and Sreeram K. Kalpathy

Subjects

010302 applied physics, Work (thermodynamics), Materials science, Charge density, Electrocapillarity, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Physics::Fluid Dynamics, Condensed Matter::Soft Condensed Matter, Surface tension, Chemical physics, Electrical resistivity and conductivity, Electric field, 0103 physical sciences, Electric potential, Current (fluid), 0210 nano-technology

Abstract

The electrocapillary effect is the change in interfacial tension between two immiscible liquids when subjected to an electric field across the interface. The change in interfacial tension occurs due to variations in the surface charge density of adsorbed ions or polar species at the interface. In the present work, we provide fluid mechanical insights into electrocapillarity-based dynamics of an interface between a passive air layer and a thin liquid film that has small, but finite electrical conductivity. We formulate and solve mathematical equations that model the situation in which a liquid film bounded by an air layer of controllable thickness is sandwiched between two electrode plates, and an electric field is applied across the layers. As the liquid and air have different conductivities, free charges would accumulate at the liquid–air interface to ensure that current is conserved across the layers. In our model, the interfacial tension is assumed to vary as per the classical Lippmann’s equation. The present mathematical model describes spatiotemporal variation of the film height and interfacial charge density as a function of the applied potential, air layer width, and the sensitivity of interfacial tension to the electric potential. Our results show that ultrathin liquid films (

Published

2021

10. Experimental methods for the determination of stress changes at electrified solid-liquid interfaces.

Author

Láng, Gyözö G., Kovács, Noémi, Vesztergom, Soma, Ujvári, Mária, Zalka, Dóra, and Szekeres, Krisztina

Subjects

SOLID-liquid interfaces, ELECTRODES, ELECTROCAPILLARY phenomena, SURFACE tension measurement, INTERFACIAL tension, ELECTROCHEMISTRY

Abstract

Copyright of Technisches Messen is the property of De Gruyter and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2017

11. Investigating the electrowetting of silver based gas diffusion electrodes during oxygen reduction reaction with electrochemical and optical methods

Author

Fabian Bienen, Melanie C. Paulisch, Thorben Mager, Jens Osiewacz, Manigah Nazari, Markus Osenberg, Barbara Ellendorff, Thomas Turek, Ulrich Nieken, Ingo Manke, and K. Andreas Friedrich

Subjects

electrocapillarity, electrochemical impedance spectroscopy, electrowetting, gas diffusion electrode, imaging analysis, oxygen reduction reaction ORR, porous media, General Medicine

Abstract

Porous gas diffusion electrodes GDEs are widely used in electrochemical applications where a gaseous reactant is converted to a target product. Important applications for silver based GDEs are the chlor alkali and the CO2 electrolysis processes in which silver catalyzes the oxygen or carbon dioxide reduction reaction. The wetting of the porous GDEs is of utmost importance for the achieved performance of the electrode a completely dry electrode will result in low current densities due to the reduced active surface area while on the other hand, a completely flooded electrode will deteriorate the access of the gaseous reactant. Therefore, we investigated silver based GDEs for the oxygen reduction reaction with different amounts of the hydrophobic agent polytetrafluoroethylene PTFE and analyzed the potential induced wetting behavior electrowetting . The electrolyte breakthrough was recorded by a digital microscope and subsequently evaluated via imaging analysis of the observed breached electrolyte droplets. In order to characterize the wetting state during transition to the steady state, we applied electrochemical impedance spectroscopy measurements and retrieved the double layer capacitance. Our results indicate that a higher overvoltage facilitates the breakthrough of electrolytes through the gas diffusion electrode. Surprisingly, a faster breakthrough of electrolyte was observed for electrodes with higher PTFE content. Porometry measurements revealed that the GDE with low PTFE content has a monomodal pore size distribution, whereas electrodes with higher PTFE amount exhibit a bimodal pore size distribution. In GDEs with monomodal pore size distribution the time in which the double layer capacitance is leveling off correlates with the breakthrough time of the electrolyte. In summary, we emphasize that the wetting of GDEs is a complex interplay of the applied potential, electrode composition, and resulting porous structure which requires further advanced measurements and analysis considering the parameters affecting the wetting behavior as a whole

Published

2022

12. Wafer‐Scale Electroactive Nanoporous Silicon: Large and Fully Reversible Electrochemo‐Mechanical Actuation in Aqueous Electrolytes

Author

Manuel Brinker and Patrick Huber

Subjects

Materials science, Cantilever, Silicon, Electrocapillarity, chemistry.chemical_element, FOS: Physical sciences, Nanotechnology, Ingenieurwissenschaften [620], Applied Physics (physics.app-ph), Condensed Matter - Soft Condensed Matter, electrochemical characterization, Physics - Chemical Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), General Materials Science, Wafer, Fluidics, Technik [600], Chemical Physics (physics.chem-ph), Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, business.industry, Mechanical Engineering, Materials Science (cond-mat.mtrl-sci), Physics - Applied Physics, actuorics, Piezoelectricity, cyclic voltammetry, Nanopore, Semiconductor, chemistry, Mechanics of Materials, ddc:660, Soft Condensed Matter (cond-mat.soft), ddc:620, business, ddc:600, nanoporous media, laser cantilever bending

Abstract

Advanced materials 34(1), 2105923 (2021). doi:10.1002/adma.202105923, Nanoporosity in silicon results in interface-dominated mechanics, fluidics, and photonics that are often superior to the ones of the bulk material. However, their active control, for example, by electronic stimuli, is challenging due to the absence of intrinsic piezoelectricity in the base material. Here, for large-scale nanoporous silicon cantilevers wetted by aqueous electrolytes, electrosorption-induced mechanical stress generation of up to 600 kPa that is reversible and adjustable at will by potential variations of ���1 V is shown. Laser cantilever bending experiments in combination with in operando voltammetry and step coulombmetry allow this large electro-actuation to be traced to the concerted action of 100 billions of parallel nanopores per square centimeter cross-section and determination of the capacitive charge���stress coupling parameter upon ion adsorption and desorption as well as the intimately related stress actuation dynamics for perchloric and isotonic saline solutions. A comparison with planar silicon surfaces reveals mechanistic insights on the observed electrocapillarity (Hellmann���Feynman interactions) with respect to the importance of oxide formation and wall roughness on the single-nanopore scale. The observation of robust electrochemo-mechanical actuation in a mainstream semiconductor with wafer-scale, self-organized nanoporosity opens up novel opportunities for on-chip integrated stress generation and actuorics at exceptionally low operation voltages., Published by Wiley-VCH, Weinheim

Published

2022

13. Electrocapillarity

Author

Bhushan, Bharat, editor

Published

2016

14. Thermodynamic aspects of capillarity and electrocapillarity of solid interfaces.

Author

Gutman, E.

Subjects

*ELECTROCAPILLARY phenomena, *MAXWELL relations, *STRAINS & stresses (Mechanics), *THERMODYNAMICS, *CONTINUUM mechanics

Abstract

In the previous paper (Gutman, JOSSEC 18:3217-3237, 2014), we have shown that the main problem in capillarity and electrocapillarity of solid surfaces is the lack of clarity in determining the surface stress and basic equations. Now, we continue the survey of efforts to solve this problem and show origins of erroneous results, accenting some important items: comparative analysis of Gibbs and Guggenheim approaches in surface thermodynamics (a geometrical dividing surface and finite-thickness surface layer, respectively), transformation of fundamental equations on per-unit-area basis to obtain Gibbs adsorption equation for finite-thickness surface layer, different attempts to derive the thermodynamic definition of 'surface stress' in frames of Gibbs' theory (including Shuttleworth's approach), atomistic calculations of surface stress, surface stress in rational continuum mechanics, 'modifications' of Gibbs-Duhem relations made for solid interface, and Maxwell relations in capillarity and electrocapillarity of solid interface. It is shown that the erroneous Shuttleworth's approach is present in an explicit or implicit form in all efforts to introduce the surface stress in frames of Gibbsian theory (although Gibbs did not introduce surface stress). Therefore, 'modernizations' or 'generalizations' of the Gibbs-Duhem relation, the Gibbs adsorption equation, and the Lippmann equation to adopt them for a solid surface are unnatural and not necessary. Therefore, we recommend withdrawing the Shuttleworth equation and its consequences from circulation, including the IUPAC Recommendations. [ABSTRACT FROM AUTHOR]

Published

2016

15. Piezoelectric Gold: Strong Charge-Load Response in a Metal-Based Hybrid Nanomaterial.

Author

Stenner, Charlotte, Shao, Li‐Hua, Mameka, Nadiia, and Weissmüller, Jörg

Subjects

*ELECTROLYTES, *NANOSTRUCTURED materials, *CHARGE transfer, *PIEZOELECTRIC devices, *PIEZOELECTRICITY

Abstract

Impregnating the pores of nanoporous gold with aqueous electrolyte yields a hybrid nanomaterial with two separate and interpenetrating charge transport paths, electronic conduction in the metal and ionic conduction in the electrolyte. As the two paths are capacitively connected, space-charge layers along the internal interfaces are coupled to electric potential differences between the paths and can be controlled or detected thereby. The present experiments show that the space charge couples to mechanical deformation of the hybrid material, so that external loading generates an electric current. The electric signal originates from charge displacement along the entire internal interface; the signal is particularly robust since the interface area is large. The charge transfer in response to load constitutes a piezoelectric response, yet the mechanism is quite different to classic piezoelectricity. The analysis in this work predicts links between electromechanical coupling parameters for strain sensing and actuation, which are in excellent agreement with the experiment. [ABSTRACT FROM AUTHOR]

Published

2016

16. Experimental determination of the viscosity at very low shear rate for shear thinning fluids by electrocapillarity.

Author

Allouche, M.H., Botton, V., Henry, D., Millet, S., Usha, R., and Ben Hadid, H.

Subjects

*SHEAR rate dependent viscosity, *PSEUDOPLASTIC fluids, *ELECTROCAPILLARY phenomena, *NON-Newtonian fluids, *THIXOTROPY, *RHEOMETERS, *XANTHAN gum

Abstract

Non-Newtonian fluids can present a complex rheological behaviour involving shear-thinning, viscoelastic or thixotropic effects. We focus here on the characterization of generalized Newtonian fluids as shear-thinning fluids. Rotational rheometers are torque-sensitive, which makes the measurement of viscosity at low shear-rates very difficult, in particular for low viscosity fluids. An accurate knowledge of this value is, however, particularly important for the characterization of several types of flows, in particular those featuring a free surface, a symmetry axis or a symmetry plane. The experimental determination of viscosity and surface tension is enabled from the propagation of attenuated capillary waves. An optical technique has been implemented in order to determine the shear-thinning viscosity at values of the shear-rate as small as 10 −3 s −1 from measurements of the spatial attenuation and wavelength. We have performed measurements on two different polymer solutions; we show that this technique is complementary to the classical rotational rheometer techniques since it gives access to the zero shear viscosity, which could not be measured by using rotational rheometers. The present technique is thus used to characterize the Newtonian plateau, while a rotational rheometer is used to characterize the fluid behaviour at moderate to high shear rates. [ABSTRACT FROM AUTHOR]

Published

2015

17. Theoretical problems in solid electrocapillarity.

Author

Gutman, Emmanuel

Subjects

*ELECTROCAPILLARY phenomena, *SUPERIONIC conductors, *CAPILLARITY, *SOLID mechanics, *SURFACE tension

Abstract

The main problem in electrocapillarity of solid electrodes is the lack of clarity in determining the surface stress and basic equations. Within the framework of the Gibbs concept of geometrical dividing surface, the 'surface stress' cannot be defined because methods of continuum mechanics can be applied to a physical surface layer (of finite thickness), but not to a mathematical surface. Gibbs never used the concept of surface stress, introducing only 'surface tension' for a liquid electrode and 'closely related quantity' for a solid electrode. Revisiting the derivation of the Gibbs adsorption equation, we prove its applicability to solid surfaces without the limiting requirement of constant state of strain, which was undeservedly interpreted by Eriksson as a shortcoming of the Gibbs theory caused to look for other approaches to surface stress problem. A critical analysis shows that the attempts (Shuttleworth, Eriksson, Couchman, Gokhstein, Weissmüller, etc.) to create a thermodynamic definition of the surface stress (as well as the formulation of fundamental thermodynamic equations and Maxwell relations operating with surface stresses) contain mathematical defects. It is shown that confusing interpretations of some Gibbs' concepts encountered in the literature have led to 'modifications' of the Lippmann equation based on the critical error in the Gibbs-Duhem relation due to the occurrence of an extensive variable, which is inadmissible. The famous Lippmann equation should not be modified, and it remains a unique electrocapillary relation applicable to liquid and solid electrodes. [ABSTRACT FROM AUTHOR]

Published

2014

18. General Properties of the Nernst-Planck-Poisson-Boltzmann System Describing Electrocapillary Effects in Porous Media.

Author

Gagneux, Gérard and Millet, Olivier

Subjects

POROUS materials, NERNST-Planck equation, MAXWELL-Boltzmann distribution law, ELECTROCAPILLARY phenomena, LYAPUNOV functions, ENTROPY, MATHEMATICAL models

Abstract

The Nernst-Planck-Poisson-Boltzmann system describes the evolution of ionic concentrations and electrocapillarity effects in porous media. The aim of this paper is a theoretical study of various drift-diffusion modellings. The well-posedness of the systems is proved and some qualitative properties of the global solution are shown to be satisfied (energy law, entropy law in the weak sense of Lyapunov functions, stationary states, Maxwellian distribution, influence of an external electric field). Moreover, some explicit solutions are established in the one-dimensional case. [ABSTRACT FROM AUTHOR]

Published

2014

19. Giant and switchable surface activity of liquid metal via surface oxidation.

Author

Khan, Mohammad Rashed, Eaker, Collin B., Bowden, Edmond F., and Dickey, Michael D.

Subjects

*LIQUID metals, *SURFACE active agents, *OXIDATION-reduction reaction, *SURFACE tension, *ELECTROPHORETIC deposition, *ELECTROMAGNETIC devices

Abstract

We present a method to control the interfacial tension of a liquid alloy of gallium via electrochemical deposition (or removal) of the oxide layer on its surface. In sharp contrast with conventional surfactants, this method provides unprecedented lowering of surface tension (∼500 mJ/m2 to near zero) using very low voltage, and the change is completely reversible. This dramatic change in the interfacial tension enables a variety of electrohydrodynamic phenomena. The ability to manipulate the interfacial properties of the metal promises rich opportunities in shape-reconfigurable metallic components in electronic, electromagnetic, and microfluidic devices without the use of toxic mercury. This work suggests that the wetting properties of surface oxides-which are ubiquitous on most metals and semiconductors-are intrinsic "surfactants." The inherent asymmetric nature of the surface coupled with the ability to actively manipulate its energetics is expected to have important applications in electrohydrodynamics, composites, and melt processing of oxide-forming materials. [ABSTRACT FROM AUTHOR]

Published

2014

20. Electrowetting - From statics to dynamics.

Author

Chen, Longquan and Bonaccurso, Elmar

Subjects

*ELECTROCAPILLARY phenomena, *ELECTROSTATICS, *MICROFLUIDIC analytical techniques, *MICRODROPLETS, *NUCLEAR liquid drop model, *WETTING, *SATURATION (Chemistry)

Abstract

More than one century ago, Lippmann found that capillary forces can be effectively controlled by external electrostatic forces. As a simple example, by applying a voltage between a conducting liquid droplet and the surface it is sitting on we are able to adjust the wetting angle of the drop. Since Lippmann's findings, electrocapillary phenomena - or electrowetting - have developed into a series of tools for manipulating microdroplets on solid surfaces, or small amounts of liquids in capillaries for microfluidic applications. In this article, we briefly review some recent progress of fundamental understanding of electrowetting and address some still unsolved issues. Specifically, we focus on static and dynamic electrowetting. In static electrowetting, we discuss some basic phenomena found in DC and AC electrowetting, and some theories about the origin of contact angle saturation. In dynamic electrowetting, we introduce some studies about this rather recent area. At last, we address some other capillary phenomena governed by electrostatics and we give an outlook that might stimulate further investigations on electrowetting. [ABSTRACT FROM AUTHOR]

Published

2014

21. Comment on 'On the 'simple check' of electrocapillarity' by AY Gokhshtein.

Author

Gutman, Emmanuel

Subjects

*MAXWELL relations, *THERMODYNAMICS, *CAPILLARITY, *ELECTRIC double layer, *EQUATIONS

Abstract

It is shown that the so-called 'equation of solid-state electrocapillarity' derived by Gokhshtein from the simplest thermodynamic model, earlier used by Lippmann, is an incorrect modification that is returned to the classic Lippmann equation if to take into account the usual definition of differential capacity of the electrical double layer. Consequently, Gokhshtein's experiments can actually confirm only the validity of the Lippmann equation (with deviations caused by physicochemical processes in the double layer, which could not be taken into account in the thermodynamic equations). The thermodynamic model is insufficient for the interpretation s of these experimental results, whose understanding requires physical models of the different phenomena occurring at the electrode surface. [ABSTRACT FROM AUTHOR]

Published

2014

22. Challenges and Complexities in Fabrication of Nano-dispensing Electrowetting-on-Dielectric actuated Glass Micropipettes

Author

M. Ananthasubramanian, Vijay Kumar, S. Shringi, Shahbaz Ahmed Siddiqui, and Narotam Sharma

Subjects

Materials science, Fabrication, Coating, Nano, Microfluidics, engineering, Electrowetting, Electrocapillarity, Nanotechnology, Wetting, Dielectric, engineering.material

Abstract

Since the first study of electrocapillarity by Gabriel Lippmann in 1875, the modern electrowetting-on-dielectric (EWOD) has been intensively studied and developed. The modification of wetting properties of surface allows users to exploit this phenomenon for various applications such as nano liter sized droplet generation/splitting/merging, controlled chemical reactions, and DNA/protein analysis platforms. Electrowetting-on-dielectric (EWOD) is one such phenomenon that takes advantage of hydrophobic/hydrophilic surfaces to navigate a droplet onto the desired position. EWOD based micropipette provides customization (vis-a-vis droplet dispensing) to a great extent as well as the enhanced analysis speed which is the sine qua non to meet the current demand for high throughput analysis. Despite the advantages of the technology, it is observed during reviewing that the assimilation of these digital microfluidic devices have not been successfully achieved in academia or industry and this is widely visible by looking at the fraction of EWOD devices used in industrial applications in general. This is due to various issues and complicated processes involved in the development of EWOD based micropipettes. The present study focuses majorly on the challenges involved in the fabrication of an EWOD actuated micropipette. Possible ways to circumvent issues like coating of a hydrophobic layer inside the micropipette and metal coating on curved surface are also elaborated. The complexities arising during the development of these micropipettes act as a major hindrance in mainstreaming this technology from academia to industry.

Published

2020

23. Mechanical modulation of reaction rates in electrocatalysis.

Author

Deng, Qibo, Smetanin, Maxim, and Weissmüller, Jörg

Subjects

*CHEMICAL reactions, *ELECTROCATALYSIS, *CHEMICAL kinetics, *HYDROGEN evolution reactions, *STRAINS & stresses (Mechanics), *CHEMISTRY experiments

Abstract

Highlights: [•] Strain-dependent kinetic rate equation for hydrogen evolution reaction. [•] Experimental in situ monitoring of strain-induced reactivity modulation. [•] Tensile strain enhances reactivity at low overpotential. [•] Tensile strain diminishes reactivity at high overpotential. [•] Adsorption and activation enthalpies depend on strain. [ABSTRACT FROM AUTHOR]

Published

2014

24. Homogenization of the Nernst-Planck-Poisson System by Two-Scale Convergence.

Author

Gagneux, Gérard and Millet, Olivier

Subjects

ASYMPTOTIC homogenization, STOCHASTIC convergence, ELECTROCAPILLARY phenomena, MATHEMATICAL models, POROUS materials

Abstract

This work focuses on performing the homogenization of the Nernst-Planck-Poisson system, in order to obtain an efficient modelling of the ionic transfer and electrocapillary effects at the macroscopic scale for saturated porous media. The homogenization is performed with the powerful two-scale convergence method, which enables to obtain both the homogenized model and the associated convergence result. [ABSTRACT FROM AUTHOR]

Published

2014

25. Electrocapillarity

Author

Bhushan, Bharat, editor

Published

2012

26. Electrically Switchable Capillarity of Ionic Liquids.

Author

Hu, Xiaodong, Zhang, Shiguo, Qu, Chao, Zhang, Qinghua, Lu, Liujin, Ma, Xiangyuan, Zhang, Xiaoping, and Deng, Youquan

Subjects

*IONIC liquids, *ELECTROCAPILLARY phenomena, *WETTING, *ELECTROLYTES, *THERMAL analysis, *FLAMMABILITY, *HIGH temperatures

Abstract

Electrocapillarity is the basis of modern electrowetting. And room temperature ionic liquids, an increasingly important set of electrolytes and organic salts that are liquid at room temperature, are considered a novel class of electrowetting agents, because of non-significant vapor pressure, nonflammability, good thermal sta-bility, and a wide useable temperature range. In this paper, a simple device has been fabricated to investigate the electrocapillarity of ionic liquids. It shows attractive features involving wide operating temperature and in particular high stability, fast response and good reversibility at high temperatures. Besides, electrocapil-larity of ionic liquids is strongly dependent on power supply frequency. In particular, high frequency, stable, reversible and wide height of rise modulations were obtained. The phenomenon of ionic liquids-based elec-trocapillarity was found to be affected by the structure and physicochemical properties of ionic liquids such as density, surface tension, alkyl carbon chain length of cation, type of the anion, etc., and the efficiency could be further improved through optimal choice of ambient phase or rational design and synthesis of ionic liquids. [ABSTRACT FROM AUTHOR]

Published

2012

27. A comparison of the ultraslow relaxation processes at the ionic liquid|water interface for three hydrophobic ionic liquids

Author

Yasui, Yukinori, Kitazumi, Yuki, Mizunuma, Hiroyuki, Nishi, Naoya, and Kakiuchi, Takashi

Subjects

*IONIC liquids, *COMPARATIVE studies, *HYDROPHOBIC surfaces, *ELECTRIC double layer, *LIQUID-liquid interfaces, *ELECTROCAPILLARY phenomena

Abstract

Abstract: The ultraslow relaxation, on the order of a few seconds or longer, of the structure of the electrical double layer in response to the change in the phase-boundary potential across the ionic liquid (IL)|water(W) interface, which was recently reported for trioctylmethylammonium bis(nonafluorobutanesulfonyl)amide, has been confirmed in two new hydrophobic ionic liquids, trihexyltetradecylphosphonium bis(nonafluorobutanesulfonyl)amide and trihexyltetradecylphosphonium tetrakis(pentafluorophenyl)borate. A comparison of the degree of the hysteresis in electrocapillary curves for these ILs with those for trioctylmethylammonium bis(nonafluorobutanesulfonyl)amide demonstrates that the degree of the hysteresis is not correlated with the viscosity of these ILs. The ultraslow relaxation of the electrical double layer seems to be a general feature of ILs at electrified interfaces. [ABSTRACT FROM AUTHOR]

Published

2010

28. A model of the electrochemical instability at the liquid∣liquid interface based on the potential-dependent adsorption and Gouy’s double layer theory

Author

Kitazumi, Y. and Kakiuchi, T.

Subjects

*LIQUID-liquid interfaces, *ELECTROCHEMICAL analysis, *ADSORPTION (Chemistry), *GIBBS' free energy, *SURFACE active agents, *CHEMICAL structure

Abstract

Abstract: A new model has been formulated for the electrochemical instability at the liquid∣liquid interface, for which only a rudimentary model [T. Kakiuchi, J. Electroanal. Chem. 536 (2002) 63–69] had been available. The new model considers the diffuse double layers in the presence of the specifically adsorbed surface-active ions, whose adsorption Gibbs energy linearly varies with the phase-boundary potential. The electrocapillary equation in the presence of the common ions partitioning in both phases is employed under the assumption that the partition of the surface-active ions is described by the Nernst equation. The excess surface charge due to the specific adsorption of surface-active ions is allowed for in calculating the structure of the diffuse part of the electrical double layers on both sides of the interface. The calculated electrocapillary curves agree with the experimental results. It is confirmed that electrocapillary curves can have positive curvature in a certain potential region, which signifies the presence of an instability window. [Copyright &y& Elsevier]

Published

2010

29. Electrocapillarity

Author

Li, Dongqing, editor

Published

2008

30. Influence of electrical potential on the crystallization and adhesion of potassium hydrogen tartrate crystals.

Author

Huerta-Ortega, Benjamin, Gabas, Nadine, and Comtat, Maurice

Subjects

*CRYSTALLIZATION, *ELECTROLYTIC oxidation, *ALLOYS, *CORROSION resistant materials, *POTASSIUM, *CHROME-nickel steel, *ADHESION, *VOLTAMMETRY, *GLUTATHIONE

Abstract

Interfacial interactions between a hydroalcoholic solution of potassium hydrogen tartrate (KHT) and a stainless steel surface are studied, when an electrical potential is applied to the metal substrate. The capacitive domain of the metal–solution interface is determined by cyclic voltammetry. In order to study the influence of the potential on KHT nucleation and crystal adhesion, the solid–liquid interfacial energy is assessed from contact angle and capillary rise measurements. Experimentally, the contact angle between a NaF solution and a stainless steel vs. the potential has a parabolic behaviour. The metal topography has no apparent influence on physicochemical properties of the interface when ethanol is present in a KHT solution. The metal substrate promotes the formation of KHT crystals, which is improved by the application of an anodic potential. The adhesion of crystals becomes more effective when wires of 25 μm diameter are used in comparison with those of 250 μm. [ABSTRACT FROM AUTHOR]

Published

2009

31. Anion dependence of camel-shape capacitance at the interface between mercury and ionic liquids studied using pendant drop method

Author

Tetsuo Sakka, Shunsuke Yasui, Naoya Nishi, and Atsunori Hashimoto

Subjects

Differential capacitance, General Chemical Engineering, Slow dynamics, Analytical chemistry, Electrocapillarity, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Analytical Chemistry, Ion, chemistry.chemical_compound, Amide, Electrochemistry, Moiety, Interfacial structure, Surface tension, Hysteresis, Electric double layer, Electrocapillary curve, TFSI, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Dielectric spectroscopy, chemistry, Electrode, Ionic liquid, Slow relaxation, 0210 nano-technology, Interfacial tension, Electrochemical impedance spectroscopy

Abstract

The electrocapillarity and zero-frequency differential capacitance, Cd, have been studied using pendant drop method, at the Hg interface of an ionic liquid (IL), 1-ethyl-3-methylimidazolium bis(trifluoromethanesulfonyl)amide, [C2mim+][TFSA−], and have been compared with those of [C2mim+]BF 4 − , an IL with the common cation and a different anion, to focus on the anion dependence of zero-frequency Cd. The Hg interface of [C2mim+][TFSA−], the IL of the larger anion in the present study, exhibits greater zero-frequency Cd than that of [C2mim+]BF 4 − , the IL of the smaller anion. This behavior contradicts a simple expectation in which larger ion leads to smaller Cd. This apparent contradiction is explained by proximity of the charged moiety of TFSA− to the electrode surface compared with that of BF 4 − . The potential dependence of zero-frequency Cd for the two ILs both exhibits one-hump camel shape around the potential of zero charge (Epzc), which has been predicted to be specific behavior of the electrical double layer of ILs by theory and simulation. The humps are located at potentials more negative than Epzc. From a mean-field lattice-gas theory for the EDL in ILs, this negative shift can be interpreted that the charged moiety for C2mim+ is more easily condensed in the EDL than those for BF 4 − and TFSA−.

Published

2017

32. Influence of Electrocapillarity on the Water Meniscus Shape in the Atomic Force Microscopy

Author

Eliseev, E. A.

Subjects

Physics::Fluid Dynamics, water meniscus, electrocapillarity, atomic force microscopy, атомно-силова мiкроскопiя, Euler–Lagrange equation, рiвняння Ейлера–Лагранжа, Physics::Chemical Physics, електрокапiлярнiсть, водяний менiск

Abstract

In the framework of the analytical theory of electrocapillarity phenomena that arise in atomic force microscopy (AFM) experiments, the formation of a water meniscus under the AFM probe has been considered, and its dependence on the applied voltage has been analyzed. The non-uniformity of the electric field produced by the AFM probe, the influences of gravitation forces on the meniscus height, and the dependence of the surface energy of a meniscus on its shape are taken into account self-consistently. The influence of a strong non-uniform electric field of the probe on the emergence conditions, size, and shape of the water meniscus is analyzed for the first time. The Euler–Lagrange partial differential equation and the corresponding boundary conditions making allowance for the non-uniform electric field of an AFM probe, the gravitation force, the meniscus surface tension, and the environmental humidity and describing the thermodynamics of the water meniscus formation in a self-consistent way are derived. The obtained numerical results are in agreement with known experimental data., У роботi розглянуто актуальнi питання аналiтичної теорiї явищ електрокапiлярностi, що виникають в АСМ-експериментi, а саме утворення водяного менiска пiд зондом АСМ та дослiджено вплив прикладеної електричної напруги. Враховано явища електрокапiлярностi в неоднорiдному електричному полi зонда АСМ, впливу сили тяжiння на висоту менiска та його поверхневу енергiю залежно вiд реальної форми, що має знаходитися самоузгодженим чином. Вперше проаналiзовано вплив такого специфiчного фактора, як сильна неоднорiднiсть електричного поля зонда, на умови виникнення, розмiри та форму водяного менiска. З урахуванням неоднорiдного електричного поля зонда АСМ, сили тяжiння, сили поверхневого натягу менiска та вологостi оточуючого середовища виведено диференцiальне рiвняння Ейлера–Лагранжа в частинних похiдних з граничними умовами, яке описує термодинамiку утворення водяного менiска самоузгодженим чином. Одержанi чисельнi результати описують вiдомi експериментальнi данi.

Published

2019

33. Specific ion effects on electrocapillarity in aqueous electrolytes confined within nanochannels

Author

In Seok Kang and Saksham Gupta

Subjects

Work (thermodynamics), Materials science, Flow (psychology), Electrocapillarity, Electrolyte, 01 natural sciences, 010305 fluids & plasmas, Ion, Stress (mechanics), Cross section (physics), Chemical physics, Electric field, 0103 physical sciences, 010306 general physics

Abstract

A nanoslit is a long, extremely narrow (nanometers apart) opening between two parallel plates. An overlapped electric double layer is formed when an electrolyte is present inside the slit and there exist distributions of the osmotic pressure and the Maxwell stress across the nanoslit, which lead to the electrocapillarity effect. This feature can be incorporated with the specific ion effects by considering the nonelectrostatic interactions between ions and confining walls, as they significantly influence the potential, electric field, and ion distributions across the nanoslit. In the present work, the electromechanical approach is integrated with the concept of specific ion effects to analyze the behavior of an electrolyte confined in a one-dimensional nanochannel. For a nanochannel, the average outward normal stress exerted on the cross section of a channel (P_{zz}[over ¯]) can be regarded as a measure of electrocapillarity and it is the driving force of the flow. This electrocapillarity measure is analyzed by using the solution of the modified Poisson-Boltzmann equation as a function of the bulk concentration of the electrolyte, the boundary potential, and most importantly, the ion-specific interfacial interactions. The significance of the present work can be manifested by the increasing usage of extremely narrow channels in nanoscaled systems, which will require proper consideration of specific ion effects in determining the behavior of the confined electrolyte.

Published

2019

34. Interfacial Tension Modulation of Liquid Metal via Electrochemical Oxidation

Author

Abolfazl Kiani, Sahar Rashid-Nadimi, Michael D. Dickey, Karen E. Daniels, and Minyung Song

Subjects

Computer engineering. Computer hardware, Liquid metal, Work (thermodynamics), Materials science, FOS: Physical sciences, Electrocapillarity, chemistry.chemical_element, Electrochemistry, TK7885-7895, Metal, Surface tension, surface tension, electrochemical oxidation, Gallium, gallium, Condensed Matter - Materials Science, eutectic gallium indium, Control engineering systems. Automatic machinery (General), Tension (physics), Fluid Dynamics (physics.flu-dyn), Materials Science (cond-mat.mtrl-sci), Physics - Fluid Dynamics, chemistry, Chemical physics, TJ212-225, visual_art, visual_art.visual_art_medium, General Economics, Econometrics and Finance, liquid metals

Abstract

This progress report summarizes recent studies of electrochemical oxidation to modulate the interfacial tension of gallium-based alloys. These alloys, which are liquid at ambient conditions, have the largest interfacial tension of any liquid at room temperature. The ability to modulate the tension offers the possibility to create forces that change the shape and position of the metal. It has been known since the late 1800s that electrocapillarity-the use of potential to modulate the electric double layer on the surface of metals in electrolyte-lowers the interfacial tension of liquid metal. Yet, this phenomenon can only achieve modest changes in interfacial tension since it is limited to potential windows that avoid reactions. A recent discovery suggests that reactions driven by the electrochemical oxidation of gallium alloys cause the interfacial tension to decrease from ~500 mN/m at 0 V to ~0 mN/m at ~0.8 V, a change in tension that goes well beyond what is possible via conventional electrocapillarity or surfactants. The changes in tension are reversible; reductive potentials return the metal back to a state of high interfacial tension. This report aims to summarize key work and introduce beginners to this field by including electrochemistry basics while addressing misconceptions. We discuss applications that utilize modulations in interfacial tension of liquid metal and conclude with remaining opportunities and challenges that need further investigation.

Published

2021

35. On‐Chip Production of Size‐Controllable Liquid Metal Microdroplets Using Acoustic Waves

Author

Shi-Yang Tang, Yusheng Bian, Bugra Ayan, James P. Lata, Nitesh Nama, Tony Jun Huang, and Xiasheng Guo

Subjects

Liquid metal, Working electrode, Analytical chemistry, Electrocapillarity, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Article, Flexible electronics, 0104 chemical sciences, Galinstan, Biomaterials, chemistry.chemical_compound, Acoustic streaming, chemistry, General Materials Science, Gallium, 0210 nano-technology, Indium, Biotechnology

Abstract

Micro- to nanosized droplets of liquid metals, such as eutectic gallium indium (EGaIn) and Galinstan, have been used for developing a variety of applications in flexible electronics, sensors, catalysts, and drug delivery systems. Currently used methods for producing micro- to nanosized droplets of such liquid metals possess one or several drawbacks, including the lack in ability to control the size of the produced droplets, mass produce droplets, produce smaller droplet sizes, and miniaturize the system. Here, a novel method is introduced using acoustic wave-induced forces for on-chip production of EGaIn liquid-metal microdroplets with controllable size. The size distribution of liquid metal microdroplets is tuned by controlling the interfacial tension of the metal using either electrochemistry or electrocapillarity in the acoustic field. The developed platform is then used for heavy metal ion detection utilizing the produced liquid metal microdroplets as the working electrode. It is also demonstrated that a significant enhancement of the sensing performance is achieved by introducing acoustic streaming during the electrochemical experiments. The demonstrated technique can be used for developing liquid-metal-based systems for a wide range of applications.

Published

2016

36. Thermodynamic aspects of capillarity and electrocapillarity of solid interfaces

Author

Emmanuel M. Gutman

Subjects

Surface (mathematics), Physics, Continuum mechanics, Surface stress, Electrocapillarity, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, symbols.namesake, Classical mechanics, Gibbs–Duhem equation, Solid mechanics, Electrochemistry, symbols, Physical chemistry, General Materials Science, Surface layer, Electrical and Electronic Engineering, Maxwell relations, 0210 nano-technology

Abstract

In the previous paper (Gutman, JOSSEC 18:3217–3237, 2014), we have shown that the main problem in capillarity and electrocapillarity of solid surfaces is the lack of clarity in determining the surface stress and basic equations. Now, we continue the survey of efforts to solve this problem and show origins of erroneous results, accenting some important items: comparative analysis of Gibbs and Guggenheim approaches in surface thermodynamics (a geometrical dividing surface and finite-thickness surface layer, respectively), transformation of fundamental equations on per-unit-area basis to obtain Gibbs adsorption equation for finite-thickness surface layer, different attempts to derive the thermodynamic definition of “surface stress” in frames of Gibbs’ theory (including Shuttleworth’s approach), atomistic calculations of surface stress, surface stress in rational continuum mechanics, “modifications” of Gibbs–Duhem relations made for solid interface, and Maxwell relations in capillarity and electrocapillarity of solid interface. It is shown that the erroneous Shuttleworth’s approach is present in an explicit or implicit form in all efforts to introduce the surface stress in frames of Gibbsian theory (although Gibbs did not introduce surface stress). Therefore, “modernizations” or “generalizations” of the Gibbs–Duhem relation, the Gibbs adsorption equation, and the Lippmann equation to adopt them for a solid surface are unnatural and not necessary. Therefore, we recommend withdrawing the Shuttleworth equation and its consequences from circulation, including the IUPAC Recommendations.

Published

2016

37. Piezoelectric gold : strong charge-load response in a metal-based hybrid nanomaterial

Author

Stenner, Charlotte, Shao, Li-Hua, Mameka, Nadiia, Weissmüller, Jörg, Stenner, Charlotte, Shao, Li-Hua, Mameka, Nadiia, and Weissmüller, Jörg

Abstract

Impregnating the pores of nanoporous gold with aqueous electrolyte yields a hybrid nanomaterial with two separate and interpenetrating charge transport paths, electronic conduction in the metal and ionic conduction in the electrolyte. As the two paths are capacitively connected, space‐charge layers along the internal interfaces are coupled to electric potential differences between the paths and can be controlled or detected thereby. The present experiments show that the space charge couples to mechanical deformation of the hybrid material, so that external loading generates an electric current. The electric signal originates from charge displacement along the entire internal interface; the signal is particularly robust since the interface area is large. The charge transfer in response to load constitutes a piezoelectric response, yet the mechanism is quite different to classic piezoelectricity. The analysis in this work predicts links between electromechanical coupling parameters for strain sensing and actuation, which are in excellent agreement with the experiment.

Published

2018

38. Discrete Helmholtz charge distribution at liquid-liquid interfaces: Electrocapillarity, capacitance and non-linear spectroscopy studies

Author

Grégoire C. Gschwend and Hubert H. Girault

Subjects

Work (thermodynamics), General Chemical Engineering, capacitance, water, Electrocapillarity, ion adsorption, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, Capacitance, ities, Analytical Chemistry, charged interfaces, Phase (matter), Electrochemistry, surface, liquid-liquid interface, ITIES, double-layer capacitance, electrocapillarity, Chemistry, association, Charge density, tension, 021001 nanoscience & nanotechnology, 0104 chemical sciences, 2nd-harmonic generation, Chemical physics, impedance, double layer, Surface second harmonic generation, 0210 nano-technology

Abstract

The structure of the polarised interface between two immiscible electrolyte solutions (ITIES) has usually been deduced from electrocapillarity and capacitance measurements. However, these two methods only offer an indirect access to the surface change density, by differentiation and integration. In this work, we analyse the dependence on the potential difference and the organic phase electrolyte concentration of the surface charge density of the polarised ITIES. Our study is based on electrocapillarity, capacitance and surface second harmonic generation (SHG). This spectroscopic approach allows us to probe directly ionic concentrations and hence surface charge density. By comparing the results provided by these different methods, we confirm that integration of the capacitance curves yields too large values of the charge density. On the other hand, electrocapillarity and SHG provide consistent results over a large potential range. These results depict an ITIES weakly affected by the organic electrolyte concentration. Furthermore, the surface charge density depends quasi-linearly on the potential difference, at all concentrations. Altogether, these results support the model of a polarised ITIES made of two ionic face-to-face layers and devoid of diffuse layer, the so-called discrete Helmholtz model.

Published

2020

39. Two-dimensional condensation in camphor-10-sulphonic acid films at the mercury/electrolyte interface.

Author

Dörfler, H., Dietrich, J., Müller, E., and Philipp, R.

Abstract

The electrocapillarity and the barrier properties of camphor-10-sulphonic acid (CS) in various aqueous electrolytes (1 M NaSO, 3 M LiClO, 2 M KNO, 3 M KCl, 3 M KBr) were studied. From the electrocapillary curves the charge-density-potential and the surface-pressure-potential-curves were calculated and analyzed using the Lippmann-Helmholtz and Gibbs-equations. The cross-sectional areas a of CS, resulting from the maximum excess surface concentration, suggest a perpendicular orientation of CS-molecules in the condensed film at the potential of maximum adsorption. This orientation causes a dense packing and a strong interaction between the CS-molecules in the condensed film. The barrier properties that represent the reduction of Cu-ions in the presence of the adsorption layer were studied dc polarographically at high surface coverage. A change in the inhibition mechanism was observed due to the change of the structure in the adsorptions layer. The electrode reaction is strongly inhibited within the potential and concentration range of film condensation. [ABSTRACT FROM AUTHOR]

Published

1990

40. Can the equilibrium interfacial tensions be more in magnitude than non-equilibrium ones? Comment on 'Electrocapillarity and zero-frequency differential capacitance at the interface between mercury and ionic liquids measured using the pendant drop method' by N. Nishi et al. [Phys. Chem. Chem. Phys., 2015, 17, 5219]

Author

Rouvim Kadis

Subjects

Measurement method, 010304 chemical physics, Differential capacitance, Drop (liquid), General Physics and Astronomy, Electrocapillarity, chemistry.chemical_element, Thermodynamics, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Mercury (element), Physics::Fluid Dynamics, Drop method, chemistry.chemical_compound, chemistry, 0103 physical sciences, Ionic liquid, Physical and Theoretical Chemistry, Zero frequency

Abstract

In the paper commented upon, the electrocapillary curves for mercury in ionic liquids, obtained by static (pendant drop) and dynamic (drop-time) measurement methods, were compared to support the inference about ultraslow relaxation at the interface. Yet, the static, i.e. equilibrium interfacial tensions proved to be more in magnitude (at E

Published

2019

41. Liquid-Metal Microdroplets Formed Dynamically with Electrical Control of Size and Rate

Author

Khashayar Khoshmanesh, Kourosh Kalantar-zadeh, Ishan D. Joshipura, Arnan Mitchell, Yiliang Lin, Michael D. Dickey, and Shi-Yang Tang

Subjects

Liquid metal, Materials science, Mechanical Engineering, Microfluidics, Electrocapillarity, Nanotechnology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Surface tension, Flow focusing, Chemical engineering, Mechanics of Materials, General Materials Science, 0210 nano-technology, Body orifice

Abstract

Liquid metal co-injected with electrolyte through a microfluidic flow-focusing orifice forms droplets with diameters and production frequencies controlled in real time by voltage. Applying voltage to the liquid metal controls the interfacial tension via a combination of electrochemistry and electrocapillarity. This simple and effective method can instantaneously tune the size of the microdroplets, which has applications in composites, catalysts, and microsystems.

Published

2015

42. Uphill Movement of Sessile Droplets by Electrostatic Actuation

Author

Arup Kumar Das, Santanu Prasad Datta, and Prasanta Kumar Das

Subjects

Gravity (chemistry), Chemistry, Dynamics (mechanics), Surface force, Electrocapillarity, Nanotechnology, Surfaces and Interfaces, Mechanics, Condensed Matter Physics, Physics::Fluid Dynamics, Sessile drop technique, Circulation (fluid dynamics), Electrochemistry, Climb, General Materials Science, Spectroscopy, Voltage

Abstract

The dynamics of uphill motion and the internal circulation of a sessile droplet by inducing asymmetric electrocapillarity were formulated and investigated numerically. We developed and analyzed a coupled electro-hydrodynamic model that includes conservative body and surface forces along with electrostatic effects. The interplay between gravity and electrostatic actuation is influenced by induction voltage, the inclination of the surface, and the droplet volume. Actuation voltage on the sessile drop causes an internal circulation which, upon increasing strength, overcomes the gravitational pull to climb uphill. As uphill droplet climbing is a spatiotemporal phenomenon, droplet volume plays a major role in accommodating the internal circulations and subsequent climb. Simultaneously, actuation due to electrostatic force behaves differently on different inclined surfaces, causing a roll down at higher inclination and an uphill climb at lower ones. A pattern map has been generated to identify favorable conditions for uphill movement based on the inclination, actuation voltage, and volume of the droplet.

Published

2015

43. Influence of Electrocapillarity on the Water Meniscus Shape In The Atomic Force Microscopy

Author

Eugene A. Eliseev

Subjects

Materials science, Atomic force microscopy, General Physics and Astronomy, Meniscus, Electrocapillarity, Composite material

Published

2015

44. Electrocapillarity and zero-frequency differential capacitance at the interface between mercury and ionic liquids measured using the pendant drop method

Author

Tetsuo Sakka, Atsunori Hashimoto, Naoya Nishi, and Eiji Minami

Subjects

chemistry.chemical_classification, Tetrafluoroborate, Differential capacitance, Analytical chemistry, General Physics and Astronomy, Ionic bonding, Electrocapillarity, Electrochemistry, Surface tension, chemistry.chemical_compound, chemistry, Ionic liquid, Physical and Theoretical Chemistry, Alkyl

Abstract

The structure of ionic liquids (ILs) at the electrochemical IL|Hg interface has been studied using the pendant drop method. From the electrocapillarity (potential dependence of interfacial tension) differential capacitance (Cd) at zero frequency (in other words, static differential capacitance or differential capacitance in equilibrium) has been evaluated. The potential dependence of zero-frequency Cd at the IL|Hg interface exhibits one or two local maxima near the potential of zero charge (Epzc), depending on the cation of the ILs. For 1-ethyl-3-methylimidazolium tetrafluoroborate, an IL with the cation having a short alkyl chain, the Cdvs. potential curve has one local maximum whereas another IL, 1-octyl-3-methylimidazolium tetrafluoroborate, with the cation having a long alkyl chain, shows two maxima. These behaviors of zero-frequency Cd agree with prediction by recent theoretical and simulation studies for the electrical double layer in ILs. At negative and positive potentials far from Epzc, the zero-frequency Cd increases for both the ILs studied. The increase in zero-frequency Cd is attributable to the densification of ionic layers in the electrical double layer.

Published

2015

45. Rapid electrocapillary deformation of liquid metal with reversible shape retention

Author

Gough, Ryan C, Morishita, Andy M, Dang, Jonathan H, Moorefield, Matthew R, Shiroma, Wayne A, and Ohta, Aaron T

Published

2015

46. Field‐Controlled Electrical Switch with Liquid Metal

Author

James Wissman, Carmel Majidi, and Michael D. Dickey

Subjects

Liquid metal, Materials science, Bistability, General Chemical Engineering, bipolar electrochemistry, General Physics and Astronomy, Medicine (miscellaneous), Electrocapillarity, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), Instability, Physics::Fluid Dynamics, Bipolar electrochemistry, General Materials Science, Fluidics, electrical switches, Coalescence (physics), Full Paper, General Engineering, electrowetting, Full Papers, bistable, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical physics, Electrowetting, 0210 nano-technology, liquid metals

Abstract

When immersed in an electrolyte, droplets of Ga‐based liquid metal (LM) alloy can be manipulated in ways not possible with conventional electrocapillarity or electrowetting. This study demonstrates how LM electrochemistry can be exploited to coalesce and separate droplets under moderate voltages of ~1–10 V. This novel approach to droplet interaction can be explained with a theory that accounts for oxidation and reduction as well as fluidic instabilities. Based on simulations and experimental analysis, this study finds that droplet separation is governed by a unique limit‐point instability that arises from gradients in bipolar electrochemical reactions that lead to gradients in interfacial tension. The LM coalescence and separation are used to create a field‐programmable electrical switch. As with conventional relays or flip‐flop latch circuits, the system can transition between bistable (separated or coalesced) states, making it useful for memory storage, logic, and shape‐programmable circuitry using entirely liquids instead of solid‐state materials.

Published

2017

47. Theoretical problems in solid electrocapillarity

Author

Emmanuel M. Gutman

Subjects

Continuum mechanics, Chemistry, Surface stress, Electrocapillarity, Thermodynamics, Condensed Matter Physics, Thermodynamic equations, Surface tension, symbols.namesake, Classical mechanics, Gibbs–Duhem equation, Solid mechanics, Electrochemistry, symbols, General Materials Science, Electrical and Electronic Engineering, Maxwell relations

Abstract

The main problem in electrocapillarity of solid electrodes is the lack of clarity in determining the surface stress and basic equations. Within the framework of the Gibbs concept of geometrical dividing surface, the “surface stress” cannot be defined because methods of continuum mechanics can be applied to a physical surface layer (of finite thickness), but not to a mathematical surface. Gibbs never used the concept of surface stress, introducing only “surface tension” for a liquid electrode and “closely related quantity” for a solid electrode. Revisiting the derivation of the Gibbs adsorption equation, we prove its applicability to solid surfaces without the limiting requirement of constant state of strain, which was undeservedly interpreted by Eriksson as a shortcoming of the Gibbs theory caused to look for other approaches to surface stress problem. A critical analysis shows that the attempts (Shuttleworth, Eriksson, Couchman, Gokhstein, Weissmuller, etc.) to create a thermodynamic definition of the surface stress (as well as the formulation of fundamental thermodynamic equations and Maxwell relations operating with surface stresses) contain mathematical defects. It is shown that confusing interpretations of some Gibbs’ concepts encountered in the literature have led to “modifications” of the Lippmann equation based on the critical error in the Gibbs–Duhem relation due to the occurrence of an extensive variable, which is inadmissible. The famous Lippmann equation should not be modified, and it remains a unique electrocapillary relation applicable to liquid and solid electrodes.

Published

2014

48. Comment on 'On the ‘simple check’ of electrocapillarity' by AY Gokhshtein

Author

Emmanuel M. Gutman

Subjects

Surface (mathematics), Physics, Physical model, Electrocapillarity, Condensed Matter Physics, Thermodynamic equations, Thermodynamic model, Classical mechanics, Simple (abstract algebra), Electrochemistry, General Materials Science, Electrical and Electronic Engineering, Differential (infinitesimal), Maxwell relations, Mathematical physics

Abstract

It is shown that the so-called “equation of solid-state electrocapillarity” derived by Gokhshtein from the simplest thermodynamic model, earlier used by Lippmann, is an incorrect modification that is returned to the classic Lippmann equation if to take into account the usual definition of differential capacity of the electrical double layer. Consequently, Gokhshtein’s experiments can actually confirm only the validity of the Lippmann equation (with deviations caused by physicochemical processes in the double layer, which could not be taken into account in the thermodynamic equations). The thermodynamic model is insufficient for the interpretations of these experimental results, whose understanding requires physical models of the different phenomena occurring at the electrode surface.

Published

2014

49. General Properties of the Nernst-Planck-Poisson-Boltzmann System Describing Electrocapillary Effects in Porous Media

Author

Gérard Gagneux and Olivier Millet

Subjects

Physics, Lyapunov function, Mechanical Engineering, Electrocapillarity, Poisson–Boltzmann equation, symbols.namesake, Classical mechanics, Mechanics of Materials, Electric field, symbols, General Materials Science, Nernst equation, Statistical physics, Planck, Porous medium, Stationary state

Abstract

The Nernst-Planck-Poisson-Boltzmann system describes the evolution of ionic concentrations and electrocapillarity effects in porous media. The aim of this paper is a theoretical study of various drift-diffusion modellings. The well-posedness of the systems is proved and some qualitative properties of the global solution are shown to be satisfied (energy law, entropy law in the weak sense of Lyapunov functions, stationary states, Maxwellian distribution, influence of an external electric field). Moreover, some explicit solutions are established in the one-dimensional case.

Published

2014

50. Droplet-Based Microfluidic Thermal Management Methods for High Performance Electronic Devices

Author

Zhibin Yan, Guofu Zhou, Zhengguang Li, Lingling Shui, and Mingliang Jin

Subjects

Materials science, lcsh:Mechanical engineering and machinery, 020209 energy, Microfluidics, microfluidics, Mechanical engineering, Electrocapillarity, Review, 02 engineering and technology, Thermal management of electronic devices and systems, Cooling methods, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TJ1-1570, Electronics, Electrical and Electronic Engineering, Microscale chemistry, Mechanical Engineering, 3D IC packaging, electrowetting, 021001 nanoscience & nanotechnology, hot spots, Coolant, integrated/embedded thermal management, Control and Systems Engineering, Electrowetting, droplet, 0210 nano-technology

Abstract

Advanced thermal management methods have been the key issues for the rapid development of the electronic industry following Moore’s law. Droplet-based microfluidic cooling technologies are considered as promising solutions to conquer the major challenges of high heat flux removal and nonuniform temperature distribution in confined spaces for high performance electronic devices. In this paper, we review the state-of-the-art droplet-based microfluidic cooling methods in the literature, including the basic theory of electrocapillarity, cooling applications of continuous electrowetting (CEW), electrowetting (EW) and electrowetting-on-dielectric (EWOD), and jumping droplet microfluidic liquid handling methods. The droplet-based microfluidic cooling methods have shown an attractive capability of microscale liquid manipulation and a relatively high heat flux removal for hot spots. Recommendations are made for further research to develop advanced liquid coolant materials and the optimization of system operation parameters.

Published

2019