Vapor-fed microfluidic hydrogen generator

Modestino, Miguel A.; Dumortier, Mikaël; Hashemi, S. Mohammad H.; Haussener, Sophia; Moser, Christophe

doi:10.1039/c5lc00259a

Cited by 39 publications

(46 citation statements)

References 42 publications

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“…The gaseous water is relatively easier split due to its lower standard Gibbs free energy of formation (−228.59 kJ mol −1 ) in comparison with that of liquid water (−237.18 kJ mol −1 ) . In 2015, Modestino has assessed the abilities of the vapor‐fed microfluidic electrolyzer in balancing the water, gas, and ionic transport processes during a continuous and steady water electrolysis . To support an efficient gas phase water splitting, the material should be hygroscopic to maintain a rapid and sufficient moisture adsorption, be porous to decrease the gas diffusion limitations, be highly ionic conductive and catalytically active for fast reaction kinetics.…”

Section: Fundamental Requirements Of Materials For Photoelectrocatalymentioning

confidence: 93%

Photoelectrocatalytic Materials for Solar Water Splitting

Yao

Han

et al. 2018

Advanced Energy Materials

411

257

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Photoelectrocatalytic water splitting offers a promising approach to convert sunlight into sustainable hydrogen energy. A thorough understanding of the relationships between the properties and functions of photoelectrocatalytic materials plays a crucial role in the design and fabrication of efficient photoelectrochemical systems for water splitting. This review presents the advances in the development of efficient photoelectrocatalytic materials. First, the fundamentals involved in the photoelectrocatalytic water splitting are elaborated. Then, the critical properties of photoelectrocatalytic materials are classified and discussed according to the associated photoelectrochemical processes, including light absorption, charge separation, charge transportation, and photoelectrocatalytic reactions. The importance of heterointerfaces in photoelectrodes is also mentioned in conjunction with the illustration of some functional interlayer materials. Finally, some strategies that can be employed in material screening and optimization for the construction of highly efficient photoelectrochemical devices for water splitting are also discussed.

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Section: Fundamental Requirements Of Materials For Photoelectrocatalymentioning

confidence: 93%

Photoelectrocatalytic Materials for Solar Water Splitting

Yao

Han

et al. 2018

Advanced Energy Materials

411

257

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“…[75] These dehydration effects have been recently demonstrated in a microfluidic water-vapor electrolyzer (Figure 4 d3). [76] As the device operated, the ohmic resistance increased because of the loss of water from the ionomer, which led to lower current densities at the steady state. Overall, water-vapor feeds are promising for solar-fuel generators, assuming that cost metrics and the correct current-density operating regime are amenable.…”

Section: Vapor-feed Designmentioning

confidence: 99%

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

et al. 2016

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An integrated cell for the solar‐driven splitting of water consists of multiple functional components and couples various photoelectrochemical (PEC) processes at different length and time scales. The overall solar‐to‐hydrogen (STH) conversion efficiency of such a system depends on the performance and materials properties of the individual components as well as on the component integration, overall device architecture, and system operating conditions. This Review focuses on the modeling‐ and simulation‐guided development and implementation of solar‐driven water‐splitting prototypes from a holistic viewpoint that explores the various interplays between the components. The underlying physics and interactions at the cell level is are reviewed and discussed, followed by an overview of the use of the cell model to provide target properties of materials and guide the design of a range of traditional and unique device architectures.

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“…When devices are operated with pure water or vapor, solid-state ion conductors are required to allow for ion-transport between the electrodes. 65,66 Under these circumstances the interfacial layer of the ionomer that covers the catalyst surface plays a very important role in defining the overall device performance. Mainly, this ionomer layer needs to allow for fast water, gas and ion transport between the surfaces of the catalyst into the bulk region of the device.…”

Section: à2mentioning

confidence: 99%

“…83 Notably, modelling of transport processes has provided insights into the design of solar-water splitting devices operated under water vapor feeds, 65,178,179 and near-neutral pH electrolytes. 43,82 These conditions have complex mass transport characteristics due to the limitations expected from the low concentration of water in vapor feeds, or the presence of multiple ionic species with non-uniform concentrations in buffered electrolytes.…”

Section: Coupled Processes In Integrated Solar-hydrogen Devicesmentioning

confidence: 99%

Mass transport aspects of electrochemical solar-hydrogen generation

Modestino

Hashemi

Haussener

2016

Energy Environ. Sci.

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The conception of practical solar-hydrogen generators requires the implementation of engineering design principles that allow photo-electrochemical material systems to operate efficiently, continuously and stably over their lifetime. At the heart of these engineering aspects lie the mass transport of reactants, intermediates and products throughout the device. This review comprehensively covers these aspects and ties together all of the processes required for the efficient production of pure streams of solar-hydrogen. In order to do so, the article describes the fundamental physical processes that occur at different locations of a generalized device topology and presents the state-of-the-art advances in materials and engineering approaches to mitigate masstransport challenges. Processes that take place in the light absorber and electrocatalyst components are only briefly described, while the main focus is given to mass transport processes in the boundary-layer and bulk liquid or solid electrolytes. Lastly, a perspective on how engineering approaches can enable more efficient solar-fuel generators is presented. Broader contextSolar-hydrogen generators have the potential to trigger the incorporation of a much larger share of solar energy sources in our current energy landscape. These technologies can directly capture and store energy from the sun in the form of hydrogen molecules. As hydrogen can be transported, and stored for long periods of time, solar-hydrogen devices allow for the spacio-temporal decoupling of the energy generation and consumption processes, and in this way provide a larger flexibility to the electrical grid. While significant focus has been given to the development of photoelectrochemical materials for solar water-splitting, equally important are engineering aspects related to the materials' integration into devices that can operate stably, and produce pure hydrogen streams continuously over long lifetimes. This review provides a broad view on these engineering challenges and approaches to conceive practical solar-hydrogen generators.

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Vapor-fed microfluidic hydrogen generator

Cited by 39 publications

References 42 publications

Photoelectrocatalytic Materials for Solar Water Splitting

Photoelectrocatalytic Materials for Solar Water Splitting

Modeling, Simulation, and Implementation of Solar‐Driven Water‐Splitting Devices

Mass transport aspects of electrochemical solar-hydrogen generation

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