Review of Heat Transfer Research for Solar Thermochemical Applications

Lipiński, Wojciech; Davidson, Jane H.; Haussener, Sophia; Klausner, James F.; Mehdizadeh, A.; Petrasch, Joerg; Steinfeld, Aldo; Venstrom, Luke J.

doi:10.1115/1.4024088

Cited by 71 publications

(26 citation statements)

References 131 publications

(200 reference statements)

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“…At the same time, the catalysts investigated show reasonable stability in theses electrolytes. The ion conductivity of the various electrolytes was 16.45 S/m for 1M NaOH, 19.86 S/m for 1M KOH, and 0.86 S/m for 0.1M KHCO 3 . The conductivity of the wet Nafion membrane was 10 S/m.…”

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confidence: 99%

“…Our model provides insights and practical considerations for the design and implementation of a PEC device for the concurrent production of hydrogen and CO. Solar liquid fuel production can potentially be achieved by the reduction of water and CO 2 through two non-biological pathways: [1][2][3][4] i) solar thermochemical (STC) approaches, and ii) photoelectrochemical (PEC) approaches. In both cases, water and CO 2 is split into hydrogen and CO (a mixture called synthesis gas) and, for PEC approaches only, other lower order hydrocarbon products.…”

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confidence: 99%

“…17 reduced CO 2 to methanol in 0.5 M potassium bicarbonate (KHCO 3 ) utilizing different copper oxides, namely air-oxidized copper, anodized copper, and cuprous oxide thin film electrodes. The results suggested that CH 3 OH production may be associated with Cu(I) surface species which appeared to be reduced as CH 3 OH was produced. The results also showed that Cu(I) sites promoted catalytic activity and selectivity.…”

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Modeling of Concurrent CO₂and Water Splitting by Practical Photoelectrochemical Devices

Gutiérrez

Haussener

2016

J. Electrochem. Soc.

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Concurrent solar generation of hydrogen and CO through photoelectrochemical (PEC) water and CO 2 electrolysis, and the subsequent use of the product gas mixture in conventional Fischer-Tropsch processes, has the potential to provide a flexible pathway for direct solar generation of a variety of liquid fuels. In order for this approach to be practical, PEC devices must be designed to continuously and selectively provide a well-defined ratio of hydrogen to CO, independent of operating conditions. We develop a computational PEC device model providing insight into the dynamics and design requirements of such a device. We investigate a variety of combinations of catalysts (Ag, Cu, Ni, Pt, Co) and photoabsorbers (Si and Ga-based) under steady and transient solar irradiation conditions. Typical H 2 /CO ratios of 0.1 were observed for Ag-based electrodes, and ratios of 5 when using Cu-based electrodes. Variation in catalyst and photoabsorber properties provided guidance for the development of catalysts allowing for a H 2 /CO product ratio close to 2. Device design variations and the addition of Ni as a second cathode-side catalyst improved the generation of hydrogen, allowing H 2 /CO ratios to reach between 1.7 and 2.15. Transient simulations showed that product ratios vary significantly over the day and year, implying the use of storage or controlling measures or the addition of a water gas shift reactor. Our model provides insights and practical considerations for the design and implementation of a PEC device for the concurrent production of hydrogen and CO. Solar liquid fuel production can potentially be achieved by the reduction of water and CO 2 through two non-biological pathways: [1][2][3][4] i) solar thermochemical (STC) approaches, and ii) photoelectrochemical (PEC) approaches. In both cases, water and CO 2 is split into hydrogen and CO (a mixture called synthesis gas) and, for PEC approaches only, other lower order hydrocarbon products. Synthesis gas can subsequently be used in a Fischer-Tropsch process to produce liquid fuels such as gasoline and diesel. In STC approaches, redox couples are used and alternatingly reduced then oxidized at temperatures above 1000 K while splitting water and CO 2 . Synthesis gas is very selectively produced at a tailorable hydrogen to CO ratio. 5In PEC approaches, water electrolysis has been achieved, 6 and the reduction of CO 2 has been demonstrated, 7-10 but with challenges in respect to product selectivity and efficiency. While the PEC production of CO requires the involvement of two electrons only, methanol or higher order hydrocarbon products require the involvement of six, eight, or even twelve electrons (Eqs. 5 and 6), presenting significant challenges for the development of efficient and selective catalysts. Assuming that STC and PEC approaches can be complementary solar fuel processing pathways, synthesis gas appears to be the obvious fuel choice, as it can be produced by both pathways (comparatively easy in the case of PEC compared to other products) and would subseque...

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Modeling of Concurrent CO₂and Water Splitting by Practical Photoelectrochemical Devices

Gutiérrez

Haussener

2016

J. Electrochem. Soc.

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“…This paper aims to provide a review of the research area of numerical modelling of STRSs, outline the challenges unique to high-temperature STRS modelling, highlight the existing literature in the field and their attempts to overcome these hurdles, and guide the reader to relevant studies related to different material/-chemical processes and physical reactor configurations. The reader is also referred to the recent reviews of the areas of heat transfer within STRSs and experimental studies of them by Lipiń ski et al (2013) and Alonso and Romero (2015), respectively. Fig.…”

Section: Introductionmentioning

confidence: 99%

Modelling of solar thermochemical reaction systems

et al. 2017

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a b s t r a c tThis article reviews the progress, challenges and opportunities in numerical modelling of thermal transport, thermochemical reactions and thermomechanics in high-temperature solar thermochemical systems. Continuum-scale models are presented in mathematical detail while highlighting the literature that uses them. The discussion is enhanced by selected examples of numerical studies of solar thermochemical systems for solar fuels and commodity material production. Property predictions necessary for the modelling of solar thermochemical reaction systems are covered.

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“…The determination of the apparent radiative properties of dispersed media based on media morphology and composition becomes crucial to the accuracy of this approach. This topic has continuously attracted interest from the radiative transfer community due to its large variety of applications such as solar energy conversion [3][4][5] , nuclear technologies [6] , snow physics [7] , and medical applications [8] . The reviews of Viskanta and Mengüç [9] , Baillis and Sacadura [10] , and Bail-lis et al [11] present the theoretical approaches and experimental methodologies for the characterization of spectral, directional apparent radiative properties of particulate and realistic disperse media, such as foams, fibrous materials, various ceramics, polymer coatings containing microspheres, and aerogel super-insulations.…”

Section: Introductionmentioning

confidence: 99%

Radiative characterization of random fibrous media with long cylindrical fibers: Comparison of single- and multi-RTE approaches

Randrianalisoa

Haussener

Baillis

et al. 2017

Journal of Quantitative Spectroscopy and Radiative Transfer

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a b s t r a c tRadiative heat transfer is analyzed in participating media consisting of long cylindrical fibers with a diameter in the limit of geometrical optics. The absorption and scattering coefficients and the scattering phase function of the medium are determined based on the discrete-level medium geometry and optical properties of individual fibers. The fibers are assumed to be randomly oriented and positioned inside the medium. Two approaches are employed: a volume-averaged two-intensity approach referred to as multi-RTE approach and a homogenized single-intensity approach referred to as the single-RTE approach . Both approaches require effective properties, determined using direct Monte Carlo ray tracing techniques. The macroscopic radiative transfer equations (for single intensity or two volume-averaged intensities) with the corresponding effective properties are solved using Monte Carlo techniques and allow for the determination of the radiative flux distribution as well as overall transmittance and reflectance of the medium. The results are compared against predictions by the direct Monte Carlo simulation on the exact morphology. The effects of fiber volume fraction and optical properties on the effective radiative properties and the overall slab radiative characteristics are investigated. The single-RTE approach gives accurate predictions for high porosity fibrous media (porosity about 95%). The multi-RTE approach is recommended for isotropic fibrous media with porosity in the range of 79 −95%.

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Review of Heat Transfer Research for Solar Thermochemical Applications

Cited by 71 publications

References 131 publications

Modeling of Concurrent CO₂and Water Splitting by Practical Photoelectrochemical Devices

Modeling of Concurrent CO₂and Water Splitting by Practical Photoelectrochemical Devices

Modelling of solar thermochemical reaction systems

Radiative characterization of random fibrous media with long cylindrical fibers: Comparison of single- and multi-RTE approaches

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Review of Heat Transfer Research for Solar Thermochemical Applications

Cited by 71 publications

References 131 publications

Modeling of Concurrent CO2and Water Splitting by Practical Photoelectrochemical Devices

Modeling of Concurrent CO2and Water Splitting by Practical Photoelectrochemical Devices

Modelling of solar thermochemical reaction systems

Radiative characterization of random fibrous media with long cylindrical fibers: Comparison of single- and multi-RTE approaches

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Modeling of Concurrent CO₂and Water Splitting by Practical Photoelectrochemical Devices

Modeling of Concurrent CO₂and Water Splitting by Practical Photoelectrochemical Devices