Wood-Templated CeO<sub>2</sub> as Active Material for Thermochemical CO Production

Malonzo, Camille D.; Smith, Robert M. De; Rudisill, Stephen G.; Petkovich, Nicholas D.; Davidson, Jane H.; Stein, Andreas

doi:10.1021/jp5083449

Cited by 27 publications

(35 citation statements)

References 37 publications

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“…We have demonstrated the technical feasibility of the ceria‐based redox cycle using a solar cavity receiver containing porous structures and the entire production chain to solar kerosene from H 2 O and CO 2 . It was shown that the morphology of the porous structure has a significant impact on the cycle's performance, e.g., on the molar conversion and energy efficiency, because the reduction step is heat transfer controlled, while the oxidation step is surface/mass transfer controlled . Therefore, for a given volume of the solar cavity receiver, a desired porous structure should feature high mass loading for maximum fuel output, appropriate optical thickness for volumetric absorption and uniform heating during the endothermic reduction step, and a high specific surface area for rapid reaction kinetics during the exothermic oxidation step with H 2 O and/or CO 2 .…”

Section: Introductionmentioning

confidence: 99%

“…[16] It was shown that the morphology of the porous structure has a significant impact on the cycle's performance, e.g., on the molar conversion and energy efficiency, because the reduction step is heat transfer controlled, while the oxidation step is surface/mass transfer controlled. [13,17,18] Therefore, for a given volume of the solar cavity receiver, a desired porous structure should feature high mass loading for maximum fuel output, appropriate optical thickness for volumetric absorption and uniform heating during the endothermic reduction step, and a high specific surface area for rapid reaction kinetics during the exothermic oxidation step with H 2 O and/or CO 2 . Reticulated porous ceramic (RPC) foam-type structures with dual-scale interconnected porosity (mm-and μm-sized pores within the struts) fulfill some of these desired characteristics.…”

Section: Introductionmentioning

confidence: 99%

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Additive‐Manufactured Ordered Porous Structures Made of Ceria for Concentrating Solar Applications

et al. 2019

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Porous structures made of redox active ceria are attractive for high‐temperature concentrating solar applications and particularly for the thermochemical splitting of H2O and CO2 as their enhanced heat and mass transport properties lead to fast reaction rates, especially with regard to the absorption of concentrated solar radiation during the endothermic reduction step. Hierarchically ordered porous structures, fabricated by the Schwartzwald replica method on 3D‐printed polymer scaffolds, are experimentally assessed for their ability to volumetrically absorb high‐flux irradiation of up to 670 suns. Temperature distributions across the porosity‐gradient path are measured (peak 1724 K) and compared with that obtained for a reticulated porous ceramic (RPC) structure with a uniform porosity. To assist the analysis, a Monte Carlo ray‐tracing model is developed for pore‐level numerical simulations of the ordered geometries and applied to analyze the absorbing–emitting–scattering exchange and determine the radiation attenuation and the temperature distribution at a radiative equilibrium. In contrast to the Bouguer's law exponential‐decay attenuation of incident radiation observed for the RPC, the ordered structures with a porosity gradient exhibit a step‐wise radiative attenuation that leads to a more uniform temperature distribution across the structure. This in turn predicts a superior redox performance.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Additive‐Manufactured Ordered Porous Structures Made of Ceria for Concentrating Solar Applications

et al. 2019

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“…Sometimes the geometrical concentration ratio is defined (Malonzo et al, 2014), which correspond to the ratio between the collector area and the receiver area. However, this definition assumes a perfect energy conversion efficiency during the redirection and concentration steps.…”

Section: Definitionsmentioning

confidence: 99%

“…This field has recently picked up momentum driven by the desire for alternative, renewable and sustainable approaches for fuel processing, and material and chemical commodity production, as well as for direct, energydense, and long-term storage of solar energy. Among the existing solar-driven, non-biological chemistry routes which include solar thermochemistry, photocatalysis and photoelectrochemistry, solar thermochemistry has reached the largest scale demonstrations (up to 100 kW) (Villasmil et al, 2013;Chueh et al, 2010;Säck et al, 2016), demonstrated stability over hundreds of cycles (Malonzo et al, 2014), and enormous versatility in demonstrated chemical reactions (Scheffe and Steinfeld, 2014;Steinfeld, May 2005;Romero and Steinfeld, 2012;Bader and Lipinski, 2017).…”

Section: Introduction and Historical Backgroundmentioning

confidence: 99%

“…metal oxides which are doped with other metals in order to facilitate the reduction and/or improve the thermal stability. The first of this kind have been doped ferrites ( perovskite-type materials have shown potential in terms of fuel productivity and thermal stability (Chueh et al, 2010;Malonzo et al, 2014), and are currently more intensively researched. These oxides generally present a lower reduction temperature (around 1800 K), but also a smaller productivity (220 mmol CO /g for structured pure ceria (Furler et al, 2014) than stoichiometric oxides.…”

Section: Introduction and Historical Backgroundmentioning

confidence: 99%

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High-flux optical systems for solar thermochemistry

et al. 2017

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a b s t r a c tHigh-flux optical systems (HFOSs) are optical concentrators used to increase the radiative flux of the natural terrestrial solar irradiation. High radiative flux concentration leads to high energy density in solar receivers which allows to obtain high temperatures. In solar thermochemical applications, the hightemperature heat drives endothermic thermochemical reactions. HFOSs have been deployed for research and development of solar thermochemical devices and systems, from solar reacting media to solar reactors. Here, we review the designs and characteristics of HFOSs as well as challenges and opportunities in the area of high-flux optical systems for solar thermochemical applications.

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Biomimetic cork-based CeO2 ecoceramics for hydrogen generation using concentrated solar energy

Pullar

Gil²,

Oliveira

2016

Ciência & Tecnologia dos Materiais

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Naturally occurring and sustainable materials can be used as a template to create biomimetic/biomorphic ceramics, known as Ecoceramics (environmentally conscious ceramics). In this work, cork was chosen as template to produce novel ceria (CeO2) ecoceramics, for applications in water splitting for H2 production via direct concentrated solar thermochemical fuel production (TCFP). The cork powder was pyrolised at 900 °C and the resulting carbon skeleton was infiltrated with an aqueous CeO2 precursor, and then heated at 1000 °C for 2 h to produce the ecoceramic. The cellular structure of the cork was maintained, with hexagonal cell dimensions of 20-30 μm in diameter, but the grains were nanoscale at ≤100 nm. XRD data confirmed that CeO2 was the only crystalline phase obtained. An important feature was that, while the rectangular side walls were maintained to hold the threedimensionally ordered macroporous (3DOM) cellular cork structure, the rear hexagonal walls were pierced repeatedly through the structure, unlike in the original cork structure, which will allow gasses such as H2 to permeate well into the structure, greatly increasing the reactive area available for catalysis. The next step will be to test the capabilities of both the regular, porous 3DOM structure and the nanoscale grains for thermochemical water splitting to produce hydrogen under direct concentrated solar energy.

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Wood-Templated CeO₂ as Active Material for Thermochemical CO Production

Cited by 27 publications

References 37 publications

Additive‐Manufactured Ordered Porous Structures Made of Ceria for Concentrating Solar Applications

Additive‐Manufactured Ordered Porous Structures Made of Ceria for Concentrating Solar Applications

High-flux optical systems for solar thermochemistry

Biomimetic cork-based CeO2 ecoceramics for hydrogen generation using concentrated solar energy

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Wood-Templated CeO2 as Active Material for Thermochemical CO Production

Cited by 27 publications

References 37 publications

Additive‐Manufactured Ordered Porous Structures Made of Ceria for Concentrating Solar Applications

Additive‐Manufactured Ordered Porous Structures Made of Ceria for Concentrating Solar Applications

High-flux optical systems for solar thermochemistry

Biomimetic cork-based CeO2 ecoceramics for hydrogen generation using concentrated solar energy

Contact Info

Product

Resources

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Wood-Templated CeO₂ as Active Material for Thermochemical CO Production