Low-temperature, manganese oxide-based, thermochemical water splitting cycle

Xu, Bingjun; Bhawe, Yashodhan; Davis, Mark E.

doi:10.1073/pnas.1206407109

Cited by 71 publications

(62 citation statements)

References 25 publications

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“…Generation of H 2 occurs at 850°C in this cycle ( Fig. 1) and the cycle is devoid of corrosive products (8). Thermal oxidation of Mn 3 O 4 to Mn 2 O 3 is thermodynamically unfavorable, but the use of Na 2 CO 3 drastically decreases the ΔG and forms MnO(s) and α-NaMnO 2 (s) at 850°C with the evolution of CO 2 (g), as shown in step 1 (Eq.…”

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

“…In this context, the thermochemical cycle based on Mn 3 O 4 /MnO oxides proposed by Davis and coworkers is noteworthy (8). The four reactions in this cycle are shown in Fig.…”

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

“…Thermal oxidation of Mn 3 O 4 to Mn 2 O 3 is thermodynamically unfavorable, but the use of Na 2 CO 3 drastically decreases the ΔG and forms MnO(s) and α-NaMnO 2 (s) at 850°C with the evolution of CO 2 (g), as shown in step 1 (Eq. S3) (8,9). The CO 2 evolution temperature can be decreased drastically (∼600°C) with the use of nanoparticles of Mn 3 O 4 and Na 2 CO 3 obtained with ball milling (Fig.…”

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

“…During step 2 (Eq. S4), introduction of H 2 O(g) at 850°C oxidizes MnO to α-NaMnO 2 with the evolution of H 2 (g) (8). The main hurdle in this cycle is the slow H 2 evolution.…”

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

“…The two-step process involving the thermal decomposition of metal oxides followed by reoxidation by reacting with H 2 O to yield H 2 is an attractive and viable process that can be rendered to become an isothermal process. Thermochemical splitting of H 2 O at low temperatures (<1,000°C) is accomplished by a minimum of three steps as dictated by thermodynamic energy constraints (7,8). In this paper we present the highlights of recent investigations of H 2 O splitting by the low-temperature multistep process as well as the high temperature two-step process.…”

mentioning

confidence: 99%

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Solar thermochemical splitting of water to generate hydrogen

Rao

Dey

2017

Proc. Natl. Acad. Sci. U.S.A.

126

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Solar photochemical means of splitting water (artificial photosynthesis) to generate hydrogen is emerging as a viable process. The solar thermochemical route also promises to be an attractive means of achieving this objective. In this paper we present different types of thermochemical cycles that one can use for the purpose. These include the low-temperature multistep process as well as the high-temperature two-step process. It is noteworthy that the multistep process based on the Mn(II)/Mn(III) oxide system can be carried out at 700°C or 750°C. The two-step process has been achieved at 1,300°C/900°C by using yttrium-based rare earth manganites. It seems possible to render this high-temperature process as an isothermal process. Thermodynamics and kinetics of H 2 O splitting are largely controlled by the inherent redox properties of the materials. Interestingly, under the conditions of H 2 O splitting in the high-temperature process CO 2 can also be decomposed to CO, providing a feasible method for generating the industrially important syngas (CO+H 2 ). Although carbonate formation can be addressed as a hurdle during CO 2 splitting, the problem can be avoided by a suitable choice of experimental conditions. The choice of the solar reactor holds the key for the commercialization of thermochemical fuel production. The impact of global climate change as well as the likely shortage of fossil fuels demand harvesting of energy using renewable sources. Although solar energy captured by the Earth in an hour is expected to satisfy the energy demand of the world for a year, the high energy density and nonpolluting end product renders hydrogen a viable alternative to fossil fuels (1). In this context, conversion of solar power to H 2 and synfuels with the utilization of renewable H 2 O and CO 2 seems to be a sound option. Artificial photosynthesis and photovoltaic-powered electrolysis of water are promising approaches, although their implementation is somewhat restricted because of the low solar-tofuel conversion efficiency (η solar-to-fuel ) of <5% and <15%, respectively (2, 3). The other strategy would be a solarthermochemical process that provides a high theoretical efficiency and enables large-scale production of H 2 by using the entire solar spectrum (4). Research in thermochemical splitting of H 2 O made a beginning in the early 1980s (5, 6) and several thermochemical cycles have been examined. Thermochemical methods come under two main categories, the low-temperature multistep processes and the high-temperature two-step processes. The two-step process involving the thermal decomposition of metal oxides followed by reoxidation by reacting with H 2 O to yield H 2 is an attractive and viable process that can be rendered to become an isothermal process. Thermochemical splitting of H 2 O at low temperatures (<1,000°C) is accomplished by a minimum of three steps as dictated by thermodynamic energy constraints (7,8). In this paper we present the highlights of recent investigations of H 2 O splitting by the low-temperature m...

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Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

“…In this context, the thermochemical cycle based on Mn 3 O 4 /MnO oxides proposed by Davis and coworkers is noteworthy (8). The four reactions in this cycle are shown in Fig.…”

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

“…During step 2 (Eq. S4), introduction of H 2 O(g) at 850°C oxidizes MnO to α-NaMnO 2 with the evolution of H 2 (g) (8). The main hurdle in this cycle is the slow H 2 evolution.…”

Section: Low-temperature Multistep Cyclesmentioning

confidence: 99%

mentioning

confidence: 99%

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Solar thermochemical splitting of water to generate hydrogen

Rao

Dey

2017

Proc. Natl. Acad. Sci. U.S.A.

126

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A Computational Framework to Accelerate the Discovery of Perovskites for Solar Thermochemical Hydrogen Production: Identification of Gd Perovskite Oxide Redox Mediators

Bare

Morelock

Musgrave

2022

Adv Funct Materials

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A high‐throughput computational framework to identify novel multinary perovskite redox mediators is presented, and this framework is applied to discover the Gd‐containing perovskite oxide compositions Gd2BB′O6, GdA′B2O6, and GdA′BB′O6 that split water. The computational scheme uses a sequence of empirical approaches to evaluate the stabilities, electronic properties, and oxygen vacancy thermodynamics of these materials, including contributions to the enthalpies and entropies of reduction, ΔHTR and ΔSTR. This scheme uses the machine‐learned descriptor τ to identify compositions that are likely stable as perovskites, the bond valence method to estimate the magnitude and phase of BO6 octahedral tilting and provide accurate initial estimates of perovskite geometries, and density functional theory including magnetic‐ and defect‐sampling to predict STCH‐relevant properties. Eighty‐three promising STCH candidate perovskite oxides down‐selected from 4392 Gd‐containing compositions are reported, three of which are referred to experimental collaborators for characterization and exhibit STCH activity. The results demonstrate that the high‐throughput computational scheme described herein—which is used to evaluate Gd‐containing compositions but can be applied to any multinary perovskite oxide compositional space(s) of interest—accelerates the discovery of novel STCH active redox mediators with reasonable computational expense.

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Lithium Imide Synergy with 3d Transition‐Metal Nitrides Leading to Unprecedented Catalytic Activities for Ammonia Decomposition

Guo

Wang

et al. 2015

Angewandte Chemie

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Alkali metals have been widely employed as catalyst promoters; however, the promoting mechanism remains essentially unclear. Li, when in the imide form, is shown to synergize with 3d transition metals or their nitrides TM(N) spreading from Ti to Cu, leading to universal and unprecedentedly high catalytic activities in NH 3 decomposition, among which Li 2 NH À MnN has an activity superior to that of the highly active Ru/carbon nanotube catalyst. The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li 2 NH and 3d TM(N) to form ternary nitride of LiTMN and H 2 , and 2) the ammoniation of LiTMN to Li 2 NH, TM(N) and N 2 resulting in the neat reaction of 2 NH 3 ÐN 2 + 3 H 2 . Li 2 NH, as an NH 3 transmitting agent, favors the formation of higher Ncontent intermediate (LiTMN), where Li executes inductive effect to stabilize the TMÀN bonding and thus alters the reaction energetics.

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Low-temperature, manganese oxide-based, thermochemical water splitting cycle

Cited by 71 publications

References 25 publications

Solar thermochemical splitting of water to generate hydrogen

Solar thermochemical splitting of water to generate hydrogen

A Computational Framework to Accelerate the Discovery of Perovskites for Solar Thermochemical Hydrogen Production: Identification of Gd Perovskite Oxide Redox Mediators

Lithium Imide Synergy with 3d Transition‐Metal Nitrides Leading to Unprecedented Catalytic Activities for Ammonia Decomposition

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