Fe2O3@LaxSr1−xFeO3 Core–Shell Redox Catalyst for Methane Partial Oxidation

Shafiefarhood, Arya; Galinsky, Nathan; Huang, Yan; Chen, Yanguang; Li, Fanxing

doi:10.1002/cctc.201301104

Cited by 118 publications

(72 citation statements)

References 59 publications

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“…This approach provides a promising strategy, not only to address the stability requirement, but also to improve the performance in terms of reactivity, redox properties and coke resistance, depending on the employed shell materials. Such core-shell structured nanomaterials have shown excellent performance in methane reforming [117,118,138,139,140] and chemical looping processes [14,40,119,120,121,122,123,124,141]. …”

Section: Improvements To Oxygen Carriersmentioning

confidence: 99%

Advanced Chemical Looping Materials for CO2 Utilization: A Review

Galvita

Poelman

et al. 2018

Materials

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Combining chemical looping with a traditional fuel conversion process yields a promising technology for low-CO2-emission energy production. Bridged by the cyclic transformation of a looping material (CO2 carrier or oxygen carrier), a chemical looping process is divided into two spatially or temporally separated half-cycles. Firstly, the oxygen carrier material is reduced by fuel, producing power or chemicals. Then, the material is regenerated by an oxidizer. In chemical looping combustion, a separation-ready CO2 stream is produced, which significantly improves the CO2 capture efficiency. In chemical looping reforming, CO2 can be used as an oxidizer, resulting in a novel approach for efficient CO2 utilization through reduction to CO. Recently, the novel process of catalyst-assisted chemical looping was proposed, aiming at maximized CO2 utilization via the achievement of deep reduction of the oxygen carrier in the first half-cycle. It makes use of a bifunctional looping material that combines both catalytic function for efficient fuel conversion and oxygen storage function for redox cycling. For all of these chemical looping technologies, the choice of looping materials is crucial for their industrial application. Therefore, current research is focused on the development of a suitable looping material, which is required to have high redox activity and stability, and good economic and environmental performance. In this review, a series of commonly used metal oxide-based materials are firstly compared as looping material from an industrial-application perspective. The recent advances in the enhancement of the activity and stability of looping materials are discussed. The focus then proceeds to new findings in the development of the bifunctional looping materials employed in the emerging catalyst-assisted chemical looping technology. Among these, the design of core-shell structured Ni-Fe bifunctional nanomaterials shows great potential for catalyst-assisted chemical looping.

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Section: Improvements To Oxygen Carriersmentioning

confidence: 99%

Advanced Chemical Looping Materials for CO2 Utilization: A Review

Galvita

Poelman

et al. 2018

Materials

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“…The challenge of NiO based redox catalysts, however, is their high tendency for coke formation, high cost, and health concerns (Adanez et al, 2012;Neal et al, 2014). Fe-based oxides have the advantages of being cheaper, low agglomeration, high melting point and more environmentally benign (Cabello et al, 2014a;Adanez et al, 2012;Neal et al, 2014Neal et al, , 2015Shafiefarhood et al, 2014;Galinsky et al, 2015). However, iron oxide based redox catalysts are not particularly active for methane oxidation (Cabello et al, 2014a;Shafiefarhood et al, 2014), and tend to have low selectivity toward methane partial oxidation.…”

Section: Introductionmentioning

confidence: 99%

“…Fe-based oxides have the advantages of being cheaper, low agglomeration, high melting point and more environmentally benign (Cabello et al, 2014a;Adanez et al, 2012;Neal et al, 2014Neal et al, , 2015Shafiefarhood et al, 2014;Galinsky et al, 2015). However, iron oxide based redox catalysts are not particularly active for methane oxidation (Cabello et al, 2014a;Shafiefarhood et al, 2014), and tend to have low selectivity toward methane partial oxidation. Notably, the reactivity and selectivity in CLMR process can be improved by combining different materials to bring synergetic effect or form solid solution (spinel, perovskite, et al) (Cabello et al, 2014a;Neal et al, 2014Neal et al, , 2015Bhavsar and Veser, 2013;Zhu et al, 2014;Chen et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Reduction kinetics of lanthanum ferrite perovskite for the production of synthesis gas by chemical-looping methane reforming

Dai

Cheng

et al. 2016

Chemical Engineering Science

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“…Typical perovskite takes the form of ABO 3Àd , where A is a large cation of either the alkali earth or rare earth metal and B is a smaller transition metal cation [55]. As a support, mixed ionic and electronic conductive (MIEC) perovskites such as La 1Àx Sr x FeO 3 (LSF) have shown to enhance the redox activity of iron oxides by nearly two orders of magnitude [51][52][53][54]. Perovskite and perovskite supported iron oxide have also been explored as redox catalysts for syngas generation and water-splitting [42,56].…”

Section: Introductionmentioning

confidence: 99%

Ca1−A MnO3 (A = Sr and Ba) perovskite based oxygen carriers for chemical looping with oxygen uncoupling (CLOU)

et al. 2015

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h i g h l i g h t sSr and Ba are doped into the CaMnO 3 structure for enhanced phase stability and CLOU properties. Strontium dopant helps to prevent irreversible decomposition of the perovskite structure. Sr-doped oxygen carriers have CLOU capabilities at lower temperatures while being redox stable. Computational techniques, such as DFT, can potentially be used to guide oxygen carrier selection. a b s t r a c tOperated under a cyclic redox mode with an oxygen carrier, the chemical looping with oxygen uncoupling (CLOU) process offers the potential to effectively combust solid fuels while capturing CO 2 . Development of oxygen carriers capable of reversibly exchanging their active lattice oxygen (O 2À ) with gaseous oxygen (O 2 ) under varying external oxygen partial pressure (P O2 ) is of key importance to CLOU process performance. This article investigates the effect of A-site dopants on CaMnO 3 based oxygen carriers for CLOU. Both Sr and Ba are explored as potential dopants at various concentrations. Phase segregations are observed with the addition of Ba dopant even at relatively low concentrations (5% A-site doping). In contrast, stable solid solutions are formed with Sr dopant at a wide range of doping level. While CaMnO 3 perovskite suffers from irreversible change into Ruddlesden-Popper (Ca 2 MnO 4 ) and spinel (CaMn 2 O 4 ) phases under cyclic redox conditions, Sr doping is found to effectively stabilize the perovskite structure. In-situ XRD studies indicate that the Sr doped CaMnO 3 maintains a stable orthorhombic perovskite structure under an inert environment (tested up to 1200°C). The same oxygen carrier sample exhibited high recyclability over 100 redox cycles at 850°C. Besides being highly recyclable, Sr doped CaMnO 3 is found to be capable of releasing its lattice oxygen at a temperature significantly lower than that for CaMnO 3 , rendering it a potentially effective oxygen carrier for solid fuel combustion and carbon dioxide capture.

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Fe₂O₃@La_xSr_1−xFeO₃ Core–Shell Redox Catalyst for Methane Partial Oxidation

Cited by 118 publications

References 59 publications

Advanced Chemical Looping Materials for CO2 Utilization: A Review

Advanced Chemical Looping Materials for CO2 Utilization: A Review

Reduction kinetics of lanthanum ferrite perovskite for the production of synthesis gas by chemical-looping methane reforming

Ca1−A MnO3 (A = Sr and Ba) perovskite based oxygen carriers for chemical looping with oxygen uncoupling (CLOU)

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