Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle

Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle

The computational thermodynamic analysis of a samarium oxide-based two-step solar thermochemical water splitting cycle is reported. The analysis is performed using HSC chemistry software and databases. The first (solar-based) step drives the thermal reduction of Sm2O3 into Sm and O2. The second (non...

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Main Authors: Rahul Bhosale, Anand Kumar, Fares AlMomani, Ujjal Ghosh, Mohammad Saad Anis, Konstantinos Kakosimos, Rajesh Shende, Marc A. Rosen
Format: Article
Language:English
Published: MDPI AG 2016-04-01
Series:Energies
Subjects:
solar thermochemical
thermodynamics
hydrogen
water splitting
samarium oxide
computational analysis
Online Access:http://www.mdpi.com/1996-1073/9/5/316
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spelling doaj-c6c579ff51104c6eb2042caf15565b462020-11-24T20:46:04ZengMDPI AGEnergies1996-10732016-04-019531610.3390/en9050316en9050316Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting CycleRahul Bhosale0Anand Kumar1Fares AlMomani2Ujjal Ghosh3Mohammad Saad Anis4Konstantinos Kakosimos5Rajesh Shende6Marc A. Rosen7Department of Chemical Engineering, College of Engineering, Qatar University, P. O. Box 2713, Doha 2713, QatarDepartment of Chemical Engineering, College of Engineering, Qatar University, P. O. Box 2713, Doha 2713, QatarDepartment of Chemical Engineering, College of Engineering, Qatar University, P. O. Box 2713, Doha 2713, QatarDepartment of Chemical Engineering, College of Engineering, Qatar University, P. O. Box 2713, Doha 2713, QatarDepartment of Chemical Engineering, College of Engineering, Qatar University, P. O. Box 2713, Doha 2713, QatarDepartment of Chemical Engineering, Texas A&M University at Qatar, PO Box 23874, Doha 2713, QatarDepartment of Chemical and Biological Engineering, South Dakota School of Mines and Technology, Rapid City, SD 57701-3995, USAFaculty of Engineering and Applied Science, University of Ontario Institute of Technology, 2000 Simcoe St. North, Oshawa, ON L1H 7K4, CanadaThe computational thermodynamic analysis of a samarium oxide-based two-step solar thermochemical water splitting cycle is reported. The analysis is performed using HSC chemistry software and databases. The first (solar-based) step drives the thermal reduction of Sm2O3 into Sm and O2. The second (non-solar) step corresponds to the production of H2 via a water splitting reaction and the oxidation of Sm to Sm2O3. The equilibrium thermodynamic compositions related to the thermal reduction and water splitting steps are determined. The effect of oxygen partial pressure in the inert flushing gas on the thermal reduction temperature (TH) is examined. An analysis based on the second law of thermodynamics is performed to determine the cycle efficiency (ηcycle) and solar-to-fuel energy conversion efficiency (ηsolar−to−fuel) attainable with and without heat recuperation. The results indicate that ηcycle and ηsolar−to−fuel both increase with decreasing TH, due to the reduction in oxygen partial pressure in the inert flushing gas. Furthermore, the recuperation of heat for the operation of the cycle significantly improves the solar reactor efficiency. For instance, in the case where TH = 2280 K, ηcycle = 24.4% and ηsolar−to−fuel = 29.5% (without heat recuperation), while ηcycle = 31.3% and ηsolar−to−fuel = 37.8% (with 40% heat recuperation).http://www.mdpi.com/1996-1073/9/5/316solar thermochemicalthermodynamicshydrogenwater splittingsamarium oxidecomputational analysis
collection DOAJ
language English
format Article
sources DOAJ
author Rahul Bhosale
Anand Kumar
Fares AlMomani
Ujjal Ghosh
Mohammad Saad Anis
Konstantinos Kakosimos
Rajesh Shende
Marc A. Rosen
spellingShingle Rahul Bhosale
Anand Kumar
Fares AlMomani
Ujjal Ghosh
Mohammad Saad Anis
Konstantinos Kakosimos
Rajesh Shende
Marc A. Rosen
Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle
Energies
solar thermochemical
thermodynamics
hydrogen
water splitting
samarium oxide
computational analysis
author_facet Rahul Bhosale
Anand Kumar
Fares AlMomani
Ujjal Ghosh
Mohammad Saad Anis
Konstantinos Kakosimos
Rajesh Shende
Marc A. Rosen
author_sort Rahul Bhosale
title Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle
title_short Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle
title_full Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle
title_fullStr Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle
title_full_unstemmed Solar Hydrogen Production via a Samarium Oxide-Based Thermochemical Water Splitting Cycle
title_sort solar hydrogen production via a samarium oxide-based thermochemical water splitting cycle
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2016-04-01
description The computational thermodynamic analysis of a samarium oxide-based two-step solar thermochemical water splitting cycle is reported. The analysis is performed using HSC chemistry software and databases. The first (solar-based) step drives the thermal reduction of Sm2O3 into Sm and O2. The second (non-solar) step corresponds to the production of H2 via a water splitting reaction and the oxidation of Sm to Sm2O3. The equilibrium thermodynamic compositions related to the thermal reduction and water splitting steps are determined. The effect of oxygen partial pressure in the inert flushing gas on the thermal reduction temperature (TH) is examined. An analysis based on the second law of thermodynamics is performed to determine the cycle efficiency (ηcycle) and solar-to-fuel energy conversion efficiency (ηsolar−to−fuel) attainable with and without heat recuperation. The results indicate that ηcycle and ηsolar−to−fuel both increase with decreasing TH, due to the reduction in oxygen partial pressure in the inert flushing gas. Furthermore, the recuperation of heat for the operation of the cycle significantly improves the solar reactor efficiency. For instance, in the case where TH = 2280 K, ηcycle = 24.4% and ηsolar−to−fuel = 29.5% (without heat recuperation), while ηcycle = 31.3% and ηsolar−to−fuel = 37.8% (with 40% heat recuperation).
topic solar thermochemical
thermodynamics
hydrogen
water splitting
samarium oxide
computational analysis
url http://www.mdpi.com/1996-1073/9/5/316
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AT ujjalghosh solarhydrogenproductionviaasamariumoxidebasedthermochemicalwatersplittingcycle
AT mohammadsaadanis solarhydrogenproductionviaasamariumoxidebasedthermochemicalwatersplittingcycle
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