Qualitative and quantitative analysis of solar hydrogen generation literature from 2001 to 2014
Maghami, Mohammadreza and Navabi asl, Shahin and Rezadad, Mohamad ismail and Ale ebrahim, Nader and Gomes, Chandima
(2015):
Qualitative and quantitative analysis of solar hydrogen generation literature from 2001 to 2014.
Published in: Scientometrics
No. First online: 09 September 2015
(9. September 2015): pp. 1-13.
MPRA_paper_67182.pdf Download (795kB) | Preview |
Abstract
Solarhydrogen generation is one of the new topics in the field of renewable
energy. Recently, the rate of investigation about hydrogen generation is
growing dramatically in many countries. Many studies have been done
about hydrogen generation from natural resources such as wind, solar,
coal etc. In this work we evaluated global scientific production of
solar hydrogen generation papers from 2001 to 2014 in any journal of all
the subject categories of the Science Citation Index compiled by
Institute for Scientific Information (ISI), Philadelphia, USA. Solar
hydrogen generation was used as keywords to search the parts of titles,
abstracts, or keywords. The published output analysis showed that
hydrogen generation from the sun research steadily increased over the
past 14 years and the annual paper production in 2013 was about three
times 2010-paper production. The number of papers considered in this
research is 141 which have been published from 2001 to this date. There
are clear distinctions among author keywords used in publications from
the five most high-publishing countries such as USA, China, Australia,
Germany and India in solar hydrogen studies. In order to evaluate this
work quantitative and qualitative analysis methods were used to the
development of global scientific production in a specific research
field. The analytical results eventually provide several key findings
and consider the overview hydrogen production according to the solar
hydrogen generation.
Item Type: | MPRA Paper |
---|---|
Original Title: | Qualitative and quantitative analysis of solar hydrogen generation literature from 2001 to 2014 |
English Title: | Qualitative and quantitative analysis of solar hydrogen generation literature from 2001 to 2014 |
Language: | English |
Keywords: | Solar hydrogen generation, hydrogen generation, water splitting, hydrogen literature, Bibliometrics |
Subjects: | L - Industrial Organization > L0 - General L - Industrial Organization > L0 - General > L00 - General R - Urban, Rural, Regional, Real Estate, and Transportation Economics > R0 - General Z - Other Special Topics > Z0 - General > Z00 - General |
Item ID: | 67182 |
Depositing User: | Nader Ale Ebrahim |
Date Deposited: | 13. Oct 2015 16:49 |
Last Modified: | 13. Oct 2015 16:54 |
References: | Agrafiotis, C., Roeb, M., Konstandopoulos, A., Nalbandian, L., Zaspalis, V., Sattler, C., et al. (2005). Solar water splitting for hydrogen production with monolithic reactors. Solar Energy, 79(4), 409-421. Andrews, J., & Shabani, B. Dimensionless analysis of the global techno-economic feasibility of solar-hydrogen systems for constant year-round power supply. International journal of hydrogen energy, 37(1), 6-18. Bak, T., Nowotny, J., Rekas, M., & Sorrell, C. (2002). Photo-electrochemical hydrogen generation from water using solar energy. Materials-related aspects. International journal of hydrogen energy, 27(10), 991-1022. Barbir, F. PEM fuel cells: theory and practice: Academic Press. Barbir, F. (2005). PEM electrolysis for production of hydrogen from renewable energy sources. Solar Energy, 78(5), 661-669. Dicks, A. L. (1996). Hydrogen generation from natural gas for the fuel cell systems of tomorrow. Journal of power sources, 61(1), 113-124. Dincer, F. The analysis on photovoltaic electricity generation status, potential and policies of the leading countries in solar energy. Renewable and Sustainable Energy Reviews, 15(1), 713-720. Dou, X. X., & Andrews, J. Design of a dynamic control system for standalone solar-hydrogen power generation. Procedia Engineering, 49, 107-115. Duigou, A. L., Borgard, J.-M., Larousse, B., Doizi, D., Allen, R., Ewan, B. C., et al. (2007). HYTHEC: an EC funded search for a long term massive hydrogen production route using solar and nuclear technologies. International journal of hydrogen energy, 32(10), 1516-1529. El-Bassuoni, A., Sheffield, J. W., & Veziroglu, T. (1982). Hydrogen and fresh water production from sea water. International journal of hydrogen energy, 7(12), 919-923. Eriksson, S., Wolf, M., Schneider, A., Mantzaras, J., Raimondi, F., Boutonnet, M., et al. (2006). Fuel-rich catalytic combustion of methane in zero emissions power generation processes. Catalysis today, 117(4), 447-453. Fakioğlu, E., Yürüm, Y., & Nejat Veziroğlu, T. (2004). A review of hydrogen storage systems based on boron and its compounds. International journal of hydrogen energy, 29(13), 1371-1376. Ghosh, P., Emonts, B., Janßen, H., Mergel, J., & Stolten, D. (2003). Ten years of operational experience with a hydrogen-based renewable energy supply system. Solar Energy, 75(6), 469-478. Gorensek, M. B., & Forsberg, C. W. (2009). Relative economic incentives for hydrogen from nuclear, renewable, and fossil energy sources. International journal of hydrogen energy, 34(9), 4237-4242. Graf, D., Monnerie, N., Roeb, M., Schmitz, M., & Sattler, C. (2008). Economic comparison of solar hydrogen generation by means of thermochemical cycles and electrolysis. International journal of hydrogen energy, 33(17), 4511-4519. Kotler, P. Reinventing marketing to manage the environmental imperative. Journal of Marketing, 75(4), 132-135. Larminie, J., Dicks, A., & McDonald, M. S. (2003). Fuel cell systems explained (Vol. 2): Wiley New York. Licht, S. (2002). Efficient solar generation of hydrogen fuel–a fundamental analysis. Electrochemistry Communications, 4(10), 790-795. Licht, S. (2005). Thermochemical solar hydrogen generation. Chemical communications(37), 4635-4646. Licht, S. (2009). STEP (solar thermal electrochemical photo) generation of energetic molecules: A solar chemical process to end anthropogenic global warming. The Journal of Physical Chemistry C, 113(36), 16283-16292. Linkous, C. A., & Muradov, N. Z. (2001). Closed cycle photocatalytic process for decomposition of hydrogen sulfide to its constituent elements: Google Patents. Momirlan, M., & Veziroglu, T. (2002). Current status of hydrogen energy. Renewable and Sustainable Energy Reviews, 6(1), 141-179. Momirlan, M., & Veziroglu, T. N. (2005). The properties of hydrogen as fuel tomorrow in sustainable energy system for a cleaner planet. International journal of hydrogen energy, 30(7), 795-802. Nadal, M., & Barbir, F. (1996). Development of a hybrid fuel cell/battery powered electric vehicle. International journal of hydrogen energy, 21(6), 497-505. Noglik, A., Hinkley, J., Sattler, C., Pitz-Paal, R., Roeb, M., & Rzepczyk, T. (2009). Solar thermochemical generation of hydrogen: development of a receiver reactor for the decomposition of sulfuric acid. Journal of Solar Energy Engineering, 131(1), 011003. Noglik, A., Roeb, M., Sattler, C., & Pitz-Paal, R. Numerical Optimization of a Volumetric Solar Receiver-Reactor for Thermochemical Hydrogen Generation via Decomposition of Sulfur Trioxide. Paper presented at the ASME 2010 4th International Conference on Energy Sustainability. Noglik, A., Roeb, M., Sattler, C., & Pitz�Paal, R. Modeling of a solar receiver–reactor for sulfur�based thermochemical cycles for hydrogen generation. International Journal of Energy Research, 35(5), 449-458. Paul, B., & Andrews, J. (2008). Optimal coupling of PV arrays to PEM electrolysers in solar–hydrogen systems for remote area power supply. International journal of hydrogen energy, 33(2), 490-498. Pregger, T., Graf, D., Krewitt, W., Sattler, C., Roeb, M., & Möller, S. (2009). Prospects of solar thermal hydrogen production processes. International journal of hydrogen energy, 34(10), 4256-4267. Priya, R., & Kanmani, S. Design of pilot-scale solar photocatalytic reactor for the generation of hydrogen from alkaline sulfide wastewater of sewage treatment plant. Environmental Technology, 34(20), 2817-2823. Priya, R., & Kanmani, S. Solar photocatalytic generation of hydrogen under ultraviolet-visible light irradiation on (CdS/ZnS)/Ag2S+(RuO2/TiO2) photocatalysts. Bulletin of Materials Science, 33(1), 85-88. Priya, R., & Kanmani, S. (2008). Solar photocatalytic generation of hydrogen from hydrogen sulphide using CdS-based photocatalysts. Current Science (00113891), 94(1). Priya, R., & Kanmani, S. (2009). Batch slurry photocatalytic reactors for the generation of hydrogen from sulfide and sulfite waste streams under solar irradiation. Solar Energy, 83(10), 1802-1805. Roeb, M., Konstandopoulos, A. G., Steele, A., Stobbe, P., Agrafiotis, C., Sattler, C., et al. (2006). Solar hydrogen production by a two-step cycle based on mixed iron oxides. Journal of Solar Energy Engineering, 128(2), 125-133. Roeb, M., & Müller-Steinhagen, H. Concentrating on solar electricity and fuels. Science, 329(5993), 773-774. Satyapal, S., Petrovic, J., Read, C., Thomas, G., & Ordaz, G. (2007). The US Department of Energy's National Hydrogen Storage Project: Progress towards meeting hydrogen-powered vehicle requirements. Catalysis today, 120(3), 246-256. Shabani, B., & Andrews, J. An experimental investigation of a PEM fuel cell to supply both heat and power in a solar-hydrogen RAPS system. International journal of hydrogen energy, 36(9), 5442-5452. Shabani, B., Andrews, J., & Watkins, S. Energy and cost analysis of a solar-hydrogen combined heat and power system for remote power supply using a computer simulation. Solar Energy, 84(1), 144-155. Sherif, S. A., Barbir, F., & Veziroglu, T. (2005). Wind energy and the hydrogen economy—review of the technology. Solar Energy, 78(5), 647-660. Sopian, K., Yigit, K., Liu, H., Kakac, S., & Veziroglu, T. (1996). Performance analysis of photovoltaic thermal air heaters. Energy Conversion and Management, 37(11), 1657-1670. van de Krol, R., Liang, Y., & Schoonman, J. (2008). Solar hydrogen production with nanostructured metal oxides. Journal of Materials Chemistry, 18(20), 2311-2320. Veziroğlu, T. N. (2008). 21st Century’s energy: Hydrogen energy system. Energy Conversion and Management, 49(7), 1820-1831. Wang, G., & Li, Y. Nickel Catalyst Boosts Solar Hydrogen Generation of CdSe Nanocrystals. ChemCatChem, 5(6), 1294-1295. Wang, H., Qian, F., Wang, G., Jiao, Y., He, Z., & Li, Y. Self-Biased Solar-Microbial Device for Sustainable Hydrogen Generation. ACS nano, 7(10), 8728-8735. Winter, C.-J. (1987). Hydrogen energy—expected engineering breakthroughs. International journal of hydrogen energy, 12(8), 521-546. Xiong, L., Kannan, A., & Manthiram, A. (2002). Pt–M (M= Fe, Co, Ni and Cu) electrocatalysts synthesized by an aqueous route for proton exchange membrane fuel cells. Electrochemistry Communications, 4(11), 898-903. Z’Graggen, A., Haueter, P., Maag, G., Vidal, A., Romero, M., & Steinfeld, A. (2007). Hydrogen production by steam-gasification of petroleum coke using concentrated solar power—III. Reactor experimentation with slurry feeding. International journal of hydrogen energy, 32(8), 992-996. Zhang, Y.-H. P., Evans, B. R., Mielenz, J. R., Hopkins, R. C., & Adams, M. W. (2007). High-yield hydrogen production from starch and water by a synthetic enzymatic pathway. PloS one, 2(5), e456. |
URI: | https://mpra.ub.uni-muenchen.de/id/eprint/67182 |
Qualitative and quantitative analysis of solar hydrogen generation literature from 2001 to 2014 - Munich Personal RePEc Archive
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