Environmental Engineering Reference
In-Depth Information
Licht, S. (2002) Efficient solar generation of hydrogen fuel - a fundamental analysis.
Electro-
chemistry Communications
, 4, 790-795.
Licht, S. Ed. (2002)
Semiconductor Electrodes and Photoelectrochemistry
. Weinheim: Wiley-
VCH.
Licht, S. (2003) Solar water splitting to generate hydrogen fuel: photothermal electrochemical
analysis.
Journal of Physical Chemistry B
, 107, 4253-4260.
Licht, S., Halperin, L., Kalina, M., Zidman, M. and Halperin, N. (2003) Electrochemical
potential tuned solar water splitting.
Chemical Communication
, 2003, 3006-3007.
Licht, S. (2005) Thermochemical solar hydrogen generation.
Chemical Communication
, 2005,
4635-4646
Light, T.S., Licht, S., Bevilacqua, A.C. and Morash, K.R. (2005) The fundamental conductivity
and resistivity of water.
Electrochemal and Solid-State Letters
8, E16-E19.
Licht, S. (2009) STEP (solar thermal electrochemical photo) generation of energetic molecules: A
solar chemical process to end anthropogenic global warming.
Journal of Physical Chemistry
C
, 113, 16283-16292.
Licht, S. and Wang, B. (2010) High solubility pathway to the carbon dioxide free production of
iron.
Chemical Communications
, 46, 7004-7006.
Licht, S., Wang B., Ghosh, S., Ayub, H., Jiang, D. and Ganley, J. (2010a) A new solar car-
bon capture process: solar thermal electrochemical photo (STEP) carbon capture.
Journal of
Physical Chemistry Letters
, 1, 2363-2368.
Licht, S., Chityat, O., Bergmann, H., Dick, A., Ayub, H. and Ghosh, S. (2010b) Efficient STEP
(Solar thermal electrochemical photo) production of hydrogen - an economic assessment.
International Journal of Hydrogen Energy
, 35, 10867-10882.
Licht, S. (2011) Efficient solar-driven synthesis, carbon capture, and desalinization, STEP:
solar thermal electrochemical production of fuels, metals, bleach.
Advanced Materials
, 20,
1-21.
Licht, S. and Wu, H. (2011) STEP - STEP iron, a chemistry of iron formation without CO
2
emission: Molten carbonate solubility and electrochemistry of iron ore impurities.
Journal
of Physical Chemistry C
, 115, 25138-25147.
Licht, S., Wang, B. and Wu, H. (2011a) STEP - A solar chemical process to end anthro-
pogenic global warming II: experimental results.
Journal of Physical Chemistry C
, 115,
11803-11821.
Licht, S., Wu, H., Zhang, Z. and Ayub, H. (2011b) Chemical mechanism of the high solubility
pathway for the carbon dioxide free production of iron.
Chemical Communications
, 47,
3081-3083.
Licht, S., Wu, H., Hettige, C., Wang, B., Lau, J., Asercion, J., Stuart, J. (2012) STEP
Cement: Solar Thermal Electrochemical Production of CaO without CO2 emission.
Chemical
Communications
48, 6019-6021, with online 20 page supplement.
Licht, S. Cui, B., Wang, B. (2013) STEP Carbon Capture: the barium advantage
Journal of CO
2
Utilization
2, 58-63, with 12 page online supplementary information.
Lueck, D., Buttner, W. and Surma, J. (2002) Space habitat carbon dioxide electrolysis to
oxygen.
Fluid System Technologies,
at: http://rtreport.ksc.nasa.gov/techreports/2002report/
600%20Fluid%20Systems/609.html.
Luque, A. and Marti, A. (2003)
Handbook of Photovoltaic Sci. & E
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S. Haegedus, S. Weinheim:Wiley-VCH, 113.
Lykasov, A. and Pavlovskaya, M. (2003) Phase equilibria in the Fe-Na-O system between 1100
and 1300 K.
Inorganic Materials
, 39, 1088-1091.
Martin, N. (1965) Carbon dioxide reduction systems.
AIAA Fourth Manned Space Flight
Meeting
, October 11-13, 1965, St. Louis, Missouri, USA.
Miller, J., Allendorf, M., Diver, R., Evans, L.R., Siegel, N.P. and Stuecker. J.N. (2008) Metal
oxide composites and structures for ultra-high temperature solar thermochemical cycles.
Journal of Materials Science
, 43, 4714-4728.
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