Biblio

Export 21 results:
[ Author(Desc)] Keyword Title Type Year
Filters: First Letter Of Last Name is K  [Clear All Filters]
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z 
K
Kaindl G., Kalkowski G., Brewer W.D, Perscheid B., Holtzberg F..  0.  M‐edge x‐ray absorption spectroscopy of 4f instabilities in rare‐earth systems (invited). Journal of Applied Physics. 55(6):1910-1915.
Kaneko H, Miura T, Ishihara H, Taku S, Yokoyama T, Nakajima H, Tamaura Y.  0.  Reactive ceramics of CeO2–MOx (M=Mn, Fe, Ni, Cu) for H2 generation by two-step water splitting using concentrated solar thermal energy. Energy. 32(5):656-663.
Kang Z, Alia SM, Young JL, Bender G.  2019.  Investigation of porous transport layer parameters for proton exchange membrane water electrolysis.
Kaur H, Wang M, Gorensek MB, Chen C-C.  0.  Thermodynamic modeling of the hybrid sulfur (HyS) cycle for hydrogen production. Fluid Phase Equilibria. 460:175-188.
Kawaguchi T, Fukuda K, Matsubara E.  0.  Site- and phase-selective x-ray absorption spectroscopy based on phase-retrieval calculation. Journal of Physics: Condensed Matter. 29(11):113002.
Keene DJ, Davidson JH, Lipiński W.  2013.  A Model of Transient Heat and Mass Transfer in a Heterogeneous Medium of Ceria Undergoing Nonstoichiometric Reduction. Journal of Heat Transfer. 135(5):052701.
Khan IS, Muzzillo CP, Perkins CL, Norman AG, Young JL, Gaillard N, Zakutayev A.  2021.  Mg $\less$sub$\greater$x$\less$/sub$\greater$ Zn$\less$sub$\greater$1-x $\less$/sub$\greater$O contact to CuGa$\less$sub$\greater$3$\less$/sub$\greater$Se$\less$sub$\greater$5$\less$/sub$\greater$ absorber for photovoltaic and photoelectrochemical devices. Journal of Physics: Energy. 3:024001.
Kiessling A, Fornaciari JC, Anderson G, Peng X, Gerstmayr A, Gerhardt MR, McKinney S, Serov A, Kim YSeung, Zulevi B et al..  2021.  Influence of Supporting Electrolyte on Hydroxide Exchange Membrane Water Electrolysis Performance: Anolyte. Journal of The Electrochemical Society. 168:084512.
Kim J, Johnson TA, Miller JE, Stechel EB, Maravelias CT.  2012.  Fuel production from CO2 using solar-thermal energy: system level analysis. Energy & Environmental Science. 5(9):8417.
Kim YSeung, Li D, Park EJoo, Wenlei Z, Qiurong S, Zhou Y, Tian H, Lin Y, Serov A, Zulevi B et al..  2020.  Highly quaternized polystyrene ionomers for high performance anion exchange membrane water electrolysers. Nature Energy. 5
Kinyanjui M.K, Axmann P., Mancini M., Gabrielli G., Balasubramanian P., Boucher F., Wohlfahrt-Mehrens M., Kaiser U..  0.  Understanding the spectroscopic signatures of Mn valence changes in the valence energy loss spectra of Li-Mn-Ni-O spinel oxides. Physical Review Materials. 1(7)
Kistler TA, Larson D, Walczak K, Agbo P, Sharp ID, Weber AZ, Danilovic N.  2019.  Integrated Membrane-Electrode-Assembly Photoelectrochemical Cell under Various Feed Conditions for Solar Water Splitting. Journal of The Electrochemical Society. 166(5):H3020-H3028.
Kistler TA, Zeng G, Young JL, Weng L-C, Aldridge C, Wyatt K, Steiner MA, Jr. OSolorzano, Houle FA, Toma FM et al..  2020.  Emergent Degradation Phenomena Demonstrated on Resilient, Flexible, and Scalable Integrated Photoelectrochemical Cells. Advanced Energy Materials. 10:2002706.
Knoblauch N, Dörrer L, Fielitz P, Schmücker M, Borchardt G.  2015.  Surface controlled reduction kinetics of nominally undoped polycrystalline CeO 2. Phys. Chem. Chem. Phys.. 17(8):5849-5860.
Kodama T., Kondoh Y., Yamamoto R., Andou H., Satou N..  0.  Thermochemical hydrogen production by a redox system of ZrO2-supported Co(II)-ferrite. Solar Energy. 78(5):623-631.
Kodama T, Gokon N.  0.  Thermochemical Cycles for High-Temperature Solar Hydrogen Production. Chemical Reviews. 107(10):4048-4077.
Kodama T., Gokon N., Yamamoto R..  0.  Thermochemical Two-Step Water Splitting by ZrO2-supported NixFe3−xO4 for Solar Hydrogen Production. Solar Energy. 82(1):73-79.
Kolb GJ, Diver RB.  2008.  Screening Analysis of Solar Thermochemical Hydrogen Concepts.
Krenzke PT, Davidson JH.  0.  On the efficiency of solar H2 and CO production via the thermochemical cerium oxide redox cycle: The option of inert-swept reduction. Energy & Fuels. :150206073859007.
Kubicek M, Bork AH, Rupp JLM.  2017.  Perovskite oxides – a review on a versatile material class for solar-to-fuel conversion processes. Journal of Materials Chemistry A. 5(24):11983-12000.
Kurata H, Colliex C.  0.  Electron-energy-loss core-edge structures in manganese oxides. Physical Review B. 48(4):2102-2108.