Search Results - "Felderhoff, M"

Mg-based compounds for hydrogen and energy storage by Crivello, J.-C., Denys, R. V., Dornheim, M., Felderhoff, M., Grant, D. M., Huot, J., Jensen, T. R., de Jongh, P., Latroche, M., Walker, G. S., Webb, C. J., Yartys, V. A.

“…Magnesium-based alloys attract significant interest as cost-efficient hydrogen storage materials allowing the combination of high gravimetric storage capacity…”
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Hydrogen storage properties of nanostructured MgH2/TiH2 composite prepared by ball milling under high hydrogen pressure by SHAO, H, FELDERHOFF, M, SCHÜTH, F

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Demonstration of Mg2FeH6 as heat storage material at temperatures up to 550 °C by Urbanczyk, R., Meggouh, M., Moury, R., Peinecke, K., Peil, S., Felderhoff, M.

“…The storage of heat at high temperatures, which can be used to generate electricity after sunset in concentrating solar power plants, is one of the most…”
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Metal hydrides for concentrating solar thermal power energy storage by Sheppard, D. A., Paskevicius, M., Humphries, T. D., Felderhoff, M., Capurso, G., Bellosta von Colbe, J., Dornheim, M., Klassen, T., Ward, P. A., Teprovich, J. A., Corgnale, C., Zidan, R., Grant, D. M., Buckley, C. E.

“…The development of alternative methods for thermal energy storage is important for improving the efficiency and decreasing the cost of concentrating solar…”
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Aluminium alloy based hydrogen storage tank operated with sodium aluminium hexahydride Na3AlH6 by Urbanczyk, R., Peinecke, K., Felderhoff, M., Hauschild, K., Kersten, W., Peil, S., Bathen, D.

“…Here we present the development of an aluminium alloy based hydrogen storage tank, charged with Ti-doped sodium aluminium hexahydride Na3AlH6. This hydride has…”
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Complex aluminum hydrides by Bogdanović, B., Eberle, U., Felderhoff, M., Schüth, F.

“…NaAlH 4 is amongst the most advanced and intensely investigated hydrogen storage materials today. It reaches a storage capacity of more than 5 wt.% at around…”
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Development of a heat storage demonstration unit on the basis of Mg 2 FeH 6 as heat storage material and molten salt as heat transfer media by Urbanczyk, R., Peinecke, K., Peil, S., Felderhoff, M.

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Advanced Hydrogen‐Storage Materials Based on Sc‐, Ce‐, and Pr‐Doped NaAlH4 by Bogdanović, B., Felderhoff, M., Pommerin, A., Schüth, F., Spielkamp, N.

“…The most favorable dopants for solid‐state hydrogen‐storage materials are still considered to be compounds of titanium in spite of intensive research on other…”
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Metal hydrides for concentrating solar thermal power energy storage by Sheppard, D. A., Paskevicius, M., Humphries, T. D., Felderhoff, M., Capurso, G., Bellosta von Colbe, J., Dornheim, M., Klassen, T., Ward, P. A., Teprovich, J. A., Corgnale, C., Zidan, R., Grant, D. M., Buckley, C. E.

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Improved Hydrogen Storage Properties of Ti-Doped Sodium Alanate Using Titanium Nanoparticles as Doping Agents by Bogdanović, B., Felderhoff, M., Kaskel, S., Pommerin, A., Schlichte, K., Schüth, F.

“…By using nanosized doping agents, the properties of Ti‐catalyzed NaAlH4 storage systems are considerably improved. Hydrogenation–dehydrogenation cyclic testing…”
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Mechanochemical preparation and investigation of properties of magnesium, calcium and lithium–magnesium alanates by Mamatha, M., Bogdanović, B., Felderhoff, M., Pommerin, A., Schmidt, W., Schüth, F., Weidenthaler, C.

“…Ball milling of MgCl 2 and CaCl 2 with NaAlH 4 or LiAlH 4 can be used for the preparation of magnesium, calcium and lithium–magnesium alanates in mixture with…”
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Comparative studies of the decomposition of alanates followed by in situ XRD and DSC methods by Mamatha, M., Weidenthaler, C., Pommerin, A., Felderhoff, M., Schüth, F.

“…The decomposition of various alkali and alkaline earth complex alanates and the formation of intermediate compounds was studied by in situ X-ray…”
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Investigation of hydrogen discharging and recharging processes of Ti-doped NaAlH4 by X-ray diffraction analysis (XRD) and solid-state NMR spectroscopy by BOGDANOVIC, B, FELDERHOFF, M, GERMANN, M, HÄRTEL, M, POMMERIN, A, SCHÜTH, F, WEIDENTHALER, C, ZIBROWIUS, B

“…The processes occurring in the course of two sequential hydrogen discharging and recharging cycles of Ti-doped sodium alanate were investigated in parallel…”
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HT-PEM Fuel Cell System with Integrated Complex Metal Hydride Storage Tank by Urbanczyk, R., Peil, S., Bathen, D., Heßke, C., Burfeind, J., Hauschild, K., Felderhoff, M., Schüth, F.

“…A hydrogen storage tank based on the metal hydride sodium alanate is coupled with a high temperature PEM fuel cell (HT‐PEM). The waste heat of the fuel cell is…”
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Recording of hydrogen evolution—a way for controlling the doping process of sodium alanate by ball milling by Bellosta von Colbe, J.M., Bogdanović, B., Felderhoff, M., Pommerin, A., Schüth, F.

“…A simple equipment was developed which allows to monitor gas evolution or absorption occurring in the course of a ball milling process. The equipment has been…”
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Development of a heat storage demonstration unit on the basis of Mg2FeH6 as heat storage material and molten salt as heat transfer media by Urbanczyk, R., Peinecke, K., Peil, S., Felderhoff, M.

“…The development and preliminary tests of a 5 kg Mg2FeH6 heat storage system which is useable for short and long-term storage applications at temperatures…”
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Evidence for the existence of β-Na3AlH6 : Monitoring the phase transformation from α-Na3AlH6 by in situ methods by WEIDENTHALER, C, POMMERIN, A, FELDERHOFF, M, SCHMIDT, W, BOGDANOVIC, B, SCHÜTH, F

“…The phase transformation of alpha-Na3AlH6 to beta-Na3AlH66 was characterized by in situ DSC and high-temperature X-ray diffraction methods. The detection of…”
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Magnesium based materials for hydrogen based energy storage: Past, present and future by Yartys, V.A., Lototskyy, M.V., Akiba, E., Albert, R., Antonov, V.E., Ares, J.R., Baricco, M., Bourgeois, N., Buckley, C.E., Bellosta von Colbe, J.M., Crivello, J.-C., Cuevas, F., Denys, R.V., Dornheim, M., Felderhoff, M., Grant, D.M., Hauback, B.C., Humphries, T.D., Jacob, I., Jensen, T.R., de Jongh, P.E., Joubert, J.-M., Kuzovnikov, M.A., Latroche, M., Paskevicius, M., Pasquini, L., Popilevsky, L., Skripnyuk, V.M., Rabkin, E., Sofianos, M.V., Stuart, A., Walker, G., Wang, Hui, Webb, C.J., Zhu, Min

“…Magnesium hydride owns the largest share of publications on solid materials for hydrogen storage. The “Magnesium group” of international experts contributing…”
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Advanced Hydrogen-Storage Materials Based on Sc-, Ce-, and Pr-Doped NaAlH4 by Bogdanović, B., Felderhoff, M., Pommerin, A., Schüth, F., Spielkamp, N.

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Design and operation of an aluminium alloy tank using doped Na3AlH6 in kg scale for hydrogen storage by Urbanczyk, R., Peinecke, K., Meggouh, M., Minne, P., Peil, S., Bathen, D., Felderhoff, M.

“…In this publication the authors present an aluminium alloy tank for hydrogen storage using 1921 g of Na3AlH6 doped with 4 mol% of TiCl3 and 8 mol% of activated…”
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