Hydride formation rates of titanium-based b.c.c. solid solution alloys

Maeland, A. J.; Libowitz, G. G.; Lynch, John P.

doi:10.1016/0022-5088(84)90420-x

Cited by 77 publications

(32 citation statements)

References 4 publications

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“…Of the various materials under consideration, some of bcc solid solution alloys look more promising than others. Since the pioneering work of Libowitz et al [1][2][3], many researchers have studied and improved the bcc solid solution alloys for hydrogen storage [4][5][6][7][8][9]. They show excellent volumetric hydrogen storage density and high reactivity with hydrogen at reasonably low temperature.…”

Section: Introductionmentioning

confidence: 99%

Effects of desorption temperature and substitution of Fe for Cr on the hydrogen storage properties of Ti0.32Cr0.43V0.25Ti0.32Cr0.43V0.25 alloy

Yoo

Shim

Cho

et al. 2007

International Journal of Hydrogen Energy

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Section: Introductionmentioning

confidence: 99%

Effects of desorption temperature and substitution of Fe for Cr on the hydrogen storage properties of Ti0.32Cr0.43V0.25Ti0.32Cr0.43V0.25 alloy

Yoo

Shim

Cho

et al. 2007

International Journal of Hydrogen Energy

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“…Many amorphous or nano-crystalline Mg-based alloys were hereby obtained to improve their gaseous or electrochemical hydrogen storage properties. Meanwhile, previous studies including those of our group showed experimentally that the BCC structure has more room for hydrogen accommodation in the lattice [5][6][7][8][9][10], because the BCC structure possesses lower density than the conventional intermetallic hydrogen absorbing alloys that have usually closer packed structures. Ti-Cr-V "Laves phase related BCC solid solution" alloy absorbed and desorbed hydrogen at room temperature [9,10] and the hydrogen capacity reached at around 3 mass%.…”

Section: Introductionmentioning

confidence: 94%

The study on binary Mg–Co hydrogen storage alloys with BCC phase

Zhang

Tsushio

Enoki

et al. 2005

Journal of Alloys and Compounds

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“…Before the Laves phase related BCC solid solution was proposed, only a few reports on hydrogen absorbing properties of BCC alloys could be found in the literature [6][7][8]. However, the hydrogen capacity of the BCC metals and alloys was recognized to be large in the hydrogen-metal ratio.…”

Section: Introductionmentioning

confidence: 98%

Hydrogenation properties and crystal structures of Ti−Mn-V BCC solid solution alloys

Akiba

Nakamura

2001

Met. Mater. Int.

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We have proposed new hydrogen absorbing alloys of the 'Laves phase related BCC solid solution alloy', the hydrogen capacity of which reaches almost double that of conventional rare-earth based AB 5 alloys. We have reported the hydrogen absorbing properties of Ti-V-Mn, Ti-V-Cr and T-V-Mn-Cr alloys. It has been accepted that the crystal structural change of BCC hydrogen absorbing alloys is the same as that of V metal. The mono-hydride (H/M=1) of V metal has a BCT structure and the di-hydride (H/M=2) has an FCC structure. However, we recently found that the Ti-V-Mn alloy shows different behaviors in phase transformation with hydrogenation to V metal. We found three hydride phases with a BCC, a deformed FCC and an FCC structure in the Ti-V-Mn solid solution alloy-H 2 system. The deformed FCC hydride phase has not yet to our knowledge been reported. The lattice constant of the deformed FCC was 0.407 nm, one axis of which is reduced by about 4%. Its single-phase region appeared at a hydrogen content between 0.8 H/M and 1.0 H/M in absorption at 298 K. The lower plateau observed due to formation of the deformed FCC hydride phase gives an increase of effective hydrogen capacity by decreasing hydrogen remaining in the alloy in the desorption process.

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Hydride formation rates of titanium-based b.c.c. solid solution alloys

Cited by 77 publications

References 4 publications

Effects of desorption temperature and substitution of Fe for Cr on the hydrogen storage properties of Ti0.32Cr0.43V0.25Ti0.32Cr0.43V0.25 alloy

Effects of desorption temperature and substitution of Fe for Cr on the hydrogen storage properties of Ti0.32Cr0.43V0.25Ti0.32Cr0.43V0.25 alloy

The study on binary Mg–Co hydrogen storage alloys with BCC phase

Hydrogenation properties and crystal structures of Ti−Mn-V BCC solid solution alloys

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