Abstract
The microstructures of two metal hydride (MH) alloys, a Zr7Ni10 based Ti15Zr26Ni59 and a C14 Laves phase based Ti12Zr21.5V10Ni36.2Cr4.5Mn13.6Sn0.3Co2.0Al0.4, were studied using the electron backscatter diffraction (EBSD) technique. The first alloy was found to be composed of completely aligned Zr7Ni10 grains with a ZrO2 secondary phase randomly scattered throughout and a C15 secondary phase precipitated along the grain boundary. Two sets of orientation alignments were found between the Zr7Ni10 grains and the C15 phase: (001)Zr7Ni10A//(110)C15 and [100]Zr7Ni10A//[0 1 ¯ 1]C15, and (01 1 ¯ )Zr7Ni10B//( 1 ¯ 00)C15 and [100]Zr7Ni10B//[313]C15. The grain growth direction is close to [313]Zr7Ni10B//[ 1 ¯ 11]C15. The second alloy is predominated by a C14 phase, as observed from X-ray diffraction analysis. Both the matrix and dendrite seen through a scanning electron microscope arise from the same C14 structure with a similar chemical composition, but different orientations, as the matrix with the secondary phases in the form of intervening Zr7Ni10/Zr9Ni11/(Zr,Ni)Ti needle-like phase coated with a thin layer of C15 phase. The crystallographic orientation of the C15 phase is in alignment with the neighboring C14 phase, with the following relationships: (111)C15//(0001)C14 and [1 1 ¯ 0]C15//[11 2 ¯ 0]C14. The alignments in crystallographic orientations among the phases in these two multi-phase MH alloys confirm the cleanliness of the interface (free of amorphous region), which is necessary for the hydrogen-storage synergetic effects in both gaseous phase reaction and electrochemistry.
Highlights
IntroductionNickel/metal hydride (Ni/MH) batteries have been the choice of energy storage medium for powering hybrid electric vehicles (HEVs) over the past fifteen years due to their unmatched safety record and durable cycle life
The alignments in crystallographic orientations among the phases in these two multi-phase metal hydride (MH) alloys confirm the cleanliness of the interface, which is necessary for the hydrogen-storage synergetic effects in both gaseous phase reaction and electrochemistry
Nickel/metal hydride (Ni/MH) batteries have been the choice of energy storage medium for powering hybrid electric vehicles (HEVs) over the past fifteen years due to their unmatched safety record and durable cycle life
Summary
Nickel/metal hydride (Ni/MH) batteries have been the choice of energy storage medium for powering hybrid electric vehicles (HEVs) over the past fifteen years due to their unmatched safety record and durable cycle life. Laves phase based metal hydride (MH) AB2 alloys have a great potential in gravimetric specific energy, compared to currently used. A Mn-rich AB2 MH alloy (Ti0.9 Zr0.1 Mn1.6 Ni0.4 ) with the electrochemical capacity of 438 mAhg ́1 after 150 formation cycles has been reported [6] Another Ni-rich AB2 MH alloy, Ti0.62 Zr0.38 V0.41 Cr0.30 Mn0.36 Ni0.89 , exhibited a discharge capacity of 424 mAhg ́1 after activation in a 30% KOH bath at 110 ̋ C for 4.5 h [7]. These capacity values are 40% higher than the 320 mAhg ́1 found in commercially available AB5 alloys.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
