Local bonding structure in mechanically activated TiH2 and TiH2+graphite mixture

“…2 shows the microstructure of TiH 2 /C and TiH 2 /B powders, milled for 66 min. Whereas milled TiH 2 forms flake-like structures some 10 nm in size [3], the samples milled with additives consist of nm-sized hydride particles embedded in an additive matrix. TiH 2 /BN has a quite similar appearance (not shown).…”

“…The TiH2 desorption was tested by temperatureprogrammed desorption (TPD) under flow conditions. Details of these experimental methods are published elsewhere [3][4][5]. Table 1 shows phase compositions of the respective samples after milling, after TPD, as well as H 2 evolution under milling, and H 2 desorption and peak temperatures recorded under TPD.…”

“…For a successful application, fast and low-temperature decomposition of metal-hydrides should be realized. High-energy ball milling is used to accelerate the process after significantly decreasing the powder size [1][2][3]. The decomposition efficiency can be improved, when compounds, which prevent particle sticking (graphite, h-BN), are added to the reactive powder before milling [3][4][5].…”

“…However, changes in local Me-H bonding structure caused by the interaction between matrix material and metal-hydride may be a key factor. The effect of graphite additive on TiH 2 thermal stability was studied in detail [3]. The aim of this work is to compare the effect of graphite, boron and h-BN additives on the thermal stability of TiH 2 .…”

Effect of N, C and B interstitial atoms on local bonding structure in mechanically activated TiH2/h-BN, TiH2/C, and TiH2/B mixtures

“…2 shows the microstructure of TiH 2 /C and TiH 2 /B powders, milled for 66 min. Whereas milled TiH 2 forms flake-like structures some 10 nm in size [3], the samples milled with additives consist of nm-sized hydride particles embedded in an additive matrix. TiH 2 /BN has a quite similar appearance (not shown).…”

“…The TiH2 desorption was tested by temperatureprogrammed desorption (TPD) under flow conditions. Details of these experimental methods are published elsewhere [3][4][5]. Table 1 shows phase compositions of the respective samples after milling, after TPD, as well as H 2 evolution under milling, and H 2 desorption and peak temperatures recorded under TPD.…”

“…For a successful application, fast and low-temperature decomposition of metal-hydrides should be realized. High-energy ball milling is used to accelerate the process after significantly decreasing the powder size [1][2][3]. The decomposition efficiency can be improved, when compounds, which prevent particle sticking (graphite, h-BN), are added to the reactive powder before milling [3][4][5].…”

“…However, changes in local Me-H bonding structure caused by the interaction between matrix material and metal-hydride may be a key factor. The effect of graphite additive on TiH 2 thermal stability was studied in detail [3]. The aim of this work is to compare the effect of graphite, boron and h-BN additives on the thermal stability of TiH 2 .…”

Effect of N, C and B interstitial atoms on local bonding structure in mechanically activated TiH2/h-BN, TiH2/C, and TiH2/B mixtures

“…at sufficiently high temperatures. The kinetics of hydrogen uptake from the gas phase depends upon the elements present at the surface, [13][14][15][16][17] and especially on the composition of the gas. [1] Gas components with a higher affinity to iron than that of hydrogen, e. g. O 2 , CO, SO 2 , H 2 O vapour, inhibit hydrogen adsorption by blocking potential adsorption sites.…”

Effect of Hydrogen on the Mechanical Properties of Stainless Steels

Effect of mechanically induced modification on TiH2 thermal stability