Formation Process of [B<SUB>12</SUB>H<SUB>12</SUB>]<SUP>2&minus;</SUP> from [BH<SUB>4</SUB>]<SUP>&minus;</SUP> during the Dehydrogenation Reaction of Mg(BH<SUB>4</SUB>)<SUB>2</SUB>

“…When the temperature is increased to 475 °C, no obvious changes of diffraction peaks, Raman spectra and the major resonance at −15.4 ppm attributed to K2B12H12 are seen. The resonance originated from residual KBH4 (−38.2 ppm in solid-state and −35.6 ppm in solution-state 11 B NMR) disappears when the temperature is increased to 550 °C, whereas no obvious changes of diffraction peaks, Raman spectra and the major resonance attributed to K2B12H12 are observed. This suggests that the weight loss bellow 550 °C is responsible for the dehydrogenation of residual KBH4.…”

“…increased to 700 °C, the dehydrogenation amount reaches 5.1 mass%, the major resonance of Li2B12H12 at −15.3 ppm in 11 B MAS NMR shifts to −11.9 ppm, and that at 1.4 ppm in 1 H MAS NMR changes to several weak resonance peaks from −10 ppm to 10 ppm. This suggests that Li2B12H12−x continuously releases hydrogen accompanied by the polymerization of the icosahedral B12 skeletons and the formation of (Li2B12Hz)n polymers [15,21,29], insoluble in water and DMSO.…”

“…The decomposition behavior of anhydrous K2B12H12 is different from that formed as a dehydrogenation intermediate of KBH4 predicted by theoretical calculation [34], suggesting that the coexisting KH may facilitate the decomposition of K2B12H12. When the temperature is increased to 700 °C, the diffraction peaks and Raman spectra from K2B12H12 are hardly observed, the main resonance at −15.4 ppm in 11 B MAS NMR decreases significantly without any change in the chemical shift and a broad resonance between −12.2 ppm and −14.2 ppm appears. It suggests that the major dehydrogenation of K2B12H12 to K2B12H12−x and the polymerization of K2B12H12−x to (K2B12Hz)n polymers start to happen at 700 °C [21], similar to those of Na2B12H12.…”

“…Metal dodecaborates M 2/n B 12 H 12 (n is the valence of M) have been widely regarded as a dehydrogenation intermediate of metal borohydrides M(BH 4 ) n with a high gravimetric hydrogen density of 10 mass% [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16]. The formation of M 2/n B 12 H 12 , despite is still controversial, largely depends on the dehydrogenation temperature, hydrogen backpressure, particle size and sample pretreatment [11][12][13][14][15][16][17][18][19][20][21].…”

“…The formation of M 2/n B 12 H 12 , despite is still controversial, largely depends on the dehydrogenation temperature, hydrogen backpressure, particle size and sample pretreatment [11][12][13][14][15][16][17][18][19][20][21]. Due to the strong B-B bonds in an icosahedral boron cage B 12 , the intermediate comprising of polyatomic anion [B 12 H 12 ] 2´h as been widely regarded at the main obstacle for the rehydrogenation of M(BH 4 ) n [5,[22][23][24].…”

Thermal Decomposition of Anhydrous Alkali Metal Dodecaborates M2B12H12 (M = Li, Na, K)

“…When the temperature is increased to 475 °C, no obvious changes of diffraction peaks, Raman spectra and the major resonance at −15.4 ppm attributed to K2B12H12 are seen. The resonance originated from residual KBH4 (−38.2 ppm in solid-state and −35.6 ppm in solution-state 11 B NMR) disappears when the temperature is increased to 550 °C, whereas no obvious changes of diffraction peaks, Raman spectra and the major resonance attributed to K2B12H12 are observed. This suggests that the weight loss bellow 550 °C is responsible for the dehydrogenation of residual KBH4.…”

“…increased to 700 °C, the dehydrogenation amount reaches 5.1 mass%, the major resonance of Li2B12H12 at −15.3 ppm in 11 B MAS NMR shifts to −11.9 ppm, and that at 1.4 ppm in 1 H MAS NMR changes to several weak resonance peaks from −10 ppm to 10 ppm. This suggests that Li2B12H12−x continuously releases hydrogen accompanied by the polymerization of the icosahedral B12 skeletons and the formation of (Li2B12Hz)n polymers [15,21,29], insoluble in water and DMSO.…”

“…The decomposition behavior of anhydrous K2B12H12 is different from that formed as a dehydrogenation intermediate of KBH4 predicted by theoretical calculation [34], suggesting that the coexisting KH may facilitate the decomposition of K2B12H12. When the temperature is increased to 700 °C, the diffraction peaks and Raman spectra from K2B12H12 are hardly observed, the main resonance at −15.4 ppm in 11 B MAS NMR decreases significantly without any change in the chemical shift and a broad resonance between −12.2 ppm and −14.2 ppm appears. It suggests that the major dehydrogenation of K2B12H12 to K2B12H12−x and the polymerization of K2B12H12−x to (K2B12Hz)n polymers start to happen at 700 °C [21], similar to those of Na2B12H12.…”

“…Metal dodecaborates M 2/n B 12 H 12 (n is the valence of M) have been widely regarded as a dehydrogenation intermediate of metal borohydrides M(BH 4 ) n with a high gravimetric hydrogen density of 10 mass% [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16]. The formation of M 2/n B 12 H 12 , despite is still controversial, largely depends on the dehydrogenation temperature, hydrogen backpressure, particle size and sample pretreatment [11][12][13][14][15][16][17][18][19][20][21].…”

“…The formation of M 2/n B 12 H 12 , despite is still controversial, largely depends on the dehydrogenation temperature, hydrogen backpressure, particle size and sample pretreatment [11][12][13][14][15][16][17][18][19][20][21]. Due to the strong B-B bonds in an icosahedral boron cage B 12 , the intermediate comprising of polyatomic anion [B 12 H 12 ] 2´h as been widely regarded at the main obstacle for the rehydrogenation of M(BH 4 ) n [5,[22][23][24].…”

Thermal Decomposition of Anhydrous Alkali Metal Dodecaborates M2B12H12 (M = Li, Na, K)

Inducing One‐Step Dehydrogenation of Magnesium Borohydride via Confinement in Robust Dodecahedral Nitrogen‐Doped Porous Carbon Scaffold

Solid Hydrogen Storage Materials: Non-interstitial Hydrides