Department of Chemistry, Tsinghua University, Beijing 100084, China.
Inorg Chem. 2010 Sep 6;49(17):7710-20. doi: 10.1021/ic100418a.
The H(NH(2)BH(2))(n)H oligomers are possible products from dehydrogenation of ammonia borane (NH(3)BH(3)) and ammonium borohydride (NH(4)BH(4)), which belong to a class of boron-nitrogen-hydrogen (BNH(x)) compounds that are promising materials for chemical hydrogen storage. Understanding the kinetics and reaction pathways of formation of these oligomers and their further dehydrogenation is essential for developing BNH(x)-based hydrogen storage materials. We have performed computational modeling using density functional theory (DFT), ab initio wave function theory, and Car-Parrinello molecular dynamics (CPMD) simulations on the energetics and formation pathways for the H(NH(2)BH(2))(n)H (n = 1-4) oligomers, polyaminoborane (PAB), from NH(3)BH(3) monomers and the subsequent dehydrogenation steps to form polyiminoborane (PIB). Through computational transition state searches and evaluation of the intrinsic reaction coordinates, we have investigated the B-N bond cleavage, the reactions of NH(3)BH(3) molecule with intermediates, dihydrogen release through intra- and intermolecular hydrogen transfer, dehydrocoupling/cyclization of the oligomers, and the dimerization of NH(3)BH(3) molecules. We find that the formation of H(NH(2)BH(2))(n+1)H oligomers occurs first through reactions of the H(NH(2)BH(2))(n)H oligomers with BH(3) followed by reactions with NH(3) and the release of H(2), where the BH(3) and NH(3) intermediates are formed through dissociation of NH(3)BH(3). We also find that the dimerization of the NH(3)BH(3) molecules to form cyclic c-(NH(2)BH(2))(2) is slightly exothermic, with an unexpected transition state that leads to the simultaneous release of two H(2) molecules. The dehydrogenations of the oligomers are also exothermic, typically by less than 10 kcal/(mol of H(2)), with the largest exothermicity for n = 3. The transition state search shows that the one-step direct dehydrocoupling cyclization of the oligomers is not a favored pathway because of high activation barriers. The dihydrogen bonding, in which protic (H(N)) hydrogens interact with hydridic (H(B)) hydrogens, plays a vital role in stabilizing different structures of the reactants, transition states, and products. The dihydrogen interaction (DHI) within the R-BH(2)(eta(2)-H(2)) moiety accounts for both the formation mechanisms of the oligomers and for the dehydrogenation of ammonia borane.
H(NH(2)BH(2))(n)H 低聚物是氨硼烷(NH(3)BH(3)和氨基硼烷(NH(4)BH(4))脱氢的可能产物,它们属于硼-氮-氢(BNH(x))化合物类,是有前途的化学储氢材料。了解这些低聚物的形成动力学和反应途径及其进一步脱氢反应对于开发基于 BNH(x)的储氢材料至关重要。我们使用密度泛函理论(DFT)、从头算波函数理论和 Car-Parrinello 分子动力学(CPMD)模拟对 NH(3)BH(3)单体的低聚物 H(NH(2)BH(2))(n)H(n = 1-4)、聚氨基硼烷(PAB)以及随后的脱氢步骤进行了计算建模,以形成聚亚氨基硼烷(PIB)。通过计算过渡态搜索和固有反应坐标的评估,我们研究了 B-N 键的断裂、NH(3)BH(3)分子与中间体的反应、通过分子内和分子间氢转移释放氢气、低聚物的脱氢偶联/环化以及 NH(3)BH(3)分子的二聚化。我们发现 H(NH(2)BH(2))(n+1)H 低聚物的形成首先通过 H(NH(2)BH(2))(n)H 低聚物与 BH(3)的反应以及与 NH(3)的反应和 H(2)的释放发生,其中 BH(3)和 NH(3)中间体通过 NH(3)BH(3)的解离形成。我们还发现,NH(3)BH(3)分子的二聚化形成环状 c-(NH(2)BH(2)(2)稍微放热,具有出乎意料的过渡态,导致同时释放两个 H(2)分子。低聚物的脱氢反应也是放热的,通常小于 10 kcal/(mol 的 H(2)),其中 n = 3 的放热最大。过渡态搜索表明,由于高活化能垒,低聚物的一步直接脱氢偶联环化不是有利的途径。质子(H(N))氢与氢化物(H(B))氢之间的双氢键在稳定反应物、过渡态和产物的不同结构中起着至关重要的作用。R-BH(2)(eta(2)-H(2)) 部分内的双氢相互作用(DHI)既解释了低聚物的形成机制,也解释了氨硼烷的脱氢反应。
