排序方式: 共有9条查询结果,搜索用时 78 毫秒
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通过分子动力学方法模拟了Cu-Al合金液相,然后模拟降温过程得到Cu-Al非晶合金.通过计算机编程建立了Cu-Al-M非晶基体、Cu-Al-M非晶表面及吸附O原子Cu-Al-M非晶表面原子结构模型.利用实空间连分数方法,研究了添加微量合金元素Zr,Nb,Ta,V,Y,Sc对Cu基大块非晶合金的腐蚀行为的影响机理.研究发现合金元素Zr,Nb,Ta,V,Sc不向清洁Cu基非晶表面偏聚,但除Y外向有氧吸附的表面偏聚,说明有氧吸附后Cu基非晶表面偏聚发生逆转.键级积分计算表明Zr,Nb,Ta,V,Y,Sc元素均增大与氧之间的结合力,易形成氧化膜,提高Cu基大块非晶的耐蚀性.稀土Y提高Cu基大块非晶的耐蚀性可能是由于它向合金与氧化膜界面偏聚并提高了合金与氧化膜的结合力. 相似文献
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在变压器中,当环境温度高于灌封温度时,绝缘油对容器壁产生很大的压力,易导致密封处渗漏和壳体变形。为解决以上问题,一方面通过实验研究了密封容器内油的压强随温度的变化规律,另一方面用易压缩的空心胶囊的方法补偿油的热胀冷缩,实验研究了其减压效果,并理论分析计算影响胶囊减压效果的因素。由于胶囊是绝缘体,其大小、数量和安放位置可根据实际情况灵活安排。 相似文献
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采用基于密度泛函理论的第一原理平面波赝势方法,研究了MgH2, LiBH4,LiNH2,NaAlH4几种高密度储氢材料及其合金的释氢及影响机理.结果表明:高密储氢材料MgH2,LiBH4,LiNH2,NaAlH4都比较稳定,释氢温度都很高,合金化可以降低它们的稳定性,但系统稳定性不是决定高密度储氢材料释氢性质的关键因素;带隙的宽窄基本可以表征储氢材料成键的强弱,能隙越宽,键断开越难,释氢温度就越高;LiNH2价带顶成键峰主要由Li—N成键贡献,N—H键构成较低的峰,使得LiNH2储氢材料的带隙虽很窄释氢温度却较高,且放氢过程中有氨气放出;合金化使得几种高密度储氢材料的带隙变窄,费米能级进入导带,从而使它们的释氢性能大大改善;电荷布居分析发现LiBH4中B—H键最强,LiNH2中H—N键最弱,因此LiNH2中H相对容易放出.合金化后,各储氢材料中X—H键强度都有所降低,且LiMgNH2中N—H键强度最低,因此从降低释氢温度角度,发展LiNH2储氢材料最为有利.
关键词:
储氢材料
第一原理
释氢能力 相似文献
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A first-principles study of the catalytic mechanism of the dehydriding reaction of LiNH2 through adding Ti catalysts 下载免费PDF全文
Experiments on a ball milled mixture with a 1:1 molar ratio of LiNH2 and LiH with a small amount(1 mol %) of Ti nano,TiCl3 and TiO nano 2 have revealed a superior catalytic effect on Li-N-H hydrogen storage materials.In the x-ray diffraction profiles,no trace of Ti nano,TiCl3 and TiO nano 2 was found in these doped composites,by which we deduced that Ti atoms enter LiNH2 by partial element substitution.A first-principles plane-wave pseudopotential method based on density functional theory has been used to investigate the catalytic effects of Ti catalysts on the dehydrogenating properties of LiNH2 system.The results show that Ti substitution can reduce the dehydrogenation reaction activation energy of LiNH2 and improve the dehydrogenating properties of LiNH2.Based on the analysis of the density of states and overlap populations for LiNH2 before and after Ti substitution,it was found that the stability of the system of LiNH2 is reduced,which originates from the increase of the valence electrons at the Fermi level(EF) and the decrease of the highest occupied molecular orbital(HOMO)-lowest unoccupied molecular orbital(LUMO) gap(△EH-L) near E F.The catalytic effect of Ti on the dehydrogenating kinetics of LiNH2 may be attributed to the reduction of average populations between N-H per unit bond length(nm-1),which leads to the reduction of the chemical bond strength of N-H. 相似文献
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应用基于密度泛函理论的赝势平面波第一性原理方法研究了金属元素替代对Li4BN3H10 释氢的影响机理.计算给出了结合能、电子态密度、密集数, 分析了结构的稳定性和原子间的成键情况.结果表明: 晶体的结合能与(LiM)4BN3H10(M=Ni,Ti,Al,Mg)释氢性能没有直接的关联.带隙的宽窄和带隙中是否存在杂质能级是决定(LiM)<
关键词:
LiBNH系储氢材料
第一性原理
元素替代
释氢机理 相似文献
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