Neutron Diffraction Study of Self-Curing and Self-Crystallization Phenomena of Low-Temperature Dehydrogenating Products of Powder Crystals of Rare-Earth Metals Trihydroxides

结晶过程及技术期刊(英文) Pub Date : 2013-10-17 DOI:10.4236/JCPT.2013.34024

Khidirov Irisali

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Abstract

The phenomenon of hydrogen thermoemission out of a crystal lattice of powder rare-earth metals trihydrooxides R(OH)3 (R is La, Pr, Nd) was found. The hydrogen thermoemission out of a crystal lattice is partial or full removal of hydrogen out of the crystal lattice of powder hydrogen-containing crystal without change of symmetry of such crystal at continuous evacuation of high vacuum at evacuation temperature of Тev. which is lower than recrystallization Тrecrys. or disintegration (Tdisinteg.) temperature of this crystal: Тev. Тrecrys. Tdisineg.. By neutron diffraction it is found that low- temperature (Тevacuation = 400 - 420 K ) removal of hydrogen (by hydrogen thermoemission) out of a crystal lattice of trihydrooxide R(OH)3 under continuous high vacuum evacuating makes possible to obtain metastable “trioxide” R[O]3. Existence of such substance contradicts to the valence law (oxygen is bivalent and Pr is trivalent in hydroxides). Such “trioxide” has a superfluous negative charge: R3+O6-. So they aspire to “capture” three more protons (hydrogen ions) from a water molecules. Obviously, this substance can be stable at low temperatures and in the mediums, which are not containing hydrogen. In the air at room temperature this substance, most likely, interacting with water molecules, gradually again turns into trihydroxide R(OH)3, compensating the superfluous negative charge by three hydrogen atoms. From this it follows that substance R[O3] can simultaneously be an absorber of hydrogen and generator of oxygen at atmospheric conditions and in any mediums which contains water molecules, without any prior processing like heating or high pressure. Thus, the obtained material, without any prior processing like heating or high pressure, can simultaneously be oxygen generator and hydrogen accumulator in any mediums characteristic of R[O3] to transform into stable form R(OH)3 by selective bonding of hydrogen from the hydrogen-containing environment allowing implication of Pr[O3] as the hydrogen selective absorber. Separation (by low-temperature removal) of hydrogen out of R(OH)3 lattice can again lead to restoration of its capabilities to be a simultaneous hydrogen accumulator and oxygen generator in a medium containing water molecules.

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稀土金属三氢氧化物粉末晶体低温脱氢产物自固化自结晶现象的中子衍射研究

发现了粉末稀土金属三氢氧化物R(OH)3 (R为La, Pr, Nd)晶格外热发射氢的现象。晶格外氢热发射是指在抽真空温度为Тev的条件下，含氢粉末晶体在连续抽真空条件下，在不改变晶体对称性的情况下，将氢从晶格中部分或全部抽走。这比再结晶低Тrecrys。或该晶体的崩解温度:Тev。Тrecrys。Tdisineg . .通过中子衍射发现，在连续高真空抽气条件下，低温(Тevacuation = 400 - 420 K)脱除三氢氧化物R(OH)3晶格中的氢(通过氢热发射)，可以得到亚稳的“三氧化物”R[O]3。这种物质的存在违背了价定律(氧在氢氧化物中是二价的，Pr是三价的)。这种“三氧化物”有一个多余的负电荷:R3+O6-。因此，他们渴望从一个水分子中“捕获”三个以上的质子(氢离子)。显然，这种物质在低温和不含氢的介质中是稳定的。在室温下的空气中，这种物质很可能与水分子相互作用，逐渐再次变成三氢氧根R(OH)3，用三个氢原子补偿多余的负电荷。由此可见，物质R[O3]可以在大气条件下和任何含有水分子的介质中同时成为氢的吸收剂和氧的产生剂，而无需经过加热或高压等任何事先处理。因此，所获得的材料无需加热或高压等任何事先处理，即可在任何具有R[O3]特征的介质中同时作为氧气发生器和氢气蓄能器，通过含氢环境中的氢的选择性键合转化为稳定的R(OH)3，这意味着Pr[O3]可以作为氢气的选择性吸收剂。从R(OH)3晶格中分离氢(通过低温去除)可以再次恢复其在含有水分子的介质中同时作为氢气蓄积器和氧气发生器的能力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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结晶过程及技术期刊(英文)

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