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Controllable synthesis of α- and β-MnO2: cationic effect on hydrothermal crystallization

机译：α-和β-MnO2的可控制合成：对水热结晶的阳离子效应

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alpha- and beta-MnO(2) were controllably synthesized by hydrothermally treating amorphous MnO(2) obtained via a reaction between Mn(2+) and MnO(4)(-), and cationic effects on the hydrothermal crystallization of MnO(2) were investigated systematically. The crystallization is believed to proceed by a dissolution-recrystallization mechanism; i.e. amorphous MnO(2) dissolves first under hydrothermal conditions, then condenses to recrystallize, and the polymorphs formed are significantly affected by added cations such as K(+), NH(4)(+) and H(+) in the hydrothermal systems. The experimental results showed that K(+)/NH(4)(+) were in competition with H(+) to form polymorphs of alpha- and beta-MnO(2), i.e., higher relative K(+)/NH(4)(+) concentration favoured alpha-MnO(2), while higher relative H(+) concentration favoured beta-MnO(2).

机译：通过水热处理通过Mn（2+）和MnO（4）（-）之间的反应获得的非晶态MnO（2），以及对MnO（2）水热结晶的阳离子效应，可控制地合成了α-和β-MnO（2））进行了系统的调查。认为结晶是通过溶解-再结晶机理进行的。即非晶MnO（2）首先在水热条件下溶解，然后凝结以重结晶，并且形成的多晶型物受到水热系统中添加的阳离子（例如K（+），NH（4）（+）和H（+））的显着影响。实验结果表明，K（+）/ NH（4）（+）与H（+）竞争形成α-和β-MnO（2）的多晶型，即相对较高的K（+）/ NH（ 4）（+）浓度有利于alpha-MnO（2），而较高的相对H（+）浓度有利于beta-MnO（2）。

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Huang XK; Lv DP; Yue HJ; Attia A; Yang Y; 杨勇;
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年度 2008
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Controllable synthesis of α- and β-MnO2: cationic effect on hydrothermal crystallization

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