Colloidal-chemical mechanism of Zn(OH)2-ZnO layer formation at the glass - ammonia solution - Zn(II) interface

IF 0.8 Q4 NANOSCIENCE & NANOTECHNOLOGY
Evgeny V. Polyakov, Maria A. Maksimova, Julia V. Kuznetsova, L. Buldakova
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Abstract

A BSTRACT Thermodynamic and experimental studies of Zn(OH) 2 /ZnO particle formation conditions in the model of closed system Zn 2+ –NH 3 ,aq –NH 3 ,gas –H + –OH − –H 2 O–N 2 ,gas (1), which often occurs in the process of synthesis of zinc oxide nanoparticles and films by chemical bath deposition (CBD) methods, were carried out. It was shown that the driving force for the formation and growth of Zn(OH) 2 /ZnO particles in the initially homogeneous system (1) at 25 ◦ C is the difference in the chemical potential of particles at the initial temperature (unsaturated system) and the synthesis temperature (supersaturated system). Using vibrational spectroscopy, X-ray phase and chemical analysis, diffuse light scattering and electrophoresis methods, it was found that the phase transformation of Zn(OH) 2 into ZnO takes place in the region of 85 – 90 ◦ C. The colloid-chemical transformation of Zn(NH 3 ) 2+4 ionic particles into colloidal polycrystals of Zn(OH) 2 /ZnO composition was established for the first time to be a staged process. The first stage of the process in the solution volume is localized at the gas nanobubble-solution interface as a result of rapid formation, growth and removal of gas nanobubbles from the solution. The interaction of positively charged Zn(OH) 2 nanoparticles with the surface of larger negatively charged gas nanobubbles creates colloidal aggregates “bubble || surface film of hydroxide nanoparticles”. Their adhesion forms an openwork foam-like structure of the colloid in the solution and in the film on the interfaces at the first stage of synthesis. After degassing of the electrolyte solution, the second stage develops, consisting of the nucleation and ionic-molecular growth of Zn(OH) 2 /ZnO particles from the supersaturated solution, their distribution between the solution and the electrolyte – reactor wall – air interfaces. The film growth at this stage is regulated by the difference in surface charges of the double electric layer of the interface and polycrystalline colloidal particles. In the solution and on the interface, columnar Zn(OH) 2 /ZnO structures grow as volumetric stars with conical hexagonal spikes
在玻璃-氨溶液-Zn (II)界面形成Zn(OH)2-ZnO层的胶体化学机理
摘要对化学浴沉积法(CBD)合成氧化锌纳米颗粒和薄膜过程中经常出现的zn2 + - nh3、aq - nh3、gas -H + -OH−- h2 o - n2、gas(1)封闭体系模型中Zn(OH) 2 /ZnO颗粒形成条件进行了热力学和实验研究。结果表明,在25◦C条件下,初始均相体系(1)中Zn(OH) 2 /ZnO颗粒形成和生长的驱动力是初始温度(不饱和体系)和合成温度(过饱和体系)下颗粒化学势的差异。利用振动光谱、x射线物相及化学分析、漫射光散射和电泳等方法,发现Zn(OH) 2向ZnO的相变发生在85 ~ 90°c范围内,首次确立了Zn(nh3) 2+4离子粒子向Zn(OH) 2 /ZnO组成的胶体多晶的胶体化学转变是一个阶段性过程。由于气体纳米气泡在溶液中快速形成、生长和去除,溶液体积中过程的第一阶段定位于气体纳米气泡-溶液界面。带正电的Zn(OH) 2纳米粒子与较大的带负电的气体纳米气泡表面相互作用,形成了胶体聚集体“氢氧化物纳米粒子的气泡表面膜”。在合成的第一阶段,它们的粘附形成了溶液中的胶体和界面上的膜中的多孔泡沫状结构。电解液脱气后进入第二阶段,即过饱和溶液中Zn(OH) 2 /ZnO颗粒的成核和离子分子生长,并在溶液和电解液-反应器壁-空气界面之间分布。这一阶段的薄膜生长受界面双电层和多晶胶体颗粒表面电荷差异的调控。在溶液中和界面上,柱状Zn(OH) 2 /ZnO结构生长为具有锥形六边形尖峰的体积星
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来源期刊
Nanosystems: Physics, Chemistry, Mathematics
Nanosystems: Physics, Chemistry, Mathematics NANOSCIENCE & NANOTECHNOLOGY-
CiteScore
1.80
自引率
11.10%
发文量
64
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