EnFACE法镍电解液的初步研究

International Journal of Science and Engineering Pub Date : 2015-04-15 DOI:10.12777/IJSE.8.2.135-140

T. Widayatno, S. Roy

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引用次数: 2

摘要

镍电解液用于无光刻的微图案转移工艺，EnFACE已被开发。先前对铜沉积的研究表明，需要~2.7 Sm -1的电导率。电解液的电化学参数，即电流密度和过电位也是控制成功模式复制的关键。因此，研究的重点是测量电解质在不同镍浓度下的物理化学性质和电化学行为，以及氯化物和磺胺盐的络合剂。研究了浓度在0.14 ~ 0.3 M之间的氨基甲酸盐、氯化物和氨基甲酸盐-氯化物复合镍电解质。测量物理化学性质，即pH值和电导率，以确保它们是否在所需值。在标准的三电极电池中，通过极化实验测量了电解质的电化学行为。工作电极为铜盘(表面积0.196 cm 2)，反电极为铂网。在饱和甘汞参比电极(SCE)上测量电势。实验在不同的扫描速率和旋转圆盘电极(RDE)转速下进行，观察扫描速率和搅拌的影响。根据测定的理化性质，选择0.19 M磺酸镍作为电解液进行实验。搅拌溶液的极化曲线表明，整个镍电沉积反应是由动力学和传质共同控制的。镍的还原电位在-0.7 ~ -1.0 V范围内。相应的镍沉积电流密度在-0.1 ~ -1.5 mA cm- 2之间。

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Initial study of Nickel Electrolyte for EnFACE Process

Nickel electrolyte for a micro-pattern transfer process without photolithography, EnFACE, has been developed. Previous work on copper deposition indicated that a conductivity of ~2.7 Sm -1 is required. Electrochemical parameters of electrolyte i.e. current density and overpotential are also crucial to govern a successful pattern replication. Therefore, the investigation focused on the measurement of physicochemical properties and electrochemical behaviour of the electrolyte at different nickel concentrations and complexing agents of chloride and sulfamate. Nickel electrolytes containing sulfamate, chloride and combined sulfamate-chloride with concentrations between 0.14 M and 0.3 M were investigated. Physicochemical properties i.e. pH and conductivity were measured to ensure if they were in the desired value. The electrochemical behaviour of the electrolytes was measured by polarisation experiments in a standard three-electrode cell. The working electrode was a copper disc (surface area of 0.196 cm 2 ) and the counter electrode was platinum mesh. The potential was measured againts a saturated calomel reference electrode (SCE). The experiments were carried out at various scan rate and Rotating Disc Electrode (RDE) rotation speed to see the effect of scan rate and agitation. Based on the measured physicochemical properties, the electrolyte of 0.19 M nickel sulfamate was chosen for experimentation. Polarisation curve of agitated solution suggested that overall nickel electrodeposition reaction is controlled by a combination of kinetics and mass transfer. Reduction potential of nickel was in the range of -0.7 to -1.0 V. The corresponding current densities for nickel deposition were in the range of -0.1 to -1.5 mA cm- 2 .

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International Journal of Science and Engineering

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审稿时长

8 weeks