Recently, sn based alloys including sn co [6,7], sn ni [8,9], and sn cu [10][11] [12] have received much attention to improve the cycle performance of sn based electrode. the alloyed elements with. Eds spectrum of the sn cu alloy deposited on stainless steel sheet. sn–cu alloy deposit on stainless steel sheet was. prepared by electrodeposition under the same conditions. the.
The sn–cu alloy was determined by eds and xrd. fig. 3 illustrates the eds spectrum of the sn–cu alloy, which indicates that the average atomic ratio of sn:cu is about 50.15:49.85 for this alloy. download : download full size image; fig. 3. eds spectrum of the sn–cu alloy deposited on stainless steel sheet. Xrd pattern of the sn cu alloy is shown in fig. 4, which indicates the presence of two different phase, i.e. the main electrodeposited product of cu 6 sn 5 (jcpds no. 45 1488) with monoclinic. The experimental results showed that cu sn alloy deposited on the copper substrate (j coor (ma cm −2) = 0.037) had lower corrosion current density than electrodeposited cu sn alloy on steel substrate (j coor (ma cm −2) = 3.561), which indicated that the coating was a protective coating without pores. A gold coloured, dense, low sn binary cu–sn alloy coating containing 13.72% sn was finally obtained. these results provide a theoretical basis for the electrodeposition of cu–sn alloys. lifeng ding and chongyan chen have contributed equally to this work. lifeng ding [email protected]. qiang li [email protected].
The experimental results showed that cu sn alloy deposited on the copper substrate (j coor (ma cm −2) = 0.037) had lower corrosion current density than electrodeposited cu sn alloy on steel substrate (j coor (ma cm −2) = 3.561), which indicated that the coating was a protective coating without pores. A gold coloured, dense, low sn binary cu–sn alloy coating containing 13.72% sn was finally obtained. these results provide a theoretical basis for the electrodeposition of cu–sn alloys. lifeng ding and chongyan chen have contributed equally to this work. lifeng ding [email protected]. qiang li [email protected]. At present, there is a growing recognition of the potential of sdss as a viable substitute for austenite stainless steel because of its enhanced strength and reduced weight [2, 3]. as a result, it has witnessed increased utilization in demanding environments such as petrochemical, nuclear and marine sectors [4, 5]. nevertheless, the increased. Abstract the electrodeposition of a cu–sn binary alloy on stainless steel from a cyanide free alkaline electrolyte containing edta·2na and c4h4o6kna was investigated to explore the possibility of a cyanide free double complexing system that maintains the decorative quality and coating performance. the cu–sn co deposition occurred at −0.95 vvs.hg|hgo, and the height of cathode peak a.
At present, there is a growing recognition of the potential of sdss as a viable substitute for austenite stainless steel because of its enhanced strength and reduced weight [2, 3]. as a result, it has witnessed increased utilization in demanding environments such as petrochemical, nuclear and marine sectors [4, 5]. nevertheless, the increased. Abstract the electrodeposition of a cu–sn binary alloy on stainless steel from a cyanide free alkaline electrolyte containing edta·2na and c4h4o6kna was investigated to explore the possibility of a cyanide free double complexing system that maintains the decorative quality and coating performance. the cu–sn co deposition occurred at −0.95 vvs.hg|hgo, and the height of cathode peak a.
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