Pulsed Electrodeposition of Ni‐Mo Alloys

Nee, C. C.; Kim, W.; Weil, R.

doi:10.1149/1.2095883

Cited by 66 publications

(41 citation statements)

References 6 publications

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“…Hence, the pulse electrodeposited Si electrodes were directly assembled in a 2025 coin cell without The SEM analysis (Figure 2) of the samples shows a drastic change in morphology between the films deposited at 0 (galvanostatic, PEDSi-0), 500 (PEDSi-500) and 1000 Hz (PEDSi-1000). PEDSi-0 (Figure 2c) which corresponds to the constant current electrodeposition showed islands of silicon approximately 5-10 µm wide simulating dried mud cracks, which is in good agreement with previous study reported [37]. PEDSi-500 (Figure 2d) which corresponds to pulse current frequency of 500 Hz, showed a cracked morphology very similar to PEDSi-0, however, the solid islands of Si were replaced by discrete particulate deposits.…”

Section: Electrochemical Characterization Of Pedsi On Cusupporting

confidence: 90%

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Pulsed Current Electrodeposition of Silicon Thin Films Anodes for Lithium Ion Battery Applications

et al. 2017

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Electrodeposition of amorphous silicon thin films on Cu substrate from organic ionic electrolyte using pulsed electrodeposition conditions has been studied. Scanning electron microscopy analysis shows a drastic change in the morphology of these electrodeposited silicon thin films at different frequencies of 0, 500, 1000, and 5000 Hz studied due to the change in nucleation and the growth mechanisms. These electrodeposited films, when tested in a lithium ion battery configuration, showed improvement in stability and performance with an increase in pulse current frequency during deposition. XPS analysis showed variation in the content of Si and oxygen with the change in frequency of deposition and with the change in depth of these thin films. The presence of oxygen largely due to electrolyte decomposition during Si electrodeposition and the structural instability of these films during the first discharge-charge cycle are the primary reasons contributing to the first cycle irreversible (FIR) loss observed in the pulse electrodeposited Si-O-C thin films. Nevertheless, the silicon thin films electrodeposited at a pulse current frequency of 5000 Hz show a stable capacity of~805 mAh·g −1 with a fade in capacity of~0.056% capacity loss per cycle (a total loss of capacitỹ 246 mAh·g −1 ) at the end of 500 cycles.

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Section: Electrochemical Characterization Of Pedsi On Cusupporting

confidence: 90%

“…The pulse power electrodeposition approach offers an economical and easy way to change the grain size and morphology of the deposits, thus enhancing the density of coatings and their mechanical strength and corrosion properties [36][37][38][39].…”

Section: Introductionmentioning

confidence: 99%

Pulsed Current Electrodeposition of Silicon Thin Films Anodes for Lithium Ion Battery Applications

et al. 2017

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“…One of the reasons for using a pulse rather than dc plating voltage is that pulse voltage can suppress plating thickness nonuniformity. [1][2][3][4][5] In contrast, this paper deals with an application wherein nonuniform plating thickness induced by surface condition variations is a desirable feature.Electroplating is the commonly used method of fabricating metal contacts of thickness Ͼ2 m on semiconductor substrates. This paper presents the interesting plating nonuniformities introduced by dc and PR plating waveforms on semiconductor substrates in which the doping polarity varies over the semiconductor surface.…”

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DC and Periodic Reverse Electroplating of Semiconductor Surfaces Having Adjacent p-Type and n-Type Areas

Karmalkar

Venkatasubramanian

Oak

2002

J. Electrochem. Soc.

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This paper presents interesting results of electroplating semiconductor surfaces having adjacent p-type and n-type areas, using dc and periodic reverse ͑PR͒ voltages. It is shown that, the n-type ͑p-type͒ areas of n-type substrates having diffused/implanted p-type pockets get selectively plated by dc ͑PR͒ plating voltages. On the other hand, a dc plating voltage selectively plates the p-type areas of p-type substrates containing diffused/implanted n-type regions; in this case, PR plating serves no useful purpose. Applications of these results are discussed. © 2002 The Electrochemical Society. ͓DOI: 10.1149/1.1491983͔ All rights reserved. It is well known that both dc and pulse currents have been used for electroplating.1-8 The voltage waveform employed in pulse plating applications is shown in Fig. 1. The voltage periodically switches between two values V 1 and V 2 . When one of these two values is negative, the plating process is referred to as periodic reverse or PR plating. DC plating can be regarded as a special case of pulse plating with V 1 ϭ V 2 .In a general pulse plating application, the metal deposition rate depends on the average current over the plating waveform cycle, rather than the current levels in individual half-cycles. The average current into any area of the substrate depends on the resistance from the anode to the cathode contacting that area. Since this resistance is a function of the substrate surface condition, surface areas differing in conditions draw different average currents and plating thicknesses. Ensuring uniform plating thickness over the substrate surface, by overcoming variation in surface conditions, has been an overriding concern in electroplating research. One of the reasons for using a pulse rather than dc plating voltage is that pulse voltage can suppress plating thickness nonuniformity. [1][2][3][4][5] In contrast, this paper deals with an application wherein nonuniform plating thickness induced by surface condition variations is a desirable feature.Electroplating is the commonly used method of fabricating metal contacts of thickness Ͼ2 m on semiconductor substrates. This paper presents the interesting plating nonuniformities introduced by dc and PR plating waveforms on semiconductor substrates in which the doping polarity varies over the semiconductor surface. Both n-type substrates with p-type pockets and p-type substrates with n-type pockets are considered. Some useful applications of such plating nonuniformities are described. n-Type Substrate Having p-Type PocketsThe electroplating of these substrates is illustrated in Fig. 2. The parallel paths to the n-regions, denoted X, have been effectively represented by a single bath resistance R N in the equivalent circuit. This resistance and the bath resistance R P into the p region are inversely proportional to the surface areas of the n and p regions, respectively, exposed to the bath. The path Y encounters, in addition to R P , a p-n diode, which is absent in the path X. Note that the equivalent circuit shown applies, ev...

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ChemInform Abstract: Pulsed Electrodeposition of Ni‐Mo Alloys.

1988

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ChemInform Abstract The effect of pulsing the current on the composition, internal stress, and mechanical properties of Ni-Mo electrodeposits is studied (Cu-substrate, plating bath: nickel sulfate-sodium molybdenate-sodium citrate, pH 10.5). The Mo content increases with peak current density and to a lesser degree with increasing off-time. High-frequency pulse plating at peak current densities of 25 mA/cm2 results in increased yield and tensile strengths. Deposition of alternate layers of different composition results in improved mechanical properties after annealing at 300 rc C.

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Pulsed Electrodeposition of Ni‐Mo Alloys

Cited by 66 publications

References 6 publications

Pulsed Current Electrodeposition of Silicon Thin Films Anodes for Lithium Ion Battery Applications

Pulsed Current Electrodeposition of Silicon Thin Films Anodes for Lithium Ion Battery Applications

DC and Periodic Reverse Electroplating of Semiconductor Surfaces Having Adjacent p-Type and n-Type Areas

ChemInform Abstract: Pulsed Electrodeposition of Ni‐Mo Alloys.

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