Comparison of the environmental impact of the conventional nickel electroplating and the new nickel electroplating

Takuma, Yasuhiko; Sugimori, Hirokazu; Ando, Eri; Mizumoto, Kazunari; Tahara, Kiyotaka

doi:10.1007/s11367-017-1375-y

Cited by 11 publications

(8 citation statements)

References 11 publications

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“…To further verify the role of the magnetic field for the deep deposition within the substrate, nickel was used instead of lithium to simulate the electroplating process on CF. [ 47 ] Figure S1a in the Supporting Information shows the simple schematic diagram of electroplating, where the red line on the left of CF shows that only this area is in contact with the electrolyte, and the arrow indicates the direction of movement of ions into the CF. The cross‐sectional digital photo images for the CF after Ni deposition are shown in Figure S1b,c in the Supporting Information.…”

Section: Resultsmentioning

confidence: 99%

Lithiophilic 3D Copper‐Based Magnetic Current Collector for Lithium‐Free Anode to Realize Deep Lithium Deposition

Zhang

Chen

Wen

et al. 2021

Adv Funct Materials

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Lithium metal is the ideal anode material for high-energy-density lithiumbased batteries. Nevertheless, lithium metal tends to accumulate on the surface of the current collector during the plating and stripping process to form lithium dendrites, resulting in low Coulombic efficiency and safety issues. Here, a lithiophilic 3D copper-based magnetic current collector is designed by loading ferromagnetic nickel-cobalt alloy and lithiophilic zinc oxide onto the copper foam to create a lithium-free anode. Under the micromagnetic field, the novel lithium-free anode achieves a high level of deep lithium deposition (from 300 µm to about 1000 µm), successfully alleviating the large change of lithium volume. In addition, the Coulombic efficiency and cyclic stability are improved effectively. With a total capacity of 1 mA h cm −2 at a current density of 1 mA cm −2 , the Coulombic efficiency of the above remains 95% at 590th-cycle. Moreover, the symmetric cell can stably cycle for more than 560 h at 2 mA cm −2 with the capacity of 1 mA h cm −2 . This novel strategy will potentially open up new horizons for lithium-free anodes, which may be generalized to other advanced energy storage systems.

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Section: Resultsmentioning

confidence: 99%

Lithiophilic 3D Copper‐Based Magnetic Current Collector for Lithium‐Free Anode to Realize Deep Lithium Deposition

Zhang

Chen

Wen

et al. 2021

Adv Funct Materials

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“…Presence of boron in the bath waste is nonetheless reported to be harmful for the environment. Since the enforcement of Water Pollution Control Act in Japan [59] the imposed national minimum effluent standards have greatly influenced the electroplat- ing industry. Thus, it became necessary to find more environmentally friendly solutions for the electrodeposition of nickel and its alloys.…”

Section: Electrolytic Bath Compositionmentioning

confidence: 99%

“…When it comes to the environmental impact exerted by the electroplating process from either of the two baths: the one containing boric or the other containing citric acid, findings are quite contradictory. Takuma et al [59] applied a life cycle assessment method to demarcate the extent of their influence in terms of human toxicity and ecotoxicity. Results indicated that the newly developed citrate plating bath exerts higher environmental impact compared to the traditional Watts electrolyte, this owing to the release of nickel chelated with citric acid whose harmful influence overshadows the benefit of reduced boron emissions achieved by substituting boric acid in the electroplating bath.…”

Section: Electrolytic Bath Compositionmentioning

confidence: 99%

Ni-P coatings electroplating - A review, Part I: Pure Ni-P alloy

Lelevic

2018

Preprint

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In the electroplating industry Ni-P coatings are extensively employed owing to their excellent properties which enable substrate protection against corrosion and wear. Depending on their composition and structure, as-plated deposits demonstrate good mechanical, tribological and electrochemical features, catalytic activity but also beneficial magnetic characteristics. With subsequent thermal treatment hardness of Ni-P metal-metalloid system can approach or be even higher than that of hard Cr coatings. The purpose of this paper is to provide a general survey of the research work dealing with the electrodeposition of Ni-P binary alloy coatings. Proposed phosphorus incorporation mechanisms, Ni-P alloy microstructure before and after thermal treatment, its mechanical, tribological, corrosion, catalytic and magnetic properties are considered, so are the key process variables influencing phosphorus content in the deposits and the roles of the main electrolytic bath constituents. Findings on the merits of employing pulse plating and fabrication of unconventional (layered and functionally graded) structures are succinctly explored.

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“…Therefore, the environmental impact of these chemicals needs to be evaluated and reduced through suitable treatment of industrial wastewater. [ 1 ] Heavy metals, such as zinc, copper, and chromium, are harmful to the environment and human body [ 2,3 ] ; therefore, the concentrations of these metals in effluents are strictly regulated. [ 4 ] In Japan, the effluent standard value for zinc is 2 mg/L.…”

Section: Introductionmentioning

confidence: 99%

Pretreatment with fine bubbles for effective zinc ion precipitation and removal from zinc electroplating wastewater

et al. 2023

Self Cite

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Heavy metals such as zinc are widely used in plating plants for the processing of material surfaces; therefore, an adequate wastewater treatment is required afterwards to comply with wastewater regulations. However, the presence of chemicals such as degreasing agents in the wastewater generated from the plating process inhibits the formation of hydroxides, thereby making treatment of wastewater and compliance with the stipulated regulations difficult. Herein, the effects of fine bubbles on oil cleaning and wastewater treatment were investigated for developing an alternative cleaning technology to degreasing agents. The concentration of fine bubbles significantly affected the oil cleaning. The fine bubbles demonstrated remarkable cleaning of highly viscous oil, which was difficult to remove using pure water. The high cleaning effect of fine bubbles on oil was achieved because of the hydrophobic interaction of the bubbles. Furthermore, a decrease in cleaning effect was observed for samples with uneven shapes, which was attributed to the difficulty in penetration of fine bubbles in materials with irregularities. Furthermore, fine bubble cleaning exhibited better efficiency for wastewater treatment than degreaser cleaning. Therefore, fine bubble cleaning is speculated to be an excellent cleaning technology with high oil cleaning effectiveness and improved wastewater treatability.

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Comparison of the environmental impact of the conventional nickel electroplating and the new nickel electroplating

Cited by 11 publications

References 11 publications

Lithiophilic 3D Copper‐Based Magnetic Current Collector for Lithium‐Free Anode to Realize Deep Lithium Deposition

Lithiophilic 3D Copper‐Based Magnetic Current Collector for Lithium‐Free Anode to Realize Deep Lithium Deposition

Ni-P coatings electroplating - A review, Part I: Pure Ni-P alloy

Pretreatment with fine bubbles for effective zinc ion precipitation and removal from zinc electroplating wastewater

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