Electroless plating of Co–Zn–P thin film onto nanodiamond cores

“…In these reactions X − denotes any of the OH − , SO4 2− , or Cl − anions or an organic ligand [90][91][92]. However, previous studies have reported that if three anions (OH − , SO4 2− , or Cl − ) are present in an electrolytic bath (for example, a Watts bath containing NiSO4, NaCl, and H3BO3), the anion X − is usually Cl − , and the rate-determining step is the reaction in Equation (16), i.e., the first electron transfer step [90,92].…”

“…Historically, the main thrust in the investigation into electrodeposition has been two-fold: Firstly improving corrosion resistance and, secondly, improving the wear resistance and mechanical properties of materials. In more recent times, these two demands continue to be of prominence; notwithstanding, a heightened research effort has gone into the study and development of processes for other areas of applications, such as magnetic properties [7][8][9][10][11][12][13][14][15][16][17][18][19] and catalysis, hydrogen permeability and separation [20][21][22][23][24][25][26][27][28][29], membrane technology, electronic devices, metallization of non-and semiconductors, and fuel cells . Furthermore, electrodeposition is one of the most convenient methods to obtain metal/alloys of high melting points, such as chromium (Cr, 1907 • C), nickel (Ni, 1455 • C), and molybdenum (Mo, 2623 • C) [54,55], even at ambient temperatures, of which the first two are of interest in this review.…”

Advances on Cr and Ni Electrodeposition for Industrial Applications—A Review

“…In these reactions X − denotes any of the OH − , SO4 2− , or Cl − anions or an organic ligand [90][91][92]. However, previous studies have reported that if three anions (OH − , SO4 2− , or Cl − ) are present in an electrolytic bath (for example, a Watts bath containing NiSO4, NaCl, and H3BO3), the anion X − is usually Cl − , and the rate-determining step is the reaction in Equation (16), i.e., the first electron transfer step [90,92].…”

“…Historically, the main thrust in the investigation into electrodeposition has been two-fold: Firstly improving corrosion resistance and, secondly, improving the wear resistance and mechanical properties of materials. In more recent times, these two demands continue to be of prominence; notwithstanding, a heightened research effort has gone into the study and development of processes for other areas of applications, such as magnetic properties [7][8][9][10][11][12][13][14][15][16][17][18][19] and catalysis, hydrogen permeability and separation [20][21][22][23][24][25][26][27][28][29], membrane technology, electronic devices, metallization of non-and semiconductors, and fuel cells . Furthermore, electrodeposition is one of the most convenient methods to obtain metal/alloys of high melting points, such as chromium (Cr, 1907 • C), nickel (Ni, 1455 • C), and molybdenum (Mo, 2623 • C) [54,55], even at ambient temperatures, of which the first two are of interest in this review.…”

Advances on Cr and Ni Electrodeposition for Industrial Applications—A Review

“…The Co-Zn-P thin film coated nano-diamond materials were the basis for providing a feasible solution over the expensive cobalt material in the synthesis of this type of magnetic thin film materials. These magnetic film materials have been witnessing myriad prospective applications in the field of Magnetic Abrasive Lapping Materials in the near future [87]. CNT were decorated with FeCO using one-step polymer-stabilization activation step and low-cost electroless deposition.…”

Electroless Deposition of Nanolayered Metallic Coatings

Synthesis of NiWP coated diamonds particles with enhanced mechanical and anti-corrosion property for diamond wires of the sawing process