• Title of article

    Fine grain growth of nickel electrodeposit: effect of applied magnetic field during deposition

  • Author/Authors

    V. Ganesh Kumar، نويسنده , , D. Vijayaraghavan، نويسنده , , V. Lakshminarayanan، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2005
  • Pages
    10
  • From page
    286
  • To page
    295
  • Abstract
    The electrodeposition of nickel from a nickel sulphamate bath in the presence of a magnetic field applied at an angle of 458 to the cathode surface produces a nickel deposit with a fine grain structure. The sizes of grains vary from 17 to 25 nm. We have used scanning electron microscopy (SEM), scanning tunneling microscopy (STM) and X-ray diffraction (XRD) to characterize the surface morphology of the deposit. The SEM pictures show the formation of domain growth of nickel in which the nickel nanoparticles are mostly concentrated at domain boundaries while STM and XRD analysis show the existence of individual nanoparticles. From the chronopotentiometry studies during magnetoelectrolysis of nickel, we find a significant lowering of overpotential with time and large negative shift in electrode potential in the presence of a magnetic field.We believe from these results that magnetic field induced convection increases the mass transfer rate, reduces the concentration polarisation and leads to the growth of fine grain deposit. The large shift in electrode potential on the application of magnetic field is attributed to the field-induced shift in chemical potential of the ferromagnetic nickel electrode. We have used cyclic voltammetry (CV) to determine the roughness factor and steady state current-potential plots to study the hydrogen evolution reaction on the nickelelectrodeposited surface
  • Keywords
    nanoparticles , Overpotenial , Roughness factor , magnetoelectrolysis , Convective flow , Magnetohydrodynamic effect
  • Journal title
    Applied Surface Science
  • Serial Year
    2005
  • Journal title
    Applied Surface Science
  • Record number

    1000593