Results 1 to 10 of about 71 (39)
Surface Chirality in Rotational Magnetoelectrodeposition of Copper Films [PDF]
Magnetochemistry, 2019 Chiral surface formation was investigated in rotational magnetoelectrodeposition (RMED) of copper films, where an electrochemical cell was rotated in magnetic fields.
Iwao Mogi +2 more
exaly +16 more sources
Breaking of Odd Chirality in Magnetoelectrodeposition [PDF]
Magnetochemistry, 2022 Electrodeposition under magnetic fields (magnetoelectrodeposition; MED) can induce surface chirality on copper films. The chiral signs of MED films should depend on the magnetic field polarity; namely, the reversal of the magnetic field causes the ...
Iwao Mogi +2 more
exaly +6 more sources
Breaking of Odd Chirality in Magnetoelectrodeposition of Copper Films on Micro-Electrodes [PDF]
Magnetochemistry, 2021 The surface chirality was investigated in magnetoelectrodeposition (MED) of copper films on micro-disc electrodes with the diameters of 100 and 25 µm. The MED was conducted in the magnetic fields of 1–5 T, which were parallel or antiparallel to the ionic
Iwao Mogi +2 more
exaly +6 more sources
Fluctuation Effects of Magnetohydrodynamic Micro-Vortices on Odd Chirality in Magnetoelectrolysis [PDF]
Magnetochemistry, 2020 The magnetic field dependence of chiral surface formation was investigated in magnetoelectrodeposition (MED) and magnetoelectrochemical etching (MEE) of copper films.
Iwao Mogi +2 more
exaly +6 more sources
Effects of Vertical Magnetohydrodynamic Flows on Chiral Surface Formation in Magnetoelectrolysis
Magnetochemistry, 2018 Magnetoelectrolysis (electrolysis in magnetic fields) has potential to produce chiral surfaces on metal films. The Lorentz force causes two types of magnetohydrodynamic (MHD) flows; a vertical MHD flow and micro-MHD vortices, and the combination of these
Iwao Mogi +2 more
exaly +5 more sources
Magnetochemistry, 2022 Calcium phosphate coatings were formed on a Ti6Al4V substrate by electrodeposition under a high magnetic field up to 16 T. The magnetic field was parallelly applied to the vertical surface electrode.
Anne-Lise Daltin, Jean-Paul Chopart
exaly +3 more sources
Pulse Reverse Plating of Copper Micro-Structures in Magnetic Gradient Fields
Magnetochemistry, 2022 Micro-structured copper layers are obtained from pulse-reverse electrodeposition on a planar gold electrode that is magnetically patterned by magnetized iron wires underneath. 3D numerical simulations of the electrodeposition based on an adapted reaction
Mengyuan Huang +2 more
exaly +3 more sources
IOP Conference Series: Earth and Environmental Science, 2022 Abstract A rare-earth element (REE) is one of the minerals with many resources in Indonesia and lanthanum is one of REE. Lanthanum is widely used as a material for x-ray screens, glass lenses, optical fiber, capacitor batteries, and ceramics. Electrodeposition is a metal deposition process.
Sudibyo, Sugiyanto
exaly +2 more sources
The Origin of Homochirality by Rotational Magnetoelectrochemistry
MagnetochemistryThe origin of homochirality by rotational magnetoelectrochemistry was theoretically examined. Electrochemical reductions in a rotating solution under a static vertical magnetic field were concluded to yield microscopic vortices with L-activity for ...
Ryoichi Morimoto +8 more
doaj +2 more sources
Cu-doped ZnO deposits obtained by magnetoelectrodeposition
, 2015 In our study, ZnO electrodeposits with or without Cu-doping (up to 12 μmol/L in the electrolytic bath) have been elaborated on ITO substrate by pulsed potentiostatic mode without or with magnetic field superimposition (up to 1T). The deposits have been analyzed by XRD, SEM and EDX. Magnetic field superimposition has modified the deposit morphology.
Benaissa, M +3 more
openaire +2 more sources