Electroplating to make nanostructures. Electroplating - The chemical conversion of ions in solution into a solid deposit of metal atoms with the work.

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Presentation transcript:

Electroplating to make nanostructures

Electroplating - The chemical conversion of ions in solution into a solid deposit of metal atoms with the work of a electrical power supply Cu 2+ Cu solid Cu ions in solution 2e - Cu e - –> Cu (0) M z+ + ze - –> M (0)

Electroplating Cell V I Cu e - –> Cu (0) "reduction" CuSO 4 dissolved in water Cu (0) –> Cu e - "oxidation" anodecathode If using an inert Pt electrode: 2 H 2 O –> O 2 + 4H + + 4e - Working Electrode (WE) Counter Electrode (CE)

Amount of Deposition The number of atoms deposited is proportional to the number of electrons passed through the circuit - We can determine this by measuring the current If I is constant # electrons = Q/e = It/e where e = 1.6 x C # atoms = # electrons/z = It/ez # moles of atoms = # atoms/N A = It/ezN A eN A = (1.6 x C)(6.02 x ) = 96,500 C = F = "1 Faraday" # moles of atoms = It/Fz Cu 2+ 2e - ammeter I

Amount of Deposition (cont.) # moles of atoms = It/Fz m = mass = (It/Fz)(gram atomic weight) t = film thickness = (mass)/(density area) = m/( A) e.g., AW Cu = g/mole Cu 2+ 2e - ammeter I Note that these equations assume 100% current efficiency (CE) - that is, assuming that all of the electrons are used for converting metal ions. However, another reduction reaction may compete for electrons making the CE less than 100%. For example, 2H + + 2e - –> H 2. CE must be determined by an independent measurement.

Why choose electroplating to make nanostructures?? The process is easy to operate and only needs simple equipment. Its simple to control the deposition rate by controlling the voltage or current. Its a good way to make Nanowires in a porous template.

Electrodeposited Nanowires nanoporous template nanowires in a polycarbonate filter nanowires in a diblock copolymer template

Application Data storage elements If the nanowires are magnetic, they can be used to store data (arrow indicates the direction of magnetization)