Abstract
Thin films of W oxide were prepared by reactive DC magnetron sputtering (5 cm-diameter W target), and their electrochromic (EC) properties were investigated in an electrolyte of LiClO4 in propylene carbonate. The purpose of the study was to elucidate the role of critical deposition parameters—oxygen/argon gas flow ratio for the sputter plasma Γ, total pressure in the sputter plasma ptot, and sputtering power Ps—on the EC performance with foci on electrochemical cycling durability and optical modulation range ΔT. Specifically, we used 0.15 ≤ Γ ≤ 0.90, 5 ≤ ptot ≤ 30 mTorr, and 200 ≤ Ps ≤ 400 W and studied cycling durability for up to 500 voltammetric cycles in the range 2.0–4.0 V vs. Li/Li+ together with optical properties at a wavelength of 528 nm. Most significantly, we discovered that a judicious choice of deposition parameters could yield films with superior cycling durability. Thus a ~300 nm-thick film prepared at Γ = 0.90, ptot = 10 mTorr, and Ps = 200 W showed ΔT ≈ 65% after an initial “training” during ~100 voltammetric cycles; higher values of ptot, on the other hand, yielded films whose ΔTs degraded by ~10% during the cycling, and a lower value of ptot led to dark films with only marginal electrochromism. Hence our work delineates a pathway towards W oxide films with excellent durability of the EC properties.
Highlights
Electrochromic (EC) materials are characterized by the ability to sustain persistent and reversible changes of their optical properties under the action of an electrical stimulus
By varying the deposition conditions, we document their importance for the deposited EC films and, most importantly, we demonstrate that a judicious choice of, ptot, and Ps can yield EC films with superior electrochemical durability in an Li-ion-conducting electrolyte
We have presented results of a comprehensive study on sputter deposition of W oxide films under varying O2/Ar gas flow ratios in the sputter plasma, total pressure of the sputter plasma, and sputtering power
Summary
Electrochromic (EC) materials are characterized by the ability to sustain persistent and reversible changes of their optical properties under the action of an electrical stimulus Integrating these materials in multilayer thin-film constructions enable devices such as variable-transmittance smart glazing with applications in energyefficient buildings with excellent indoor comfort for the occupants, variable-reflectance devices such as non-dazzling rear view mirrors for automobiles, non-emissive information displays of diverse kinds, dynamic camouflage for defense applications, etc. The preferred thin-film deposition technology for EC smart glazing is reactive DC magnetron sputtering with a plasma comprised of Ar with added O2, which is capable of producing coatings of the required materials with adequate optical quality at sufficient deposition rate for multiple-square-meter areas either by in-line coating or by roll-toroll technology [12,13,14,15]
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