2020
DOI: 10.3390/c6040080
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Carbon Allotropes as ITO Electrode Replacement Materials in Liquid Crystal Devices

Abstract: Indium tin oxide (ITO)-free optoelectronic devices have been discussed for a number of years in the light of a possible indium shortage as demand rises. In particular, this is due to the largely increased number of flat panel displays and especially liquid crystal displays (LCDs) being produced for home entertainment TV and mobile technologies. While a shortage of primary indium seems far on the horizon, nevertheless, recycling has become an important issue, as has the development of ITO-free electrode materia… Show more

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Cited by 7 publications
(4 citation statements)
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References 174 publications
(210 reference statements)
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“…The typical fabrication method for carbonDEP relies on the carbonization of a patterned organic precursor to form glasslike carbon, which is an allotrope of carbon (24). Although the electrical conductivity of glass-like carbon depends on the carbonization process, usual values reported hover around 1 × 10 −4 Ω/m (25), which is a few orders of magnitudes less than the ideal conductor but similar to indium tin oxide (26,27). Such electrical conductivity allows implemention of DEP forces with a relatively low voltage (<20 Vpp), when the spacing between electrodes is in the order of tens of micrometers.…”
Section: Fabrication Of Carbondep Devicementioning
confidence: 99%
“…The typical fabrication method for carbonDEP relies on the carbonization of a patterned organic precursor to form glasslike carbon, which is an allotrope of carbon (24). Although the electrical conductivity of glass-like carbon depends on the carbonization process, usual values reported hover around 1 × 10 −4 Ω/m (25), which is a few orders of magnitudes less than the ideal conductor but similar to indium tin oxide (26,27). Such electrical conductivity allows implemention of DEP forces with a relatively low voltage (<20 Vpp), when the spacing between electrodes is in the order of tens of micrometers.…”
Section: Fabrication Of Carbondep Devicementioning
confidence: 99%
“…37 Thus, strategically bringing down the electrode cost while maintaining an uncompromised device performance is much desired. In this context, attempts are observed in the literature to design costeffective alternative TCEs, such as silver or copper nanowires, [38][39][40][41][42][43][44] graphene, [45][46][47] carbon nanotubes, 46,47 aluminiumdoped zinc oxide (AZO), 48,49 and conducting polymers. 50 However, the process complexity, low stability, high sheet resistance, inhomogeneous electric eld distribution and low transparency limit their application in EC smart window fabrication.…”
Section: Introductionmentioning
confidence: 99%
“…[27] Carbon materials derived from biomass are widely applied in bioelectrochemical systems, [28][29][30] biosensing applications, [31] and ITO electrode replacement. [32] Additionally, their high electrical conductivity and overall stability during cycling, makes carbon based materials suitable for rechargeable electrochemical power sources, such as batteries, including stationary and large-scale systems, [10,33,34] supercapacitors, [35,36] Na-ion batteries, [37][38][39] and Na-ion capacitors. [40] For all these applications, an efficient charge transfer at the materials interfaces (solid/solid or solid/liquid) is crucial and found to be ideal for applications in combination with organic semiconductors (OSCs).…”
Section: Introductionmentioning
confidence: 99%
“…Among a multitude of applications one finds that carbon based nanomaterials are used to overcome intrinsic limitations in solar cells based on carbon nanomaterials, [19–23] and are heavily used as either active components or supports in electrocatalysis, [24–26] and fuel cells [27] . Carbon materials derived from biomass are widely applied in bioelectrochemical systems, [28–30] biosensing applications, [31] and ITO electrode replacement [32] . Additionally, their high electrical conductivity and overall stability during cycling, makes carbon based materials suitable for rechargeable electrochemical power sources, such as batteries, including stationary and large‐scale systems, [10,33,34] supercapacitors, [35,36] Na‐ion batteries, [37–39] and Na‐ion capacitors [40] .…”
Section: Introductionmentioning
confidence: 99%