LEADER 02275nam 2200337zn 450 001 9910774639903321 005 20240320090122.0 035 $a(CKB)5470000000569913 035 $a(NjHacI)995470000000569913 035 $a(EXLCZ)995470000000569913 100 $a20240320d2019 uy 0 101 0 $aeng 135 $aur||||||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aChapter Metallic nanowire percolating networks $efrom main properties to applications /$fNgoc Duy Nguyen 210 1$a[Place of publication not identified] :$cIntechOpen,$d2019. 215 $a1 online resource 330 $aThere has been lately a growing interest into flexible, efficient and low-cost transparent electrodes which can be integrated for many applications. This includes several applications related to energy technologies (photovoltaics, lighting, supercapacitor, electrochromism, etc.) or displays (touch screens, transparent heaters, etc.) as well as Internet of Things (IoT) linked with renewable energy and autonomous devices. This associated industrial demand for low-cost and flexible industrial devices is rapidly increasing, creating a need for a new generation of transparent electrodes (TEs). Indium tin oxide has so far dominated the field of TE, but indium's scarcity and brittleness have prompted a search into alternatives. Metallic nanowire (MNW) networks appear to be one of the most promising emerging TEs. Randomly deposited MNW networks, for instance, can present sheet resistance values below 10 ?/sq., optical transparency of 90% and high mechanical stability under bending tests. AgNW or CuNW networks are destined to address a large variety of emerging applications. The main properties of MNW networks, their stability and their integration in energy devices are discussed in this contribution. 517 $aChapter Metallic nanowire percolating networks 606 $aNanotechnology$xSafety measures 615 0$aNanotechnology$xSafety measures. 676 $a620.5 700 $aNguyen$b Ngoc Duy$01732466 801 0$bNjHacI 801 1$bNjHacl 906 $aBOOK 912 $a9910774639903321 996 $aChapter Metallic nanowire percolating networks$94146638 997 $aUNINA