Gael Giusti

Flexible transparent conductive materials based on silver nanowire networks: a review

The class of materials combining high electrical or thermal conductivity, optical transparency and flexibility is crucial for the development of many future electronic and optoelectronic devices. Silver nanowire networks show very promising results and represent a viable alternative to the commonly used, scarce and brittle indium tin oxide. The science and technology research of such networks are reviewed to provide a better understanding of the physical and chemical properties of this nanowire-based material while opening attractive new applications.

Optimization of silver nanowire-based transparent electrodes: effects of density, size and thermal annealing

Silver nanowire (AgNW) networks are efficient as flexible transparent electrodes, and are cheaper to fabricate than ITO (Indium Tin Oxide). Hence they are a serious competitor as an alternative to ITO in many applications such as solar cells, OLEDs, transparent heaters. Electrical and optical properties of AgNW networks deposited on glass are investigated in this study and an efficient method to optimize them is proposed. This paper relates network density, nanowire dimensions and thermal annealing directly to the physical properties of the nanowire networksusing original physical models. A fair agreement is found between experimental data and the proposed models. Moreover thermal stability of the nanowires is a key issue in thermal optimization of such networks and needs to be studied. In this work the impact of these four parameters on the networks physical properties are thoroughly investigated via in situ measurements and modelling, such a method being also applicable to other metallic nanowire networks. We demonstrate that this approach enables the optimization of both optical and electrical properties through modification of the junction resistance by thermal annealing, and a suitable choice of nanowire dimensions and network density. This work reports excellent optical and electrical properties of electrodes fabricated from AgNW networks with a transmittance T = 89.2% (at 550 nm) and a sheet resistance of Rs = 2.9 Ω □(-1), leading to the highest reported figure of merit.

High Performance ZnO-SnO2:F Nanocomposite Transparent Electrodes for Energy Applications

Enhancing the propagation length of light without sacrificing the electro-optical properties of transparent electrodes is of particular interest to solar cells for reaching higher efficiency. This can typically be achieved by nanostructured electrodes but all too often at the expense of complexity and cost-effectiveness. In this work, we demonstrate the simple and low-cost fabrication of a new type of ZnO-SnO2:F nanocomposite thin film by combining spin-coated ZnO nanoparticles on glass with fluorine-doped SnO2 thin films deposited by atmospheric spray pyrolysis. The resulting nanocomposites exhibit a dual surface morphology featuring rough ZnO-SnO2:F nanostructures along with the original smooth SnO2:F thin film. By readily modulating the surface morphology of ZnO-SnO2:F nanocomposite thin films with the initial ZnO NP surface coverage, the scattering efficiency of the incident light can remarkably be controlled over the 400-1100 nm solar spectrum wavelength range. High quality hazy ZnO-SnO2:F thin layers are therefore formed with an averaged haze factor ranging from 0.4 to 64.2% over the 400-1100 nm solar spectrum range while the sheet resistance is kept smaller than 15 Ω/sq for an average total optical transmittance close to 80%, substrate absorption and reflection included. Eventually, optical simulations using Fourier transform techniques are performed for computing the obtained haze factors and show good agreement with experimental data in the 400-1100 nm solar spectrum wavelength range. This opens up additional opportunities for further design optimization of nanoengineered transparent electrodes.

Thermal annealing effects on silver nanowire networks

Thermal annealing is shown to be a successful approach to reduce the electrical resistance of transparent electrodes made of randomly oriented silver nanowires (AgNWs). A decrease in the electrical resistance by several orders of magnitude, whilst maintaining optical transmission (above 85%), is demonstrated. Several mechanisms involved in the electrical behaviour induced by thermal treatment both in air and under vacuum are identified using a combination of ramped, stepped and isothermal annealing. Some mechanisms lead to the reduction of the electrical resistance such as local sintering, while others, such as spheroidisation, induce irreversible damage to the network. It is also shown that the polymer used in the synthesis of Ag nanowires plays a crucial role as a thermal stabiliser under vacuum conditions. Finally, optimised samples exhibit an optical transmittance of 83% (without substrate contribution removal) and a sheet resistance of 9.5 Ω/sq.

Fluorine doped tin oxide (FTO) thin film as transparent conductive oxide (TCO) for photovoltaic applications

Textured FTO thin films were deposited on corning glass substrates at 420°C by ultrasonic spray pyrolysis method. The electrical, optical and structural properties of the prepared functional FTO thin films were investigated. Homogeneous textured columnar grain morphology was observed through FESEM. As prepared thin films exhibits polycrystalline cassiterite structure with preferred orientation along (200). FTO is a promising TCO as front electrodes of thin film solar cells because of their good electrical properties (4.3×10−4ω.cm) combined with high transmission properties (86%).

Undoped TiO2 and nitrogen-doped TiO2 thin films deposited by atomic layer deposition on planar and architectured surfaces for photovoltaic applications

Undoped and nitrogen doped TiO2 thin films were deposited by atomic layer deposition on planar substrates. Deposition on 3D-architecture substrates made of metallic foams was also investigated to propose architectured photovoltaic stack fabrication. All the films were deposited at 265 degrees C and nitrogen incorporation was achieved by using titanium isopropoxide, NH3 and/or N2O as precursors. The maximum nitrogen incorporation level obtained in this study was 2.9 at. %, resulting in films exhibiting a resistivity of 115 Omega cm (+/-10 Omega cm) combined with an average total transmittance of 60% in the 400-1000 nm wavelength range. Eventually, TiO2 thin films were deposited on the 3D metallic foam template.