New thin film materials to suit the needs of future energy technology
Titanium dioxide with small amounts of added niobium, TNO, has recently attracted interest as a transparent conductor and as a thermoelectric material that converts waste heat into electricity.
In his doctoral dissertation, Janne-Petteri Niemel盲, doctoral candidate at 911爆料网, discovered an optimal atomic layer deposition method for TNO thin films, demonstrating that the films so fabricated exhibited high-quality transparent conductor properties.
鈥榃e discovered that we need to use sufficiently low deposition temperatures in atomic layer deposition. We managed to reduce the grain-boundary scattering that suppresses electron mobility and weakens electric conductivity,鈥 he explains.
Figure 1. In a layer-structured hybrid thin film, inorganic (e.g. titanium dioxide) and organic layers alternate. Organic layers are fabricated between ALD-based inorganic layers using the molecular layer deposition technique. The thickness of the layers can be controlled to an accuracy of a single atom or molecule layer..
Electricity from heat with hybrid materials
Atomic layer deposition, ALD, is an excellent method for fabricating materials for new energy technologies, as it allows depositing thin film materials for different kinds of nanostructured substrate surfaces according to their geometry.
When the ALD method is combined with the molecular layer deposition (MLD) method, new types of hybrid inorganic-organic materials can be fabricated. In his doctoral dissertation, Niemel盲 also examined the electric and thermal conductivity properties of ALD/MLD-fabricated titanium dioxide- and zinc oxide-based hybrid materials.
鈥業n our study, we discovered that organic molecule layers deposited between oxide layers reduced the thermal conductivity of oxide materials considerably, which is promising in view of thermoelectric applications,鈥 Niemel盲 explains.
In the future, thermoelectric materials can be used for producing electricity from the heat generated by humans for charging portable electronic devices, for example.
鈥楶otential applications for transparent conductors, on the other hand, can be found in solar cells and LED lights,鈥 says Niemel盲.
Figure 2. In polycrystalline thin film materials, the grain boundaries suppress electron mobility and weaken electric conductivity. The grain-boundary scattering was successfully reduced for ALD-based TNO thin films as a result of which the materials work better as transparent conductors.
Thin Films of TiO2 and Related Oxides by ALD/MLD: Tailoring of Transport Properties on luettavissa s盲hk枚isen盲 osoitteessa
Additional information:
Janne-Petteri Niemel盲
janne-petteri.niemela@aalto.fi
Read more news
Arsi Ik盲heimonen鈥檚 doctoral research: Smartphone data could reveal early signs of depression
A phone in your pocket, a smart ring on your finger, and an activity tracker on your wrist: everyday devices collect information about their users almost continuously. This data can help monitor and predict symptoms of depression.
Professor Hironori Yoshida: 鈥淢achines should adapt to materials, not the other way around鈥
Professor of Formgiving believes the future of design lies in embracing irregularity rather than eliminating it. His research combines design, AI and robotics.
President Ilkka Niemel盲 explains what the new vision for higher education and research means for Finland and Aalto
Aalto has the capability and the will to act as a trailblazer in implementing the vision.