Advanced electronic materials and devices group

The group specialise in experimental design and optimisation of a broad range of novel functional oxides at different length scales including bulk ceramics, thin films, superlattices and low-dimensional nanostructures for nanoelectronic, photonic and energy-related applications. We have been at the forefront of understanding the processing techniques/conditions that control the materials properties, improving the performance of existing materials, and exploring new functionalities and their related device applications.

Key research activities

• Processing of high-performance lead-free dielectric/ferroelectric/piezoelectric thin films by physical vapour deposition. 
• Novel materials design strategies to overcome the common problems encountered in electrocaloric compounds, thus dramatically enhancing the electrocaloric cooling efficiency.
• Tailoring functionality epitaxial oxide perovskite thin films/heterostructures using epitaxial strain and built-in electric field.
• Design and development of highly efficient visible light photocatalysts and pyro/mechano bi-catalysts for treatment of dye wastewater.
• Bandgap tuning in lead-free oxide perovskites for efficient photovoltaic effect.
• Oxide-semiconductor integration for next generation nanoelectronics.
• Rational design of high-performance 1D piezoelectric nanomaterials through nanostructure engineering for nanogenerator applications.
• Understanding the structure-physical properties relationship of functional oxides through nuclear magnetic resonance spectroscopy.
• Development of environmentally friendly piezoceramics having giant dynamic piezoresponse for smart actuators and displacement devices.
• Development of high-resolution 2D phased array ultrasonic transducers for real-time 3D medical imaging.

Team

Selected publications

L Zhang, HY Wang, D Wang, MY Guo, XJ Lou and DY Wang†, A New Strategy for Large Dynamic Piezoelectric Responses in Lead‐Free Ferroelectrics: The Relaxor/Morphotropic Phase Boundary Crossover, Advanced Functional Materials, 2004641 (2020)

MB Ghasemian, A Rawal, Z Shahrbabaki, Q Zhang, T Lu, Y Liu and DY Wang†, Evidence of phase coexistence in hydrothermally synthesized K0.5Na0.5NbO3 nanofibers, Journal of Materials Chemistry A 8, 8731 (2020)

SE Shirsath, C Cazorla, T Lu, L Zhang, YY Tay, XJ Lou, Y Liu, S Li and DY Wang†, Interface-charge induced giant electrocaloric effect in lead free ferroelectric thin-film bilayers, Nano Letters, 20, 1262 (2020)

Y Sun, L Zhang, HY Wang, MY Guo, XJ Lou and DY Wang†, Composition-driven inverse-to-conventional transformation of electrocaloric effect and large energy storage density in strontium modified Ba (Zr0.1Ti0.9)O3 thin films, Journal of Materials Chemistry C 8, 1366-1373 (2020)

SE Shirsath, XX Liu, MHN Assadi, A Younis, Y Yasukawa, SK Karan, J Zhang, JH Kim, DY Wang†, A Morisako, Y Yamauchi, S Li, Au quantum dots engineered room temperature crystallization and magnetic anisotropy in CoFe2O4 thin films, Nanoscale Horizons 4, 434 (2019)

MB Ghasemian, A Rawal, Y Liu and DY Wang†, Approaching Piezoelectric Response of Pb-Piezoelectrics in Hydrothermally Synthesized Bi0.5(Na1–xKx)0.5TiO3 Nanotubes, ACS Applied Materials and Interfaces 10, 20816 (2018)