We specialize in the precise synthesis and morphological control of Ti nanomaterials across all dimensional scales—from zero-dimensional (0D) dots to complex three-dimensional (3D) architectures. By meticulously tailoring the structural geometry at the nanoscale, we engineer multifunctional building blocks designed to exhibit targeted mechanical, electrical, and catalytic properties for advanced biomedical and technological applications.
Our group utilizes advanced synthesis techniques to develop a diverse library of nanomaterial architectures, each offering unique physical and chemical advantages:
0D Nanoparticles: Isotropic building blocks with high surface-to-volume ratios, providing uniform dispersion, tunable reactive sites, and foundational reinforcement for composite materials.
1D Nanowires & Nanorods: High-aspect-ratio structures ideal for directional stress transfer. These architectures act as robust microscopic bridges, creating continuous conductive or electroactive networks within softer matrices.
2D Nanoplates: Planar nanostructures offering massive specific surface areas. They maximize interfacial contact, serving as excellent load-bearing elements, micro-capacitors for charge distribution, and highly active planes for surface functionalization.
3D Hierarchical Nanoflowers: Complex, multi-layered biomimetic structures. Their intricate geometry provides an exceptionally high density of active edge sites, making them optimal for catalytic processes and advanced cell-material interactions.

We strategically integrate these dimensionally tailored nanomaterials to solve complex engineering and clinical challenges:
- Advanced Nanocomposite Fillers: Incorporating highly dispersed 0D, 1D, and 2D Ti nanomaterials into polymer and hydrogel matrices to dramatically enhance their mechanical robustness, structural integrity, and long-term stability in physiological environments.
- Amplified Piezoelectric Systems: Utilizing anisotropic structures (specifically 1D nanorods and 2D nanoplates) to maximize stress transfer and amplify the electroactive output of piezoelectric composites for mechanotransduction, guided tissue regeneration, and flexible bioelectronics.
- Photocatalytic & Antimicrobial Activity: Exploiting the massive active surface areas of 3D nanoflowers and targeted nanostructures for highly efficient reactive oxygen species (ROS) generation under specific light wavelengths, driving robust antimicrobial, anti-biofilm, and environmental remediation applications.