The project delivered several results that advance the state of the art in graphene research and hybrid material design.
A straightforward and efficient photopatterning methodology was established under both liquid and dry conditions, enabling spatially controlled covalent patterning of graphene with high precision. This approach allowed the selective anchoring of different functional groups at desired locations, making it possible to achieve different patterned substrates. These advanced graphene architectures were thoroughly characterized using a suite of state-of-the-art techniques to evaluate their efficiency and surface properties. The nanoscale chemical and structural visualization of the functionalized graphene has also yields the comprehensive information into its surface properties.
A major breakthrough was the demonstration of reversible covalent functionalization, where covalently bound molecules could be selectively removed with the aid of a focused laser, restoring its pristine characteristics without introducing additional defects. Using a correlative approach that combined time-resolved Raman spectroscopy, Electron Diffraction (ED), and Electron Energy Loss Spectroscopy (EELS), the real-time insight into the degrafting process was elucidaded for the first time. This revealed the back-conversion kinetics from sp³ to sp² hybridization and established the foundation for re-usable and sustainable graphene platforms.
Another significant achievement was the first prototype demonstration of a covalently linked graphene–perovskite conjugate system. Detailed optical and structural characterization, including Raman mapping, photoluminescence (PL) spectroscopy, SEM, and synchrotron-based XANES and EXAFS measurements, revealed clear domain-dependent behaviors between van der Waals and covalently bonded interfaces. These findings open new research directions for hybrid materials with tailored optoelectronic properties. However, further research, dedicated technology development, and potential industrial collaborations will be required to advance this type of conjugate system toward practical applications.
Together, these results not only advance the fundamental knowledge of graphene functionalization, restoration, and hybrid materials, but also establish practical methodologies that can support future applications in optoelectronics, sensing, and nanomaterials. At the same time, they provide a solid foundation for developing sustainable and re-usable graphene-based technologies.