功能化石墨烯基纳米材料（FGNS）是近年来新兴的二维薄膜材料，具有优异的结构、导电及生物相容性，有望成为干细胞培养和组织再生工程支架的首选基质材料。但目前已有FGNS支架尚不能做到微电流和光电磁场一体化介入细胞生长，故无法实现对细胞生长的分化调控。本项目将在二维材料及高性能光伏器件前期研究基础上，探索以石墨烯复合Si p-n结光伏材料，合成新型等离激元增强型石墨烯优化光电芯片。内容包括：在p-n结迎光面通过快速氧化去表面态新工艺、覆以单层n型石墨烯形成光电增益层；以电场精密调节PS小球模板结合蒸镀Au形成等离激元周期阵列；在PS@Au小球上组装还原氧化石墨烯小片、并进行生物相容性链接，作为细胞培养基底； 用芯片产生的光致微电流与等离激元增强的极化光电磁场相耦合，达到调控干细胞生长与分化的目的。这一研究成果不仅将在生物学领域有着广泛的应用前景，也可为新型高效光伏材料的研发提供新思路。

Functionalized graphene-based nanomaterials (FGNS) are emerging two-dimensional thin-film materials in recent years. Their excellent structure, conductivity and biocompatibility are expected to be the matrix materials of the first choice for stem cell culture and tissue regeneration scaffolds. However, the currently available FGNS scaffolds have not been able to achieve the integration of micro-current and photoelectromagnetic field for cell growth, and thus can not achieve the differentiation regulation in the growth process. In this project, based on the previous research on 2D materials and high-performance photovoltaic devices, we will explore a new type of plasmonic enhancement optimized graphene optoelectronic chip based on graphene composite Si p-n junction photovoltaic materials. The surface of the p-n junction is covered with a single layer of n-type graphene to form a photoelectric gain layer by a rapid oxidation to dedusting surface state technology. The PS pellets template is precisely adjusted with an electric field and evaporated to form a plasmonic periodic Au holes array; The pellets are assembled by the small pieces of reduce graphene oxide and are biocompatible linked to serve as a substrate for cell culture. With the chip generated micro photocurrent coupling to the plasmonic enhanced polarized electromagnetic field, to achieve the purpose of regulating stem cell growth and differentiation. This research will not only have broad application prospects in the field of biology, but also provide new ideas for the research and development of new and efficient photovoltaic materials.