申请人拟结合TPP(Tamm Plasmon Polariton)微纳激光和超表面相位全息图来制造一种微观尺寸的，可以进行光束整形的高效激光光源。TPP谐振腔由布拉格反射镜和金属上反射面组成，如果在谐振腔的金属上反射面上集成超表面相位图，该相位图的形状与分布将用来对激光出射光进行调制，达到原位激光光束整形的效果。我们计划采用理论分析、数值仿真和实验验证相结合的方法，研究超表面全息图对TPP微纳激光整形的物理机理，实现对微纳激光的光束整形；研究金属超表面全息图对TPP微纳激光的调制效率，激光谐振腔品质因素(Quality factor, Q)的影响；探索TPP微纳激光结合超表面全息调制技术；展开以TPP微纳激光和超表面全息调制图结合产生的新型激光为光源的片上光电子器件应用研究。此项研究的创新点和优越性体现在有机结合了微纳光源和超表面全息调制技术，为片上光电子器件的光源打开了新的可能性。

The applicant intends to combine micro/nano Tamm Plasmon Polariton(TPP) laser and meta-surface hologram to produce an efficient laser source with micrometer scale and beam shaping ability. The TPP resonator consists of a Bragg reflector and an up metal reflecting surface. If a meta-surface phase hologram is integrated on the up metal surface of the resonator, the shape and phase distribution of the meta-surface hologram can modulate the laser beam to achieve an efficient in-situ laser beam shaping. We plan to combine theoretical analysis, numerical simulation and experimental verification to study the physical mechanism of meta-surface hologram on micro/nano laser beam shaping, to achieve micro/nano laser beam shaping, to study the modulation efficiency of metal meta-surface hologram on micro-nano laser, the influence of laser resonator quality factors(Q), and to explore micro/nano laser combined with super-surface hologram modulation technology. And also study the application of on-chip optoelectronic devices using micro/nano laser with meta-surface hologram integrated as light source. The innovations and advantages of this research are embodied in the combination of micro/nano light source and meta-surface holographic modulation technology, which opens new possibilities for the light source of on-chip optoelectronic devices. The ultimate goal of this project is a set of on-chip optical communication system based on the new light source, which uses the degrees of freedom introduced by meta-surface hologram modulation to improve the bandwidth and efficiency of optical communication system, and to make technical reserve for the next generation optical communication systems.