轻质高效和高温宽频电磁波吸收材料是现代军事科学长期追求的目标，同时也是电磁污染防护、信息安全和微波成像器件等民用高科技领域重要发展方向。本项目旨在探索原子分子层沉积构筑磁性石墨烯的新方法，可控制作磁性石墨烯异质结构，揭示异质结构生长机理，赋予磁性石墨烯优异的高温电磁特性和微波吸收性能。基于组分协同和界面效应及原子分子层沉积技术，精准剪裁磁性石墨烯异质结构，阐明弛豫、磁共振、电导网络和磁涡流等多重微波响应行为规律和物理本质，建立磁性石墨烯异质结构高温电磁特性的调控策略。本项目预期成果有益于解决磁性石墨烯高温微波响应的共性科学问题，可以为新型吸波材料研发提供科学依据，支撑隐身科学技术发展。同时，本项研究有益于微波成像、微波器件、信息安全与电子对抗、电磁污染与电磁屏蔽等领域科技创新。本项目还具有突出的理论、方法和技术集成创新的实质性，有利于形成交叉创新的学术观点和学术思想，促进多学科发展。

Light-weight and high-efficiency microwave absorbers with broad bandwidth at elevated temperature, is a long sought-after goal of modern military science, significantly directing civilian high-tech fields of electromagnetic pollution and protection, information security and electronic countermeasure, and microwave imaging device. Our project aims at new methods of constructing magnetic graphene heterostructure, as well as the growth mechanism, which endows graphene with excellent electromagnetic properties and microwave attenuation ability at elevated temperature. Based on component synergism, interfacial effect and atomic-molecular layer deposition, our project will open a new way for tailoring magnetic graphene heterostructure precisely, demonstrate multiple microwave response mechanism of multi-relaxation, multi-resonance, conductive network and eddy current, and thereby establishes a new strategy for tuning the electromagnetic properties at elevated temperature. The expected results are beneficial to solve the general science issues of microwave absorbers at elevated temperature, providing scientific basis for developing new types as well as supporting the stealth science and technology of our country. Meanwhile, our results also promote innovation of technology of microwave device, electromagnetic shielding, information security, electromagnetic pollution and disease prevention. More importantly, our project has outstanding features of interdisciplinary combination and integrated innovation, in favor of formation of new academic views.