物理学报2016,Vol.65Issue(23):236801-1-236801-8,8.DOI:10.7498/aps.65.236801
利用石墨烯等离激元与表面声子耦合增强量子摩擦∗
Enhancement of quantum friction via coupling of surface phonon p olariton and graphene plasmons
摘要
Abstract
In our daily life, frictions are very common when two bodies in direct contact relatively move. However, when two bodies are separated by a finite distance, due to the quantum fluctuations inside the bodies, they may still experience a friction when they relatively move. Such a phenomenon is often called quantum friction, which has been studied for more than a decade. It has shown in previous studies that the surface modes, such as surface phonon polaritions (SPhPs) or surface plasmon polaritions (SPPs) have significant contribution to enhancing the quantum friction. However, to the best of our knowledge, the contribution of coupling from SPhPs and SPPs to quantum friction is still unknown. Here, we report a detailed study on the quantum frictions between two graphene sheets with the silicon carbide (SiC) substrates. For comparison, the quantum frictions between two other samples, i.e., SiC/SiC and graphene/graphene are also studied. As indicated in previous studies, SPhPs and SPPs, supported by SiC and graphene, respectively, can couple together in special frequency ranges. The coupling of SPhPs and SPPs can be tuned by varying the chemical potential of graphene. The coupling modes shift toward higher frequency as the chemical potential increases. Firstly, we analyze qualitatively the effects of coupled surface modes on quantum friction with the help of dispersion relation. Secondly, we calculate the quantum friction coefficients numerically for the three different samples. We find that due to the coupling of SPhPs and SPPs, the quantum friction between graphene sheets with SiC substrates is larger than that between the SiC or monolayer graphene sheets. We demonstrate that the coupling of SPhPs and SPPs can be modulated by chemical potential of graphene; therefore, the relationship between quantum friction coefficient and chemical potential is also studied. We observe that with the increase of chemical potential, quantum friction coefficient follows a non-monotonic trend, i.e., it first increases to its maximum value then decreases. We believe that our studies are not only helpful in understanding the micro mechanisms of friction, but also meaningful in the fabrications of micro- and nano-electromechanical systems.关键词
量子摩擦/石墨烯/等离激元Key words
quantum friction/graphene/plasmons引用本文复制引用
张超杰,周婷,杜鑫鹏,王同标,刘念华..利用石墨烯等离激元与表面声子耦合增强量子摩擦∗[J].物理学报,2016,65(23):236801-1-236801-8,8.基金项目
国家自然科学基金(批准号:11264029,11264030)和江西省自然科学基金(批准号:20151BAB202017)资助的课题 (批准号:11264029,11264030)
