We develop a tightly focused pump-probe absorption technique to study diffusion dynamics of photoexcited carriers.It has many advantages including the simple setup and operations,higher detection sensitivity,an analyt...We develop a tightly focused pump-probe absorption technique to study diffusion dynamics of photoexcited carriers.It has many advantages including the simple setup and operations,higher detection sensitivity,an analytic descriptive model and fast data samplings.Diffusion dynamics are measured twice,separately using two different-sized probe spots,instead of many time-delayed diffusion profiles of a carrier pocket measured using spatially probe-spot scanning.An analytic model is derived to describe diffusion dynamics.Diffusion dynamics in GaAs are measured to demonstrate the feasibility of this technique.The diffusion coefficient is obtained and agrees well with the reported experimental and theoretical results.展开更多
基金Supported by the National Natural Science Foundation of China(Grant Nos.11774438 and 61475195)the National Basic Research Program of China(Grant No.2013CB922403)the Guangdong Basic and Applied Basic Research Foundation(Grant No.2019A1515011572).
文摘We develop a tightly focused pump-probe absorption technique to study diffusion dynamics of photoexcited carriers.It has many advantages including the simple setup and operations,higher detection sensitivity,an analytic descriptive model and fast data samplings.Diffusion dynamics are measured twice,separately using two different-sized probe spots,instead of many time-delayed diffusion profiles of a carrier pocket measured using spatially probe-spot scanning.An analytic model is derived to describe diffusion dynamics.Diffusion dynamics in GaAs are measured to demonstrate the feasibility of this technique.The diffusion coefficient is obtained and agrees well with the reported experimental and theoretical results.
