Fermi level-tuned optics of graphene for attocoulomb-scale quantification of electron transfer at single gold nanoparticles.
Qing XiaZixuan ChenPengwei XiaoMinxuan WangXueqin ChenJian-Rong ZhangHong-Yuan ChenJun-Jie ZhuPublished in: Nature communications (2019)
Measurement of electron transfer at single-molecule level is normally restricted by the detection limit of faraday current, currently in a picoampere to nanoampere range. Here we demonstrate a unique graphene-based electrochemical microscopy technique to make an advance in the detection limit. The optical signal of electron transfer arises from the Fermi level-tuned Rayleigh scattering of graphene, which is further enhanced by immobilized gold nanostars. Owing to the specific response to surface charged carriers, graphene-based electrochemical microscopy enables an attoampere-scale detection limit of faraday current at multiple individual gold nanoelectrodes simultaneously. Using the graphene-based electrochemical microscopy, we show the capability to quantitatively measure the attocoulomb-scale electron transfer in cytochrome c adsorbed at a single nanoelectrode. We anticipate the graphene-based electrochemical microscopy to be a potential electrochemical tool for in situ study of biological electron transfer process in organelles, for example the mitochondrial electron transfer, in consideration of the anti-interference ability to chemicals and organisms.
Keyphrases
- electron transfer
- single molecule
- label free
- gold nanoparticles
- high resolution
- room temperature
- high speed
- walled carbon nanotubes
- carbon nanotubes
- atomic force microscopy
- high throughput
- living cells
- optical coherence tomography
- loop mediated isothermal amplification
- oxidative stress
- mass spectrometry
- multidrug resistant