- Kuo, Yung;
- Li, Jack;
- Michalet, Xavier;
- Chizhik, Alexey;
- Meir, Noga;
- Bar-Elli, Omri;
- Chan, Emory;
- Oron, Dan;
- Enderlein, Joerg;
- Weiss, Shimon
We optimized the performance of quantum-confined Stark effect (QCSE)-based voltage nanosensors. A high-throughput approach for single-particle QCSE characterization was developed and utilized to screen a library of such nanosensors. Type-II ZnSe/CdS-seeded nanorods were found to have the best performance among the different nanosensors evaluated in this work. The degree of correlation between intensity changes and spectral changes of the exciton's emission under an applied field was characterized. An upper limit for the temporal response of individual ZnSe/CdS nanorods to voltage modulation was characterized by high-throughput, high temporal resolution intensity measurements using a novel photon-counting camera. The measured 3.5 μs response time is limited by the voltage modulation electronics and represents ∼30 times higher bandwidth than needed for recording an action potential in a neuron.