Single 5-nm quantum dot detection via microtoroid optical resonator photothermal microscopy

TL;DR

This paper demonstrates a highly sensitive, label-free photothermal microscopy technique using microtoroid optical resonators to detect single 5 nm quantum dots with exceptional signal-to-noise ratio, advancing nanoscale detection capabilities.

Contribution

The study introduces a novel integration of whispering gallery mode microtoroid resonators with photothermal microscopy for single quantum dot detection at 5 nm size, surpassing previous detection limits.

Findings

Detected 5 nm quantum dots with SNR > 10^4

Achieved heat dissipation measurement below dye molecule levels

Enhanced signal stability using PID-controlled pump laser

Abstract

Label-free detection techniques for single particles and molecules play an important role in basic science, disease diagnostics, and nanomaterial investigations. While traditional fluorescence-based methods offer powerful tools for single molecule detection and imaging, they are limited by a narrow range of molecular probes and issues such as photoblinking and photobleaching. Photothermal microscopy has emerged as a label-free imaging technique capable of detecting individual nanoabsorbers with high sensitivity. Whispering gallery mode microresonators can confine light in a small volume for enhanced light-matter interaction and thus are a promising ultra-sensitive photothermal microscopy platform. Previously microtoroid optical resonators were combined with photothermal microscopy to detect 250 nm long gold nanorods. Here, we combine whispering gallery mode microtoroid optical resonators with photothermal microscopy to spatially detect 5 nm diameter quantum dots (QDs) with a signal-to-noise ratio (SNR) exceeding $10^4$. To achieve this, we integrated our microtoroid based photothermal microscopy setup with a low amplitude modulated pump laser and utilized the proportional-integral-derivative (PID) controller output as the photothermal signal source to reduce noise and enhance signal stability. The measured heat dissipation of these 5 nm QDs is below the detectable level from single dye molecules, showcasing the high sensitivity and discrimination capabilities of this platform. We anticipate that our work will have application in a wide variety of fields, including the biological sciences, nanotechnology, materials science, chemistry, and medicine.