Identifying the Nano Interface Through Phase

The quantum dots (QD) interface in solution can play significant roles in electron transfer dynamics for quantum dots-sensitized solar cells and different biological, environmental, and industrial systems. Here, we predict an avenue to identify the contribution of the quantum dots interface created static electric field on the nonlinear optical response (NLO) due to four-wave mixing (FWM), especially for the nanoparticles where surface contribution is high. We implement a way to disentangle the FWM response in QDs originating from the three incoming oscillating laser fields (NLOoscillating) and a contribution (NLOstatic) arising from the three oscillating laser fields and the static electric field caused by the interface. Advanced two-dimensional electronic spectroscopy (2DES) employs phase-resolved heterodyne techniques where FWM response is measured in a particular phase-matched direction, and the response is distinctively phase sensitive. Theoretical analysis shows alteration in the interface can introduce phase variation in the NLOstatic signal, resulting in a distinct change in the 2D-spectra. Our studies establish a range of ionic strength, which can be important to untwine the usual NLO signal (NLOoscillating) from the NLO (NLOstatic) contributed by the interface of quantum dots. This analysis may open up the possibility to study the different kinds of dynamics occurring specifically in the interface and also will pave the path towards different ion interactions through phase change in 2D spectra, and enormous scope will be employing deep learning-assisted phase recognition.