Second harmonic generation from nanocrystals under linearly and circularly polarized excitations

Abstract: Abstract:We study second harmonic generation (SHG) from noncentrosymmetric nanocrystals under linearly polarized (LP) and circularly polarized (CP) excitations. Theoretical models are developed for SHG from nanocrystals under both plane-wave and focused excitations. We find that the focused excitation reduces the polarization dependency of the SHG signal. We show that the SHG response under CP excitation is generally inferior to the average of LP excitations over all orientations. We verify the theory by measu… Show more

“…[18][19][20][21][22] SHG is a nonlinear optical process which converts two incident photons at a frequency ω into one photon at frequency 2ω in a noncentrosymmetrical material. 23 Unlike fluorescence, the SHG process only involves the transition between virtual energy states without any nonradiative loss.…”

Single-cell screening and quantification of transcripts in cancer tissues by second-harmonic generation microscopy

“…[18][19][20][21][22] SHG is a nonlinear optical process which converts two incident photons at a frequency ω into one photon at frequency 2ω in a noncentrosymmetrical material. 23 Unlike fluorescence, the SHG process only involves the transition between virtual energy states without any nonradiative loss.…”

Single-cell screening and quantification of transcripts in cancer tissues by second-harmonic generation microscopy

“…This enabled the team of Yuste and Eisenthal to measure the length of the dendritic spine necks in living neurons and to determine that dendritic spines linearize the summation of excitatory potentials [38]. In another promising approach, SHG active surface modifiable non-centrosymmetric nanodoublers [39] have been introduced as a practical alternative to fluorescent molecules and quantum dots, to track processes through in-vitro (cell) imaging [40][41][42][43][44]. These studies clearly demonstrate the unique ability and promising possibilities of SHG microscopy to probe materials and interfaces, identify and quantify histoarchitectural tissue alterations, and to track changes in living systems.…”

High throughput second harmonic imaging for label-free biological applications

“…From [137] we can conclude that the crystal orientation determines whether linearly or circularly polarized light is more efficient for the SHG process. We assume that the WFS process always converges to the optimal polarization state.…”

“…Possible candidates for these probe particles are fluorescent dyes or quantum dots as commonly used for two-photon microscopy [3]. Especially interesting are nanocrystals from wide bandgap materials with a high efficiency for second harmonic generation (SHG) [137][138][139]: Providing a stable and coherent SHG signal, and flexibility for use in a wide spectral range, this class of particles recently gained considerable attention as markers for novel microscopy techniques [140] and makes them ideal probes for WFS experiments.…”

“…For a detailed analysis, the light polarization and the second-order susceptibility tensor needs to be considered. The second-order polarization at the second harmonic frequency can be calculated by the matrix equation [137,143] [143]. Note that the second-harmonic response is independent of a rotation around the z-axis.…”

Spatiotemporal control of light in turbid media