Group theory analysis of phonons in monolayer chromium trihalides and their Janus structures.

A contrastive investigation of the symmetry aspects of phonons in monolayer chromium trihalides and their Janus structures Y3-Cr2-X3 (X, Y = F, Cl, Br, I) was presented within group theory. We classified all phonon vibration modes at the Brillouin-zone center (Γ) into irreducible representations. The infrared and Raman activity of optic phonons, Raman tensors, and the possible polarization assignments of Raman active phonons are further predicted. We clarify the discrepancy concerning the Raman and infrared activity of optic modes in monolayer CrI3. It is also found that the Raman and infrared spectra are exclusive for X3-Cr2-X3 but coincident for Janus Y3-Cr2-X3. This distinction plays a vital role in optic spectra identification of the Janus Y3-Cr2-X3 monolayer from the X3-Cr2-X3 monolayer. To demonstrate the origin of phonon chirality and magnetism intuitively, we derive the symmetry-matched phonon eigenfunctions and the corresponding schematic representations of the eigenvectors for both the F3-Cr2-I3 and I3-Cr2-I3 monolayers. Our analysis indicates that the spin-phonon coupling, the magneto-optical effect of infrared and Raman active phonons, and the phonon chirality could be observed in the Janus Y3-Cr2-X3 monolayer more easily than in the X3-Cr2-X3 monolayer. Our results thus provide a detailed guiding map for experimental identification and characterization of the Janus Y3-Cr2-X3 monolayer.

Deterministic approach to the generation of modified helical beams for optical manipulation.

We present a deterministic method to generate modified helical beams which create optical vortices with desired dark core intensity patterns in the far-field. The experiments are implemented and verified by a spatial light modulator (SLM), which imprints a phase function onto the incident wavefront of a TEM00 laser mode to transform the incident beam into a modified helical beam. The phase function can be calculated once a specific dark core shape of an optical vortex is required. The modified helical beam is exploited in optical manipulation with verification of its orbital angular momentum experimentally.