Optics (physics.optics)

Abstract: Zero-index materials (ZIMs) have become popular because of their unique optical behaviors, such as infinite effective wavelengths and spatially uniform electromagnetic distributions. The all-dielectric ZIMs, Dirac-like cone-based zero-index materials (DCZIMs) are used in various photonic applications owing to their superior optical properties, such as finite impedances, zero Ohmic losses, and high compatibility with photonic circuits. We propose a more general and simple approach that is independent of the Dirac-like cone mode for realizing near-zero index (NZI) behavior in all-dielectric waveguides. This approach can be applied to various dielectric materials up to the necessary NZI bandwidth. Si3N4 and Ge NZI waveguides are demonstrated for achieving broadband and narrowband NZI, respectively. The proposed broadband NZI waveguide achieves a bandwidth of 140 nm for neff < 0.1 (neff = effective refractive index) at telecommunication wavelengths, which is 2 times larger than that of the reported NZI waveguides. Further, NZI waveguide-based beam steering was demonstrated with a wide steering range delta theta 105 degrees across the radiation angle of theta 0 degree. The proposed NZI-waveguide design principle and beam steering present a feasible approach for the development of photonic circuits and zero-index-based photonic applications.

Abstract: Dispersion is an important factor of optical materials. Due to the effect of techniques and equipment in the manufacturing process of optical materials, the inhomogeneity of the material may be caused. In this paper, microsphere optical media are used to replace the inhomogeneous zones, and Huygens'principle is used to study the dispersion caused by the material inhomogeneity. First, we study the effect of a single inhomogeneous zone, and then the effect of a thin medium with a large number of inhomogeneous zones. It is deduced that the dispersion law of a macro-optical medium is also consistent with Cauchy formula. Finally, it is pointed out that Huygens'principle is suitable for studying the interaction between light and particles.

Abstract: Spintronic THz emitters have attracted much attention due to their desirable properties, such as affordability, ultra-wideband capability, high efficiency, and tunable polarization. In this study, we investigate the characteristics of THz signals, including their frequency, bandwidth, and amplitude, emitted from a series of heterostructures with ferromagnetic (FM) and nonmagnetic (NM) materials. The FM layer consists of a wedge-shaped CoFeB layer with a thickness of 0 to 5 nm, while the NM materials include various metals such as Pt, Au, W, Ru, Pt$_{\%92}$Bi$_{\%8}$, and Ag$_{\%90}$Bi$_{\%10}$ alloys. Our experiments show that the emitter with Pt-NM layer has the highest amplitude of the emitted THz signal. However, the PtBi-based emitter exhibits a higher central THz peak and wider bandwidth, making it a promising candidate for broadband THz emitters. These results pave the way for further exploration of the specific compositions of Pt$_{1-x}$Bi$_{x}$ for THz emitter design, especially with the goal of generating higher frequency and wider bandwidth THz signals. These advances hold significant potential for applications in various fields such as high-resolution imaging, spectroscopy, communications, medical diagnostics, and more.

Abstract: Here we report on a study exploring the design of nanoparticles that can enhance their laser refrigeration efficiency for applications in levitated optomechanics. In particular, we developed lanthanide-doped nanocrystals with an inert shell coating and compared their performance with bare nanocrystals. While optically levitated, we studied the refrigeration of both types of nanoparticles while varying the pressure. We found that the core-shell design shows an improvement in the minimum final temperature: a fourth of the core-shell nanoparticles showed a significant cooling compared to almost none of the bare nanoparticles. Specifically, We measured a core-shell nanoparticle cooling down to a temperature of 147 K at 26 mbar in the underdamped regime. Our study is a first step towards engineering nanoparticles that are suitable for achieving absolute (centre-of-mass and internal temperature) cooling in levitation, opening new avenues for force sensing and the realization of macroscopic quantum superpositions.

Abstract: Epsilon-near-zero (ENZ) metamaterials represent a powerful toolkit for selectively transmitting and localizing light through cavity resonances, enabling the study of mesoscopic phenomena and facilitating the design of photonic devices. In this experimental study, we demonstrate the feasibility of engineering and actively controlling cavity modes, as well as tuning their mutual coupling, in an ENZ multilayer structure. Specifically, by employing a high-birefringence liquid crystal film as a tunable nanocavity, the polarization-dependent coupling of resonant modes with narrow spectral width and spatial extent was achieved. Surface forces aparatus (SFA) allowed us to continuously and precisely control the thickness of the liquid crystal film contained between the nanocavities and thus vary the detuning between the cavity modes. Hence, we were able to manipulate nanocavities anti-crossing behaviors. The suggested methodology unlocks the full potential of tunable optical coupling in epsilon-near-zero metamaterials and provides a versatile approach to the creation of tunable photonic devices, including bio-photonic sensors, and/or tunable planar metamaterials for on-chip spectrometers.

Abstract: Common path interferometers (CPI) are significant due to their compactness and vibration resistance. The usual challenge in CPI would arise due to a very small separation between reference and sample beams, where sending a reference beam through a sample is considered as a limitation. But this limitation also makes it difficult to probe the interaction of beams with material as a function of their phase structure. This study can pave the way for a new kind of interferometry that can provide unique phase signatures to study the sample. The paper proposes and demonstrates a novel approach based on thermo-optic refraction, to send both beams through the sample and probe the phase deterioration due to the relative interaction of beams in the material medium. Here, thermo-optic refraction interferometry (TORI) allows the superposition of a higher order vortex beam with a non-vortex beam through the phenomenon of thermal lensing. The non-vortex beam is made to expand in a controlled fashion by another laser. The relative interaction of the expanding non-vortex beam and the vortex beam within the sample, results in the output interferogram. The phase deterioration analysis of the output interferogram elucidate medium driven phase changes. This technique is demonstrated using the milk samples by recording the RMS azimuthal phase deterioration of the OAM beam.

Abstract: Ultrabroadband electro-optic sampling with few-cycle optical pulses is known to be an extremely sensitive technique to detect electric field amplitudes. By combining this method with dual-comb spectroscopy and with a new class of ultrafast lasers, we perform high-resolution (<10 MHz, 0.0003 wavenumbers) spectroscopic measurements across the whole frequency range of 1.5 to 45 THz (6.6-200 microns) with an instantaneous spectral coverage exceeding an octave (e.g., 9-22 microns). As a driving source, we use a pair of highly mutually-coherent low-noise frequency combs centered at 2.35 microns produced by mode-locked solid-state Cr: ZnS lasers. One of the two combs is frequency downconverted via intrapulse difference frequency generation to produce a molecular sensing comb, while the second comb is frequency doubled to produce a near-IR comb for electro-optic sampling (EOS). An ultra-low intensity and phase noise of our dual-comb system allows capturing a vast amount of longwave spectral information (>200,000 comb-mode spectral lines) at up to a video rate of 69 Hz and with the high dynamic range limited by the shot noise of the near-IR EOS balanced detection. Our long-wavelength IR measurements with low-pressure gases: ethanol, isoprene, and dimethyl sulfide reveal spectroscopic features that had never been explored before.