- Nov. 21, 2024
- Vol. , Issue (2024)
- Nov. 21, 2024
- Vol. , Issue (2024)
- Nov. 21, 2024
- Vol. , Issue (2024)
- Nov. 19, 2024
- Vol. 12, Issue 10 (2024)
- Nov. 19, 2024
- Vol. 12, Issue 10 (2024)
In this paper, we experimentally investigate the tuning characteristics of laser modes for an ultrahigh-Q Er3+-doped microbottle resonator (MBR) based on
In this paper, we experimentally investigate the tuning characteristics of laser modes for an ultrahigh-Q Er3+-doped microbottle resonator (MBR) based on the whispering gallery mode (WGM). Thanks to the optimized Er3+ doping technique, the laser threshold could be as low as 70 µW. Benefiting from the abundant axial modes and radial modes of the MBR, our experiments demonstrate that the number of laser modes can be flexibly controlled by varying the pump power, adjusting the coupling positions along the axis of the MBR, as well as modifying the coupling diameter of the tapered fiber. The laser mode switching is performed from single-mode to multimodes. Furthermore, different from the traditional external tuning method, we propose a simple and stable approach for continuous wavelength tuning of the laser mode based on the thermal effect associated with the high Q MBR. By precisely adjusting the pump laser wavelength, the emitted laser wavelength can be tuned over a range of 0.102 nm with a high linearity of 99.96%. The engineering of laser mode switching and precise wavelength tuning of the Er3+-doped MBR is expected to have promising applications in miniature tunable single-mode lasers, laser precision measurement, and so on.show less
- Nov.20,2024
- Chinese Optics Letters,Vol. 22, Issue 12
- 121406 (2024)
In the field of short-range optical interconnects, the development of low-power-consumption, ultrawideband on-chip optical waveguide amplifiers is of crit
In the field of short-range optical interconnects, the development of low-power-consumption, ultrawideband on-chip optical waveguide amplifiers is of critical importance. Central to this advancement is the creation of host materials that require low pump power and provide ultrabroadband emission capabilities. We introduce a tri-doped lanthanum aluminate glass (composition: 5Er2O3-5Yb2O3-0.2Tm2O3-43.8La2O3-46Al2O3), which exhibits exceptional near-infrared (NIR) luminescence intensity, significantly outperforming other bands by 3 orders of magnitude. This glass can achieve an ultrawideband NIR gain spanning 478 nm, from 1510 to 1988 nm. Notably, the glass achieves positive optical gain with a low population inversion threshold (P > 0.2), highlighting its efficiency and low-power consumption. The high glass transition temperature (Tg ∼ 842°C) and large temperature difference (ΔT ∼ 120°C) between Tg and the onset of crystallization (Tx) indicate excellent thermal stability, which is crucial for producing high-quality amorphous films for on-chip amplifiers. This research examines the unique energy levels and spectral properties of the Er3 + -Yb3 + -Tm3 + tri-doped glass, assessing its potential for use in ultrawideband on-chip optical waveguide amplifiers. This work lays the groundwork for low-power, ultrabroadband on-chip waveguide amplifiers, offering new avenues for short-range optical interconnect systems.show less
- Nov.19,2024
- Advanced Photonics Nexus,Vol. 3, Issue 6
- 066013 (2024)
We reported on an efficient high-power continuous-wave laser operation on the 3H4 → 3H5 transition of Tm3+ ions in a diffusion-bonded composite YVO4/Tm:Gd
We reported on an efficient high-power continuous-wave laser operation on the 3H4 → 3H5 transition of Tm3+ ions in a diffusion-bonded composite YVO4/Tm:GdVO4 crystal. Pumped by a laser diode at 794 nm, a maximum output power of 7.5 W was obtained from a YVO4/Tm:GdVO4 laser at 2.29 μm, corresponding to a slope efficiency of 40.3% and exceeding the Stokes limit. To the best of our knowledge, this result represents the maximum power ever achieved from a Tm laser at 2.3 μm.show less
- Nov.19,2024
- High Power Laser Science and Engineering,Vol. 12, Issue 5
- 05000e63 (2024)
An interventional fiber optic strategy, as a representative optical medical technology, is flexible, highly sensitive, minimally invasive, and anti-electromagnetic and has good biosafety. Fiber
An interventional fiber optic strategy, as a representative optical medical technology, is flexible, highly sensitive, minimally invasive, and anti-electromagnetic and has good biosafety. Fiber optics can approach deep cancer lesions and provide direct theranostics, which other optical technologies cannot achieve. However, the realization of cancer sensing and therapy relies on the functionalization of optical fibers, which requires the strict selection and optimization of functional materials used to modify the optical fibers, ensuring high photothermal conversion efficiency without affecting fluorescence detection efficiency. Herein, we propose the use of black phosphorus, which does not interfere with fluorescence and provides a safer and more efficient photothermal effect compared to other nanomaterials, such as graphene, graphene oxide, carbon nanotubes, and MXene. We developed a fiber-optic theranostic probe that combines nitroreductase (NTR) fluorescent molecules and a black phosphorus/gold nanostar (BP/AuNS) nanomaterial hydrogel to develop an integrated strategy for cancer sensing and photothermal therapy (PTT). The sensor has high sensitivity, and the limit of detection (LOD) is 1.61 ng mL-1. BP/AuNS fibers have excellent photothermal effects, and the probe temperature reached 212°C in air as 150 mW of pump power was delivered. In the phantom test, the simulation and test results showed that the fiber probe conferred hyperthermia (>45°C) to an area with a radius of 2.5 mm. These results indicate that the minimally invasive BP/AuNS fiber exhibits excellent sensing performance and high photothermal efficiency, making it promising for tumor diagnosis and treatment and potentially advancing the development of optical fiber medicine.show less
- Nov.20,2024
- Chinese Optics Letters,Vol. 23, Issue 5
- (2025)
Nonlinear compression experiments based on multiple solid thin plates are conducted in an ultra-high peak power Ti:Sapphire laser system. The incident laser pulse, with an energy of 80 mJ and a
Nonlinear compression experiments based on multiple solid thin plates are conducted in an ultra-high peak power Ti:Sapphire laser system. The incident laser pulse, with an energy of 80 mJ and a pulse width of 30.2 fs is compressed to 10.1 fs by a thin-plate based nonlinear compression. Significant small-scale self-focusing (SSSF) is observed as ring structures appears in the near-field of the output pulse at high energy. Numerical simulations based on the experimental setup provide a good explanation for the observed phenomena, offering quantitative predictions of the spectrum, pulse width, dispersion, and near- and far-field distributions of the compressed laser pulse.show less
- Nov.20,2024
- High Power Laser Science and Engineering
Low-density polymer foams pre-ionized by a well-controlled nanosecond pulse are excellent plasma targets to trigger direct laser acceleration (DLA) of electrons by sub-picosecond relativistic la
Low-density polymer foams pre-ionized by a well-controlled nanosecond pulse are excellent plasma targets to trigger direct laser acceleration (DLA) of electrons by sub-picosecond relativistic laser pulse. In this work, the influence of the ns pulse on DLA process is investigated. The density profile of plasma generated after irradiating foam with ns pulse was simulated with a two-dimensional hydrodynamic code, which takes into account the high aspect ratio of interaction and the microstructure of polymer foams. The obtained plasma density profile was used as input to the 3D PIC code to simulate energy, angular distributions and charge carried by the directional fraction of DLA electrons. The modelling shows good agreement with experiment and in general a weak dependence of the electron spectra on the plasma profiles, which contain density up-ramp and region of near critical electron density. This explains the high DLA stability in pre-ionized foams, which is important for applications.show less
- Nov.20,2024
- High Power Laser Science and Engineering
Confronting the escalating global challenge of counterfeit products, developing advanced anticounterfeiting materials and structures with physical unclonable functions (PUFs) becomes imperative.
Confronting the escalating global challenge of counterfeit products, developing advanced anticounterfeiting materials and structures with physical unclonable functions (PUFs) becomes imperative. All-optical PUFs, distinguished by their high output complexity, and expansive response space, offer a promising alternative to conventional electronic counterparts. For practical authentications, the expansion of optical PUF keys usually involves intricate spatial or spectral shaping of excitation light using bulky external apparatus, which largely hinders the applications of optical PUFs. Here, we report a plasmonic PUF system based on heterogeneous nanostructures. The template-assisted shadow deposition technique was employed to adjust the morphological diversity of densely packed metal nanoparticles in individual PUFs. Transmission images were processed via a hash algorithm, and the generated PUF keys with a scalable capacity from 2875 to 243401 exhibit excellent uniqueness, randomness, and reproducibility. Furthermore, the wavelength and the polarization state of excitation light are harnessed as two distinct expanding strategies, offering the potential for multi-scenario applications via a single PUF. Overall, our reported plasmonic PUFs operated with the multi-dimensional expanding strategy are envisaged to serve as easy-to-integrate, and easy-to-use systems, and promise efficacy across a broad spectrum of applications, from anti-counterfeiting to data encryption and authentication.show less
- Nov.20,2024
- Advanced Photonics Nexus,Vol. 4, Issue 1