Articles tagged with Tunable Lasers
Researchers developed an all-flexible, self-cleaning smart window that fine-tunes solar gain in real time and protects against environmental contaminants. The device's multifunctionality could accelerate green building development and address climate change concerns.
Researchers have successfully achieved low-threshold anisotropic polychromatic emission from monodisperse quantum dots by coupling them with microcavities, overcame technical bottlenecks for practical applications. This enables broadband gain, amplification, and even lasing, as well as full-color display and patterning.
Distributed acoustic sensing systems face data processing speed limitations; researchers leverage photonic neural networks to overcome these challenges. The TWM-PNNA system achieves high recognition accuracy above 90% with low power consumption, outperforming electrical GPUs by orders of magnitude.
Researchers developed innovative RE³⁺-doped monolithic glasses capable of tunable full-color emission under NIR laser excitation. These glasses overcome key obstacles faced by existing technologies and demonstrate the potential as materials for dynamic, full-color laser-based volumetric displays.
Researchers have developed a CQD-based SEL array with low lasing threshold, high stability and high integration density of up to 2100 PPI. The new design features a graded alloyed core-shell structure and circular Bragg resonator, resulting in enhanced optical field confinement and Purcell effect.
Scientists have created a new method for quickly detecting and identifying very low concentrations of gases, offering promise for real-time monitoring in environmental, health, and industrial applications. The approach uses a coherent control strategy to enhance the sensitivity of quartz-enhanced photoacoustic spectroscopy.
Researchers propose a novel strategy for highly controllable micro-nano fabrication using focal volume optics in transparent solids. The approach enables the creation of composite structures with finer structures and tunable properties, opening up new avenues for photonics and nanophotonics applications.
Droplets of a specific organic liquid emit laser light when an electric field is applied, demonstrating electrically switchable 'laser pixels.' A 2x3 array of these droplets can be controlled individually for high-density displays.
Researchers developed a method to fabricate high-precision glass grooves using multi-focus laser processing. The approach corrects position deviations and improves energy uniformity, enabling the production of glass grooves with various geometries.
Researchers developed a highly sensitive hydrogen detection system using tunable diode laser absorption spectroscopy (TDLAS) with high selectivity and rapid response. The new method achieved accurate measurements of hydrogen concentrations from 0.01% to 100%, improving the detection limit at longer integration times.
Researchers developed a new spectroscopy method using tunable lasers, enabling precise tracking of the laser's color at every point in time. The technique offers higher power and spectral stability compared to existing methods, making it suitable for various applications including LIDAR and spectroscopy.
Researchers at the University of Rochester developed a new microcomb laser design that provides low power efficiency, high tunability, and easy operation. The simplified approach enables direct control over the comb with a single switch, opening up potential applications in telecommunications systems, LiDAR for autonomous vehicles.
Researchers achieve tunable ultrafast laser state active controlling by utilizing anisotropic quasi-1D material Ta2PdS6. The material enables the sustainment of two distinct laser states: conventional soliton (CS) and noise-like pulse (NLP). Numerical simulation reveals the mechanism behind the switchable laser state.
Researchers successfully fabricate a microlens on a single-mode polarization-stable VCSEL chip using 2-photon-polymerization 3D printing, reducing beam divergence from 14.4° to 3° and enabling compact optical gas sensors with improved performance.
Researchers developed a system to transmit high-capacity terahertz-wave signals to different locations using direct terahertz-optical conversion and fiber-wireless technology, achieving 32 Gb/s capacity. The system overcomes radio communications limitations in the terahertz band, expanding communication coverage.
Researchers at the University of Tsukuba created a liquid droplet-based laser that remains stable under ambient conditions and can be tuned using gas convection. The development enables the creation of flexible optical communication devices with potential applications in airflow detectors and fiber-optics communications.
A team from Nanjing University and Sun Yat-Sen University developed a two-facing Janus OPO scheme for generating high-efficiency, high-purity broadband LG modes with tunable topological charge. The output LG mode has a tunable wavelength between 1.5 μm and 1.6 μm, with a conversion efficiency above 15 percent.
Scientists at EPFL and IBM have developed a new type of laser using lithium niobate, enabling precise distance measurements in LiDAR applications. The hybrid integrated tunable laser offers low frequency noise and fast wavelength tuning.
A new type of optical manipulation has been developed, using laser light to pull macroscopic objects. The researchers designed a graphene-SiO composite structure specifically for laser pulling, which creates a reversed temperature difference when irradiated with a laser beam.
Researchers at Columbia Engineering's Lipson Nanophotonics Group create tunable and narrow-linewidth chip-scale lasers emitting light of different colors, including green, blue, and violet. These inexpensive lasers have the smallest footprint and shortest wavelength of any tunable and narrow-linewidth integrated laser emitting visible ...
Harvard scientists create a high-performance on-chip femtosecond pulse source using a time lens, enabling broadband, high-intensity pulse sources. The device is highly tunable, integrated onto a small chip and requires reduced power compared to traditional table-top systems.
The researchers achieved ultranarrow linewidths and wavelength tunability in the lithium niobate microlaser, enabling applications like lidar and metrology. The single-mode lasing is realized through simultaneous excitation of high-Q polygon modes at both pump and laser wavelengths.
The study compares the behavior of flat (1D), cylindrical (2D) and spherical (3D) micromirrors for free-space light coupling. Silicon micromirrors were fabricated and used to experimentally validate the coupling efficiency in visible and near infrared wavelengths.
Physicists at the University of Warsaw have developed a new type of tunable microlaser that emits two linearly polarized beams, which can be controlled by rotating liquid crystal molecules. The laser has been shown to exhibit unique properties, including circular polarization and phase coherence.
Researchers created a compact and ultrafast high-power yellow laser with excellent beam quality, filling the need for practical yellow light source emitting ultrafast pulses. The laser's wavelength range is highly absorbed by hemoglobin in blood, making it useful for medical treatments, dermatology, and eye surgery.
A new, broad-band tunable infrared laser from Northwestern University offers high-power rapid tuning and has implications for detecting drugs and explosives. The robust, all solid-state laser can be rapidly tuned to capture unique spectral fingerprints of gases.
A Northwestern University team has developed a mid-infrared tunable laser integrated into an on-chip amplifier, demonstrating an order-of-magnitude increase in output power. The new technology allows for adjustable wavelength output, modulators, and amplifiers in a single package, enabling more efficient detection of hazardous chemicals.
Square optical microresonators support whispering-gallery modes, suitable for unidirectional microlasers. Microsquare lasers offer better modulation behaviors and higher output power than microdisk lasers. Mode selection is achieved by adjusting the output waveguide width, enabling continuous tuning of lasing wavelength.
The Curiosity robot has confirmed an episodic increase in methane concentration in Mars' atmosphere, which may indicate the presence of biological activity. The detection is based on detailed analysis of data collected during 605 Martian days and is attributed to the tunable laser spectrometer in the SAM instrument.
A tiny ring laser can detect and count individual nanoparticles with high accuracy, offering a breakthrough in sensing technology. The sensor's effective resolution limit is about one nanometer, making it orders of magnitude more sensitive than earlier passive resonators.
The US Navy is developing a powerful free-electron laser that can transmit infrared light for use in ship-defense systems. The laser has the capability of generating extremely short pulses, sub-picosecond pulses, and breaking records for tunable high-average power lasers.
Researchers at UC Santa Barbara develop world's first tunable photon copier on a chip, enabling efficient data transmission in all-optical networks. The device integrates laser and wavelength converter components, improving signal quality and paving the way for widespread adoption.
Professor Terrill Cool's research uses flame-sampling photoionization mass spectrometry to detect key-reaction intermediates in laboratory flames. The new facility will produce average photon fluxes 100 times larger than current sources, enabling more accurate predictive models of combustion kinetics.