📣 Meet us at SPIE. Defense + Security 2026! 

April 28-30, 2026 | National Harbor, MD | Booth # 731

High-Res Retinal Imaging Made Simpler: 830 nm SLED for OCT

Retinal OCT systems in ophthalmology demand stable broadband light for sharp axial resolution without swept-source complexity. This OSE1 configuration (ASM002408) from Dayy Photonics is an 830 nm Single-SLED, delivering >5 mW SM fiber-coupled power, >35 nm FWHM bandwidth (810–850 nm coverage), integrated TEC stabilization, monitor photodiode, and zero polarization dependence. This yields cleaner interferograms, higher-contrast images, and drop-in OEM integration in a compact 14-pin butterfly package with FC/APC output.

Explore specs for your OCT system:

Versatile Performance Over the NIR Spectrum: 700-1400 nm Lasers

From DPSS pumping and medical imaging to LIDAR and industrial processing, the near-IR band continues to power some of the most practical photonics applications. RPMC’s extensive lineup includes high-power LDX multimode diodes (up to 12.8 W fiber-coupled), compact fiber lasers, and DPSS systems at key wavelengths like 808 nm, 980 nm, 1030 nm, and 1064 nm. The payoff is efficient absorption, flexible integration, and rugged solutions tailored to your exact power and beam needs.

Browse our full 700-1400 nm selection:

Surviving the Final Frontier: Lasers for Space Applications

Space missions throw radiation, vacuum, thermal swings, and vibration at every component. RPMC provides a selection of rugged & robust laser options designed to perform in the harshness of space. From fiber lasers to diodes and DPSS sources, engineered with low-SWaP designs, radiation hardening, and hermetic packaging, our devices are successfully proven on missions like OSIRIS-REx and LEO constellations. Reliable FSOC links, planetary LIDAR, atmospheric sensing, CubeSat navigation... still working when it matters most.

Learn more about our space-proven laser options:

DNA Origami: Single-Photon Emitter Positioning

An international team led by Skoltech researchers has used DNA origami to position single-photon emitters with 13 nm accuracy in two-dimensional materials like MoS₂, as reported in Light: Science & Applications. Triangular DNA structures carrying thiol groups create point traps that emit single photons under laser excitation, with over 90% positioning yield and nanosecond lifetimes. Detailed in the article, this breakthrough could enable scalable quantum light sources for computing and secure communication.