With the new “LightHUB+” and “LightHUB Ultra” laser light engines, laser- and LED specialist Omicron provides higher flexibility in the world of Microscopy and Biotechnology.
Omicron‘s innovative „LightHUB+” and “LightHUB Ultra” laser light engines represent a new form of laser light source for science and research.
The high-performance systems can be equipped with one to six (LightHUB+) / seven (LightHUB Ultra) laser modules of different wavelengths from UV to the near IR range and offer fast analogue intensity modulation with up to 1,5MHz and digital full ON/OFF modulation with a switching time of <1µs for each channel.
The individual laser modules can easily be exchanged and added by the user. Hence the systems can be adapted to changing application requirements and are future-proof.
With a direct and active temperature control of the laser modules and the complete laser bed it is now possible to keep the power level ultra-stable. This feature guarantees reliable and repeatable results in the customer’s applications.
The light of the various lasers is combined and coupled efficiently into one (LightHUB+) or up to two (LightHUB Ultra) polarization-maintaining single-mode broadband or multi-mode fibres.
The LightHUB Ultra additionally offers the possibility to integrate a fast fibre-switch or fibre splitter with defined splitting ratio.
Laser modules with up to 300 milliwatt of optical output power and wavelengths between 375 and 850nm can be used in the “LightHUB” systems. Optional clean-up filters and a fail safe laser safety shutter can be directly installed in the system to adapt the “LightHUB” system to the customer’s application and safety requirements.
High-impedance modulation inputs ensure easy interfacing to external devices like cameras, microscopes or DAC cards.
The device can be conveniently controlled via the integrated USB-2.0 interface by the included software „Omicron Control Center“ or third party software. Typical applications include microscopy, fluorescence analysis and the use as multispectral light source in analytical processes.
The new “LightHUB+” and “LightHUB Ultra” laser light engines will be presented at Photonics West 2019 exhibition, held in San Francisco, CA – USA from Feb. 5-7, 2019 at booth no. 2163 and are already available.
Further information on Omicron laser products can be found at www.omicron-laser.de
Since 1989, Omicron has been developing, building and producing innovative laser systems. With a highly qualified team Omicron specialized in customized solutions for applications in the fields of medicine, research, biotechnology, such as microscopy and flow cytometry, digital imaging and optical data storage as well as quality assurance and measurement engineering. Product development and production comply with European and US guidelines. A broad band of laser sources in the range of UV VIS/IR is available to satisfy individual customer requirements. Omicron offers single light sources as well as complete system solutions. Omicron pursues the objective of being an industry leader in product development and has not only set trends in laser technology but also has drawn worldwide attention with its developments.
Omicron-Laserage Laserprodukte GmbH, Raiffeisenstr. 5e, 63110 Rodgau
Pressekontakt: PR Solutions by Melanie Schacker, Bsuch 241, A-5760 Saalfelden Telefon +43 678 129 27 25, E-Mail email@example.com
Melanie Schacker | Omicron - Laserage Laserprodukte GmbH
2020 Hannover Messe Preview: New hearts for fuel cells: Fraunhofer IWU is researching future-oriented serial production
12.02.2020 | Fraunhofer-Gesellschaft
Microtechnologies for Optical Devices: Special exhibition area at W3 shows solutions for optics, electronics, mechanics
11.02.2020 | IVAM Fachverband für Mikrotechnik
The operational speed of semiconductors in various electronic and optoelectronic devices is limited to several gigahertz (a billion oscillations per second). This constrains the upper limit of the operational speed of computing. Now researchers from the Max Planck Institute for the Structure and Dynamics of Matter in Hamburg, Germany, and the Indian Institute of Technology in Bombay have explained how these processes can be sped up through the use of light waves and defected solid materials.
Light waves perform several hundred trillion oscillations per second. Hence, it is natural to envision employing light oscillations to drive the electronic...
Most natural and artificial surfaces are rough: metals and even glasses that appear smooth to the naked eye can look like jagged mountain ranges under the microscope. There is currently no uniform theory about the origin of this roughness despite it being observed on all scales, from the atomic to the tectonic. Scientists suspect that the rough surface is formed by irreversible plastic deformation that occurs in many processes of mechanical machining of components such as milling.
Prof. Dr. Lars Pastewka from the Simulation group at the Department of Microsystems Engineering at the University of Freiburg and his team have simulated such...
Investigation of the temperature dependence of the skyrmion Hall effect reveals further insights into possible new data storage devices
The joint research project of Johannes Gutenberg University Mainz (JGU) and the Massachusetts Institute of Technology (MIT) that had previously demonstrated...
Researchers at Chalmers University of Technology, Sweden, recently completed a 5-year research project looking at how to make fibre optic communications systems more energy efficient. Among their proposals are smart, error-correcting data chip circuits, which they refined to be 10 times less energy consumptive. The project has yielded several scientific articles, in publications including Nature Communications.
Streaming films and music, scrolling through social media, and using cloud-based storage services are everyday activities now.
After helping develop a new approach for organic synthesis -- carbon-hydrogen functionalization -- scientists at Emory University are now showing how this approach may apply to drug discovery. Nature Catalysis published their most recent work -- a streamlined process for making a three-dimensional scaffold of keen interest to the pharmaceutical industry.
"Our tools open up whole new chemical space for potential drug targets," says Huw Davies, Emory professor of organic chemistry and senior author of the paper.
12.02.2020 | Event News
16.01.2020 | Event News
15.01.2020 | Event News
19.02.2020 | Life Sciences
19.02.2020 | Information Technology
19.02.2020 | Power and Electrical Engineering