High resolution LASER SPECTROMETER based on broadly tunable CW laser model TIS-FD-08/A-scan
Computer-controlled high resolution SPECTROMETER based on broadly tunable CW
laser model TIS-FD-08/A-scan -
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Del Mar Photonics presents new unique fully computerized powerful laser
spectrometer for research studies demanding fine resolution and high spectral
density of radiation within UV-VIS-NIR spectral domains.
This fully automated high-resolution spectrometer based on Tekhnoscan's CW
narrow-line Ti:Sapphire laser, model TIS-FD-08/A-scan, comes as a perfect
embodiment of modern ideas and technology innovation in the field of smart laser
spectrometers. Novel advanced design of the fundamental laser component
implements efficient intra-cavity frequency doubling as well as provides a
state-of-the-art combined ultra-wide-tunable Ti:Sapphire & Dye laser covering a
super-broad spectral range between 275 and 1100 nm.
The spectrometer includes, as its base, a CW ultra-wide-tunable narrow-line
laser, high-precision wavelength meter, an electronic control unit driven
through USB interface as well as a software package. Positions of wavelength
selection components in the laser as well as the position of the non-linear
crystal are precisely controlled with the help of a closed-loop feed-back system
including a wavelength meter. The spectrometer is fully controllable through a
user-friendly computer interface that offers a variety of modes for setting and
scanning of the radiation wavelength as well as different modes of data
acquisition and recording.
The TIS-FD-08/A-scan features LabWindows™ based software running under Windows™
XP/Vista. For acquisition of experimental data an 8-channel 14-bit ADC is used
with quantisation frequency of 3 MHz and channel multiplexing frequency 3 MHz.
The spectrometer is designed for wide-range spectral studies and
characterization of quantum semiconductor structures, meta-materials,
bio-objects as well as for nano-, bio-technological applications, and quality
control.
Laser Spectrometer Specifications -
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Light source
CW Ti:Sapphire laser 1)
CW Ti:Sapphire laser with intra-cavity frequency doubling 2)
CW Dye laser 3)
CW Dye laser with intra-cavity frequency doubling 4)
Wavelength range
1) 680 - 1100 nm
2) 390 - 550nm/680 - 1100nm
3) 550 - 700 nm
4) 275 - 350nm/550 - 700nm
Output power
up to 4 W in the ranges 550 - 770 / 680 - 1100 nm
up to 500 mW in the ranges 275 - 350 / 390 - 550 nm
Radiation linewidth less than 0.001 nm (1 GHz) / 0.05 nm
Wavelength accuracy 0.001 nm / 0.01 nm
Scanning modes: smooth scanning / step-scan
Data channels
One 8-channel 14-bit ADC
One 12-bit DAC
6 input ports
4 output ports
Accessories (optional)
notebook
laser power meter
UV-IR viewer
extra dye circulation unit
pump laser
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Del Mar Photonics, Inc.
4119 Twilight Ridge
San Diego, CA 92130
tel: (858) 876-3133
fax: (858) 630-2376
sales@dmphotonics.com
www.dmphotonics.com
Example of the research conducted with high resolution SPECTROMETER based on broadly tunable CW laser model TIS-FD-08/A-scan at Drexel University
In single- and multi-component nano-scaled materials for efficient energy
harvesting and energy storage, the influences of finite size, shape, hierarchal
complexity and a dynamic surface chemical environment on properties extend well
beyond the constraints posed by traditional materials-specific property closures
of individual material components. In the Mesoscaled Materials Laboratory (MML)
we investigate the synthesis and selected properties of single- and
multi-component inorganic nanostructured and thin-film materials and devices. We
are currently investigating:
functional properties of ferroelectric nanostructures and their surface chemical
environment, with applicability in memory, sensing, in nanoelectromechanical and
photovoltaic energy harvesting, and in other energy-related areas
development of novel synthetic pathways for multi-component nanostructures for
electronic and photonic devices
electronic transport in low-dimensional semiconductor and metallic materials and
devices, including resonant coupling (and scattering) of electromagnetic
radiation with (and by) nanowires
resonant energy transfer between nanostructures, and its applion in proximal
scanning probes
the physical properties of selected nano-laminate solids and thin films