FemtoFiber pro SCIR

Supercontinuum Pulsed Fiber Laser

Broadband infrared fiber laser source: 980 - 2200 nm
Octave spanning continuum generated by HNLF
SAM mode locking, PM fiber based MOPA system
Compact footprint, < Letter/A4 format
Robust and reliable design, push button operation

The FemtoFiber pro SCIR comprises a very robust MOPA system with an octave-spanning supercontinuum generation (980 – 2200 nm) in one single box. The broadband continuum emission is generated by a Highly-nonlinear fiber (HNLF) and can be altered by the built-in motorized prism compressor, for an optimization to individual need

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Specification

Wavelength range of continuum	980 -2200 nm
Average output power	> 150 mW (typ. 200 mW)
Repetition rate	80 MHz standard*

Additional Information

Long wavelength part (magnified)

Short wavelength part (magnified)

Supercontinuum spectrum (full range)

FemtoFiber pro Control Unit: Push ON/OFF button only, key-lock switch, interlock capabilities, 12 inch rack housing including interfaces, driver electronics for pump diodes and power supplies

Graphic user interface based on LabVIEW. Software control features: Built-in power PC for system control, easy communication through web browser, access to motorized controls (such as variable pulse compression), LabVIEW routines available for system integration

Options

M40: Repetition rate 40 MHz instead of standard 80 MHz

Oscillator design with 40 MHz repetition rate
Some specifications may change (contact us for details)
Cannot be combined with VAR option

Mxx: Customized repetition rate, e.g. 68 MHz, 77 MHz, …

AMP: Multi-Beam Systems

Extension system equipped with amplifier, but no oscillator („AMP“)
FC/APC fiber input for external seeding by the master system
Additional seed ports can be added to each master
Allowing multi-beam system of up to 4 units
Combination of all FemtoFiber pro variants possible

Popular multi-beam systems:

MASTER Model	AMP 1 Model	Purpose
NIR	TNIR AMP	CARS laser source
NIR	UCP AMP	Broadband CARS source
IR	SCIR AMP	OPCPA seeder system
TVIS	TVIS AMP	Pump-probe spectroscopy

VAR: Variable repetition rate

Adaptation to the oscillator unit, enabling modulation of the repetition rate
Adjustable resonator length by fast control piezo transducer, resonance frequency > 1 kHz
Slow control based on motorized stage, tuning range typ. 200 kHz (± 100 kHz to nominal repetition rate)

LRC: Laser repetition rate control

Phase-locked loop electronics for synchronization of the laser pulse train to an external reference signal or a reference laser system
RMS jitter < 200 fs
Compact electronics rack with power supply
USB interface and control software

Additional seed ports for future multi-beam setups

Applications
- Mid-IR Generation (in combination with FemtoFiber pro SCIR/multiple beam configuration)
- Optical Coherence Tomography (OCT)
- Metrology
Downloads
Literature
- Article: L.v. Grafenstein et al., 5 μm few-cycle pulses with multi-gigawatt peak power at a 1 kHz repetition rate, Optics Letters 42 (2017)
- Proceedings Article: Lang, M. et al., Technology and applications of ultrafast fiber lasers (Proceedings of SPIE Vol. 8330, 833007, 2012)
- Online Article: Dimitri Basov, Martin Wagner et al: How to control superfast surface plasmons
- Application Note: Time-resolved photoluminescence spectroscopy
- Preußler, S. et al. Generation of ultra-narrow, stable and tunable millimeter- and terahertz- waves with very low phase noise, Opt. Express 21, 23950–23962 (2013)
- Kaptan, Y. et al. Gain dynamics of quantum dot devices for dual-state operation, Applied Physics Letters 104, 261108 (2014).
- Paar, M. et al. Remodeling of Lipid Droplets during Lipolysis and Growth in Adipocytes. J. Biol. Chem. 287, 11164–11173 (2012).
- Liu, S., Mahony, T. S., Bender, D. A., Sinclair, M. B. & Brener, I. Mid-infrared time-domain spectroscopy system with carrier-envelope phase stabilization. Appl. Phys. Lett. 103, 181111 (2013).
- Benz, A. et al. Strong coupling in the sub-wavelength limit using metamaterial nanocavities. Nat. Commun. 4, (2013).
- Amenabar, I. et al. Structural analysis and mapping of individual protein complexes by infrared nanospectroscopy. Nat. Commun. 4, (2013).
- Marangoni, M. et al. Fiber-format CARS spectroscopy by spectral compression of femtosecond pulses from a single laser oscillator. Opt. Lett. 34, 3262–3264 (2009).
- Keilmann, F. & Amarie, S. Mid-infrared Frequency Comb Spanning an Octave Based on an Er Fiber Laser and Difference-Frequency Generation. J. Infrared Millim. Terahertz Waves 33, 479–484 (2012).
- Wagner, M. et al. Ultrafast Dynamics of Surface Plasmons in InAs by Time-Resolved Infrared Nanospectroscopy. Nano Lett. 14, 4529–4534 (2014).
Related Products
- FemtoFErb SC
- FemtoFiber pro NIR
- FemtoFiber pro IR
- FemtoFiber pro IRS-II
- FemtoFiber pro UCP
- FemtoFiber pro TVIS

Beam divergence	< 1 mrad
Beam size (1/e²)	typ. Ø 2.4 mm
Beam shape	TEMoo, M² < 1.2
Linear polarization	> 95 %, horizontal
Output coupling	Free space
Dimensions laser head (H x W x D)	151 x 280 x 229 mm³
Weight laser head	< 10 kg
Dimensions control unit (H x W x D)	140 x 235 x 315 mm³
Weight control unit	< 4.5 kg
Power supply	100 to 240 VAC, 50/60 Hz, IEC 60320-C14 socket
Power consumption	< 40 W
PC Interface	Ethernet, USB, RS-232
Environment temperature	20 - 30 °C (operating), 0 - 40 °C (storage and transport)
Environment humidity	Non-condensing