Femtosecond Laser 1560nm High Power Pulsed Fiber Laser.
Features:
Pulse width 120 fs
Average laser power 1W
Self start maintenance free
high stability
Applications:
optical frequency comb
Supercontinuum spectrum
Terahertz wave
Ultrafast laser phenomenon
parameters
Wavelength :1560±10nm
Pulse width :<120fs (customizable )
Output power :>1W(customizable )
Power instability :< ±1%
Repetition rate : 100Hz(customizable )
Single pulse energy:> 10 nJ
Beam quality: M2<1.2TEM00
Beam diameter: ≤ 1.6mm
Beam divergence angle: mradmrad
Polarization state :linear polarization PER>20dB
Output mode :Spatial light
Beam divergence angle: mradmrad
Synchronous electrical signal interface:SMA
Electricity Desktop: AC 110~240VAC
Desktop Size:330(W)×398(D)×112(H)
Operating temperature:5 ~ 35°C
1. Intensity VS Time
2. Optical Spectrum of 1560nm fs pulsed Fiber Laser at 1W
3. Power Spectral Density VS Wavelengths
Femtosecond lasers focus the energy on a very short time scale within a single laser pulse. That leads to high peak powers which are far beyond power peaks achievable by continuous wave lasers. Delivering ultrafast high intensive laser output opens new possibilities for all kind of laser applications.
The word femtosecond is formed by the SI prefix femto and the SI unit second. Its symbol is fs. A femtosecond is equal to 1000 attoseconds, or 1/1000 picosecond. Because the next higher SI unit is 1000 times larger, times of 10−14 and 10−13 seconds are typically expressed as tens or hundreds of femtoseconds.
A femtosecond laser is a type of laser that emits ultrashort pulses of light with durations on the order of femtoseconds, where one femtosecond is equal to 10-15 seconds. These lasers are capable of generating extremely high peak powers and are widely used in various scientific, medical, industrial, and technological applications due to their unique properties.
Ultrashort pulse duration: Femtosecond lasers emit pulses with durations typically ranging from a few femtoseconds to hundreds of femtoseconds. These ultrashort pulses enable precise control and manipulation of material properties on timescales comparable to molecular and electronic interactions.
High peak power: Despite their short pulse durations, femtosecond lasers can deliver extremely high peak powers due to their concentrated energy within each pulse. This high peak power allows for nonlinear optical effects such as multiphoton absorption, harmonic generation, and filamentation.
Broadband spectrum: Femtosecond pulses often have broad spectral bandwidths, spanning from ultraviolet (UV) to near-infrared (NIR) wavelengths. This broad spectrum enables a wide range of nonlinear optical processes and applications across different wavelength regimes.
Precision and accuracy: Femtosecond lasers offer exceptional precision and accuracy in material processing, micromachining, and laser surgery due to their ability to remove material with minimal heat-affected zones and collateral damage.
Nonlinear optical effects: Femtosecond lasers are capable of inducing various nonlinear optical effects, including two-photon absorption, self-phase modulation, and optical parametric amplification. These effects find applications in nonlinear microscopy, frequency metrology, and ultrafast spectroscopy.
Mode-locking and modelocking: Many femtosecond lasers operate in mode-locked or modelocked configurations, where the laser cavity is designed to produce a train of ultrashort pulses with high repetition rates. Mode-locked femtosecond lasers are widely used in ultrafast science and technology.
Applications of femtosecond lasers span a wide range of fields, including:
Materials processing: Femtosecond lasers are used for precision micromachining, surface structuring, drilling, cutting, and welding of materials with high precision and minimal thermal damage.
Medical and biomedical applications: Femtosecond lasers are employed in laser eye surgery (LASIK), cataract surgery, corneal reshaping, tattoo removal, and various medical imaging techniques.
Scientific research:Femtosecond lasers are used in ultrafast spectroscopy, time-resolved imaging, coherent control of molecular dynamics, attosecond science, and studies of fundamental processes in physics, chemistry, and biology.
Telecommunications and optical communications: Femtosecond lasers are used in optical communications systems for high-speed data transmission, signal processing, and wavelength-division multiplexing (WDM) applications.
