Use of positive dispersion mirrors to maintain beam quality during chirped pulse amplification in a Yb:KYW regenerative amplifier

Abstract

Disclosed is a laser system that includes a femtosecond oscillator, a regenerative amplifier for chirped pulse amplification of femtosecond laser pulses, and a compressor. The regenerative amplifier includes a plurality of positive Group Delay Dispersion (GDD) mirrors disposed within a cavity of the regenerative amplifier. The compressor receives amplified laser pulses from the regenerative amplifier.

Claims

1. A laser system comprising: a femtosecond oscillator; a regenerative amplifier for chirped pulse amplification of femtosecond laser pulses, the regenerative amplifier comprising a plurality of positive Group Delay Dispersion (GDD) mirrors disposed within a cavity of the regenerative amplifier; and a compressor that receives an amplified laser pulse from the regenerative amplifier.

Description

(1) FIG. 1 depicts a laser system.

(2) FIG. 2 depicts a regenerative amplifier.

(3) FIG. 3 provides a dispersion curve of positive GDD mirrors utilized in laser cavity.

(4) FIG. 4 provides a comparison of intracavity peak powers of pulses stretched by a Chirped Volume Bragg Grating (CVBG) and Positive GDD mirrors (Chirped Optics).

(5) FIG. 5 provides a mode quality (M2) plot of the laser cavity.

DETAILED DESCRIPTION

(6) FIG. 1 is an overview of a laser system. As shown, the laser system includes a femtosecond oscillator, a regenerative amplifier, and a compressor.

(7) FIG. 2 depicts the components of a regenerative laser amplifier cavity containing positive dispersion mirrors. As shown in FIG. 2, multiple positive Group Delay Dispersion (GDD) mirrors may be utilized throughout the cavity. The coating of the mirrors was custom designed for this application and each one provides ˜4000 fs.sup.2 of dispersion to the input laser pulse per reflection. FIG. 3 provides a dispersion curve of positive GDD mirrors utilized in laser cavity.

(8) The seed laser beam reflects offs the positive GDD mirrors as it cycles through the laser amplifier cavity. During each cycle through the amplifier cavity, or “round trip,” the seed laser pulse is amplified. In order to reach the desired pulse energy, the seed laser must complete numerous round trips. The peak power of the laser pulses as it cycles through the cavity would damage the cavity optics if it was not temporally stretched. The positive GDD mirrors accomplish the stretching and keep the intracavity peak powers at levels comparable to lasers where a chirped volume Bragg grating (CVBG) is used for pulse stretching prior to amplification as shown in FIG. 4.

(9) However, unlike a system utilizing a CVBG, the input and output beam profiles of our laser are not compromised by the stretching and compressing optics. Through the use of the positive GDD mirrors for stretching then compressing by several passes through a single, conventional, transmission grating our beam profile is dependent solely upon our laser amplifier cavity design. The design of which delivers a highly symmetric beam with a mode quality (M2) value less than 1.3 as shown in FIG. 5.

(10) In addition to superior beam quality the use of positive dispersion mirrors also allows for our laser to operate and dynamically switch repetition rate from single-shot to 1 MHz without compromising laser performance (see Table 1 below, which provides laser output energy at operating repetition rates).

(11) TABLE-US-00001 Repetition Rate Max. Energy Peak Power (kHz) (μJ) (MW)   20* 150.0 300.0  40 75.0 150.0  60 50.0 100.0  80 37.5 75.0  100 30.0 60.0  200 15.0 30.0  300 10.0 20.0  400 7.5 15.0  500 6.0 12.0  600 5.0 10.0  700 4.3 8.6  800 3.8 7.5  900 3.3 6.7 1000 3.0 6.0

(12) Finally, as a result of our novel design the laser can operate over a large range of environmental conditions and use models (see Table 2 below, which provides laser specifications of novel ultrafast laser system).

(13) TABLE-US-00002 Wavelength (nm) 1030 (+/−2) Average Power (W) ≥3 (Low Cost Model) Pulse Duration (fs) <500 Repetition Rate (kHz) S5-1000 Mode Quality (M2) <1.35 Pulse to Pulse Stability 1% over 10 minutes Pulse Contrast >20:1 Start Up Time (Warm) 2 minutes Operating Temperature 15 C.-40 C. Humidity 90% noncondensing Cooling Water (closed-loop) Power Requirements 110 V/15 A (50 Hz/60 Hz) Laser Head Dimensions <450 mm × 350 mm × 220 mm Weight (kg) <22