CRDS User meeting Cork University, sept-2006 High resolution cavity-enhanced absorption spectroscopy with a mode comb. T. Gherman, S. Kassi, J. C. Vial, N. Sadeghi, D. Romanini Laboratoire de Spectrométrie Physique, CNRS UMR5588, Univ. J. Fourier de Grenoble, St Martin d Hères, France
Research at LSP/Grenoble Spectroscopy molecules of amospheric interest (O 3, CH 4, CO 2 ) : ICLAS 0.6-1.1µm, CW- CRDS in the telecom range Alain Campargue, Samir Kassi (poster) Isotope effects (in NO 2 ) : LIF, CRDS on a supersonic jet Remy Jost Trace detection Near-mid IR : DFB diode lasers & OF-CEAS Blue spectral range ECDL diode + OF-CEAS Marc Chenevier Irene Courtillot (poster) New developments Mode-Comb CEAS : Detecting radicals in the UV? VECSEL lasers (~2.5µm)... Daniele Romanini
Introduction Several CRDS/CEAS schemes exist based on different light sources. Increasing interest for Broad Band coverage for several applications. Pulsed dye lasers, lamps, LEDs, and mode-locked femtosecond sources being tested. BB CEAS/CRDS: Need to do a compromise dispersion/luminosity: The more you disperse, the less light you have per spectral element, the longer you have to accumulate. Other problem is spectral quality and stability of the BB source: Dye lasers and lamps are not very good, contrary to LEDs and ML lasers. ML lasers have high beam quality (mode matching ), and adjustable spectrum (width & spectral range) by using nonlinear optics (fibers, etc)
Standard CEAS scheme with laser tuning LASER Sample gas detector Transmission laser frequency
Wavelength Multiplexed Spectroscopy Broad-band LASER modelocked Sample gas CCD array Transmission laser frequency
What is a mode-locked laser? Laser cavity ( very simplified! ) ( ) Gain + Non-linear (Kerr) Medium (Ti:Sa) Output coupler Laser at work ( ) Intracavity giant pulse self-sustained by Kerr lensing Output : periodic series of pulse replicas! http://www.mpq.mpg.de/~haensch/comb/research/combs.html
Spectrum of a mode-locked laser... coherent ensemble of single-frequency lasers Time domain : Periodic train of pulses δt Δt 1/δt Mode spacing 1/Δt Fourier T. => Spectrum of mode-locked laser in a real case (laser Ti:Sa) the spectrum has ~10 5 modes
Spectrum of a mode-locked laser... coherent ensemble of single-frequency lasers Time domain : Periodic train of pulses δt Δt 1/δt Mode spacing 1/Δt Fourier T. => Spectrum of mode-locked laser in a real case (laser Ti:Sa) the spectrum has ~10 5 modes
Spectrum of a mode-locked laser - A closer look - http://www.mpq.mpg.de/~haensch/comb/research/combs.html
ML-CEAS : Basic principle Cavity transmission spectrum Modelocked laser spectrum Output Spectrum = T cav x Input Spectrum The spectrum transmitted by the cavity depends on the overlap of the two combs of modes : by changing the cavity length, we observe comb beatings, with different periods When combs are in tune, the laser spectrum is efficiently transmitted without beatings => Magic point
Pulse stacking : The time-domain point of view Pulses overlap in phase with circulating intracavity pulse : buildup occurs and transmission is efficient! E. R. Crosson et al., REV. SCI. INSTRUM. 70 (1999) 4
An alternative point of view in the time domain Laser pulses fall in phase with the pulse circulating in the cavity, which gives a coherent buildup of the intracavity field. This is similar to the singlefrequency case (CW-CRDS) but the buildup is not a stationary wave ( )
Comparison with the case of a lonely pulse No coherent buildup, instead a decreasing sequence of output pulses is produced (ring-down...), with initial intensity < T 2 Cavity injection is much less effective... ( ) ( ) ( ) 1/T 1/T 2
CEAS with a Mode-Locked laser Millennia pump laser, 5W Ti:Sa 100fs, 80Mhz optical isolator L 1 Photodiode PinHole M 2 M 1 L 2 PZT Translation stage Spectrograph M 1,2 : high reflectors around 800 nm CCD
Beating between mode combs 3.0 1.5 0.0 4 2 0 1000 μm 500μm Transmitted spectra for different displacements of cavity length from the «magic point» ( smaller peaks are from transverse cavity modes ) 20 10 0 150 μm 2000 1000 0 848 849 850 851 852 853 854 855 Wavelength [nm] 00 μm
Cavity transmission ( while slowly tuning its length ) 0.15 0.10 150 μm 0.50 distance from 0.25 0.00 40 μm «magic point» 1.0 0.5 0.0 10 «magic point» 20 μm NOTE: When looking at these signals on a fast timescale, one can recover the pulse train again... 5 0 00 μm 0 1 2 3 4 Time [ms] Cavity length tuning by a PZT
Why we see more than one comb resonances? f=0 frequency Laser emission 1 2 3 1 3 2 fine cavity tuning by piezo These secondary resonances have different intensity: An effect of dispersion To obtain spectra in transmission, one may either modulate the cavity around a resonance, or use a locking scheme
ML-CEAS : A first demonstration laser spectrum Spectrum transmitted by cavity filled with air Spectrum transmitted by cavity filled with HCCH 857 858 859 860 861 862 nm Effective absorption length F x L /π 120 m Acquisition time ~ 10 ms ( cavity length was modulated ) T. Gherman and D. Romanini, Optics Express, 10, 1033 (2002).
Going to the UV Doubled YAG pump laser, 5W Ti:Sa 100fs, 80Mhz PM gas out gas in BBO L 1 HR M 2 M1 L 2 + - CCD PZT Spectrograph Translation stage BBO : doubling crystal HR : high reflector for cutting the red M 1,2 : high reflectors for 370-420 nm PM : photomultiplier
ML-CEAS : Application in the blue Empty cavity... Ti:Sa frequency doubled laser : Overtone transition of HCCH with 8 quanta of CH excitation (420 nm) Cavity Finesse ~ 3000 Intensity TRSMISSION (a.u.)...with acetylène Noise ~ 10 8 / cm Acquisition ~ 30 s, (using a basic frequency-locking scheme) Absorbance [10-7 /cm] 5 4 3 2 1 0...ratio & baseline correction 23760 23780 23800 23820 23840 23860 T. Gherman, S. Kassi, A. Campargue, D. Romanini Chem. Phys. Letters 383 (2004) 353
ML-CEAS : N 2 discharge
Band 0-0 of N 2 + (B 2 Σ u + -X 2 Σ g+ ) 20000 Discharge on Discharge off Intensity ( CCD counts ) 15000 10000 5000 Continuous discharge in 1 Torr N 2 Cavity: R=98%, L=920 cm, F~150 => L eq ~ 50 m Recording time on CCD ~ 10 s 0 1000 800 600 400 200 0 Pixel number
1.00 Band 0-0 of N 2 + (B 2 Σ u + -X 2 Σ g+ ) Transmittance 0.99 0.98 0.97 spin-doubling Resolution ~ 2E-3 nm ( 0.16 cm -1 ) Discharge CW 1 Torr N 2 Cavity: Finesse ~ 150 Exposure time ~ 10 s Simulation : 400 C, 1.6E15 ions/m 3 389.0 389.5 390.0 390.5 391.0 391.5 wavelength(nm) T. Gherman, E. Eslami, D. Romanini, J.-C. Vial, N. Sadeghi, J Phys D 37 (2004) 2408
Multiplex CEAS : ML-lasers versus Lamps (or LEDs) Both sources are sufficiently smooth spectrally ML laser emission is highly coherent : SPATIALLY (TEM00 mode) => Cavity mode-matching high cavity injection efficiency reproducible & accurate absorption measurements TEMPORALLY (mode comb) => Cavity comb-locking further gain in injection Lamps easily provide a larger emission spectrum : Low resolution due to low spectral density and low cavity injection, and to the limited number of spectral elements on a CCD Less expensive (except for electric consumption?)
ML-CEAS, conclusions & perspectives Robust, simple, multiplex technique Real-time, high sensitivity (2x10-9 /cm/hz 1/2 ) Quantitative (calibration of cavity finesse by ringdown) => UV (efficient femtosecond pulse frequency upconversion) Small sample volume Frequency locking of combs allows short acquisition times even with high finesse cavities Effects of cavity dispersion (e.g. from mirrors) can be circumvented on relatively large spectral ranges (~>10nm) by using a small cavity modulation