Multiplexed Detection of CO 2 using a Novel Dual-Comb Spectrometer A. J. Fleisher , 1 D. A. Long, 1 J. T. Hodges, 1 D. F. Plusquellic 2 1 National Institute of Standards and Technology, Gaithersburg, MD, USA 2 National Institute of Standards and Technology, Boulder, CO, USA
Multiplexed Detection of CO 2 using a Novel Dual-Comb Spectrometer A. J. Fleisher, 1 D. A. Long, 1 J. T. Hodges, 1 D. F. Plusquellic 2 1 National Institute.
Jan 05, 2016
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Multiplexed Detection of CO2 using a Novel Dual-Comb Spectrometer
A. J. Fleisher,1 D. A. Long,1 J. T. Hodges,1 D. F. Plusquellic2
1National Institute of Standards and Technology,Gaithersburg, MD, USA
2National Institute of Standards and Technology,Boulder, CO, USA
Multiplexed approach to spectroscopy
• Multiplexing• acquiring data on all available optical channels
simultaneously• increase acquisition speed
• Fast Scanning• digital control of laser frequency• electro-optic modulators
• Traditional Scanning• thermomechanical tuning• laser current tuning• mechanical laser cavity length tuning
Dave LongMJ02
Experimental overview
Gas Sample
RF Detuning
Ampl
itude
PD
RSA
Generating an EOM comb
−+
6dB
<10 kHz – 18 GHz
Dual-Drive MZM
<6 Vrms
• Fiber-coupled waveguide EOMs
• Large tenability (20 GHz)
• Low Vπ
• Generate optically flat combs
• Up to 700 comb modes
OFC generation
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
Changing the mode spacing is limited by the tuning speed of our microwave sources (≤ 100 µs)
Optical frequency combs
Menlo Systems FOFC
OFC from EOM of a CW laser
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
www.menlosystems.com
Sacrifice on bandwidth
Gain in power per comb mode
Targeted molecular sensing
Toptica, Thorlabs, IMRA …
Multimode cavity coupling
wC+d+wf
wC+d
cavityresonances
Comb spacingscanning
wf
D.A. Long et al., Appl. Phys. B 114, 489 (2014)
Multiheterodyne spectroscopy
Local Oscillator (LO)fn,LO = nfmod + f0
Probefn,Probe = n(fmod + δfmod
)
+ f0 + fAOM
Heterodyne RF Signalfn,RF = nδfmod
+ fAOM
f0 = 193 THzfmod = 203 MHzδfmod
= 24 kHz
fAOM = 99 MHz
Optical Detuning
RF Detuning
Ampl
itude
Ampl
itude
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
Technical drawing
PD
EC
ECDL
FS FS
MZMLO
MZMprobe
AOMsample
AOMref
SampleFC
FC
FL
FL
FALocal Oscillator + Probe
andLocal Oscillator + Reference
Detector reveals two rf combs
𝑇=𝐼𝐼 0
=exp (−𝛼 𝐿)
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
FSLock (5%)
Down-converted rf spectrum
𝑇=𝐼 probe𝐼ref
=exp (−𝛼𝐿 )
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
MH-CEAS of CO2
PCO2 = 14 Pa
Finesse = 20,000FSR = 203 MHz
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
10,000 spectra in 30 seconds
single element NEA = 310-10 cm-1 Hz-1/2
Ruggedized spectrometer
MH-DAS
PCO2 = 13.3 kPa
L = 80 cm totalwww.wavelengthreferences.com
Fiber-coupled multipass cell
single element NEA = 410-6 cm-1 Hz-1/2
D.A. Long et al., Opt. Lett. 39, 2688 (2014)
Ruggedized spectrometer
AOMs
Multipass cell
MZMs
PD
Pump laser
Frequency comb applications
EOM
Step
-sca
n
Step
-sca
n
Electro-optic
mod. combs
T.J. Kippenberg et al. Science, 332, 555-559 (2011).
EOM
Mini-comb applications
Electro-optic
modulator c
ombs
Frac
tiona
l ban
dwid
th (Δ
λ/λ)
Mode spacing (Hz)
Nonlinear spec.Targeted sensing
Cavity GDD
Molecular dispersion
Electro-optic
modulator c
ombs
Frac
tiona
l ban
dwid
th (Δ
λ/λ)
Mode spacing (Hz)
Nonlinear spec.Targeted sensing Cavity GDD
Mini-comb applications
www.maps.google.com www.usmint.gov
Laser size?
Molecular disp.
A. Bartels et al. Science 326, 681 (2009)
Summary of method
• Low cost• An order of magnitude cheaper than competing technologies• Does not require a highly trained user
• Digital control of comb spacing and power leveling
• High power per comb tooth
• Built-in reference channel
• Common mode signals (no need for complicated locking)
Acknowledgements
MMLDavid Long
Katarzyna BielskaJoseph Hodges
PMLKevin Douglas
Stephen MaxwellDavid Plusquellic
NIST Innovations in Measurement Science (IMS) award
NIST Greenhouse Gas Measurements and Climate Research Program
Insert title here
Multiplexed detection schemes
Dispersive
Fourier transformMultiheterodyne
S.A. Diddams et al., Nature 445, 627 (2007)
I. Coddington et al., Phys. Rev. Lett. 100, 013902 (2008)J. Mandon et al., Nature Photon. 3, 99 (2009)
Streak Camera
M.J. Thorpe et al., Science 311, 1595 (2006)
Mach-Zehnder modulator
−+
6dB
<10 kHz – 18 GHz
Dual-Drive MZM
<6 Vrms Control of both amplitude and phaseFlatten output over many sideband orders
Up to 700 comb modes from ONE cw laser!
MZM references here. Detuning (GHz)
Tran
smis
sion
PCH4 = 16 kPa
L = 20 cmfmod = 20 MHztacq = 2 ms
1.0
0.0-6.5 6.5
FARS experimental setup
TTL trigger
RF source (0 – 70 GHz)
ECDL
EOM 2
PDH servo
ring-down cavity
signalacquisition
PD2
PD1
probe leg
lock leg
PBSPBS
p-pols-pol
switch
EOM 1
PDH lock beam
2f PDH error signal
Cavity modes
2f lock
D. A. Long et al., Appl. Phys. B, (2013)
Experimental Overview
(c)Local Oscillator (LO)
fn,LO = nfmod + f0
Probefn,Probe = n(fmod + δfmod
)
+ f0 + fAOM
Heterodyne RF Signalfn,RF = nδfmod
+ fAOM
Optical Detuning
RF Detuning
Ampl
itude
Ampl
itude
(b)
−+
6dB
<10 kHz – 18 GHz
Dual-Drive MZM
<6 Vrms
(a)
Laser
AOM
AOM
MZM
MZMPD
FS FSFC
FC
Gas Sample
Local Oscillator
Reference
Probe
ECDL FS FS
Gas Sample
PDFC
FC
AOM
AOMMZM
MZM
A
Laser FS FS
Gas Sample
FC
FC
AOM
AOM
EOM
EOM
PD
Technical Illustrations 1 and 2
Argument for multiplexing
• Traditional Scanning• Fast Scanning• Multiplexing
Down-convert the optical frequency comb spectrum to radiofrequencies using another optical frequency comb.
Multiheterodyne Cavity-Enhanced Absorption SpectrosocpyMH-CEAS
Femtosecond optical frequency combHall and Hänsch, 2005 Nobel Prize Optical frequency comb
Frequency domain
Time domain
Single pulse Train of pulses
S. T. Cundiff, J. Ye, and J. L. Hall, Scientific American, April 2008
Frequency comb application
N.R. Newbury, Nature Photonics 5, 186 (2011).
Book ChaptersFemtosecond Laser Spectrosocpy,ed. P. Hannaford, Springer (2005).
Femtosecond Optical Frequency Comb Technology, eds. J. Ye and S.T. Cundiff, Springer (2005).
Select ReviewsA. Schliesser et. al. Nature Photonics, 6, 440 (2012).
F. Adler et. al. Annu. Rev. Anal. Chem., 3, 175 (2010).
us!
EC
ECDL
FS FS
EOM1
EOM2
AOM2
AOM1
SampleFC
FC PD
FA
Technical Scheme 3
Frequency Comb Applications
Electro-optic
modulator c
ombs
Frac
tiona
l ban
dwid
th (Δ
λ/λ)
Mode spacing (GHz)
Targeted sensing
Non-linear spec.
Molec. disp.
Mirror disp. Telecom
Potential application
• Environmental Monitoring: monitor carbon dioxide and other greenhouse gas emissions to facilitate accurate assessment of impacts on global climate change and carbon mitigation.
• Safety and Homeland Security: detection of Toxic Industrial Chemicals (TICS) and Toxic Industrial Materials (TIMs), explosives and other hazardous materials.
• Manufacturing: detection and profiling of ion and radical concentrations during electrospray ionization, chemical vapor deposition and etching processes.
• Biomedical Analysis: breath analysis.
Dual-Mini-Comb Spectroscopy
• Inexpensive alternative to optical frequency combs created using phase-stable mode-locked lasers
• Acquisition time and bandwidth can be adjusted on the fly
• Sensitive to individual optical cavity mode dispersion
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