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www.le.ac.uk Time-tagged photon imaging for trace gas measurement using cavity enhanced absorption spectroscopy J. M. Hallam & J. S. Lapington, Space Research Centre S. M. Ball, Department of Chemistry University of Leicester

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Page 1: Time-tagged photon imaging

www.le.ac.uk

Time-tagged photon imaging for

trace gas measurement using

cavity enhanced absorption spectroscopy

J. M. Hallam & J. S. Lapington, Space Research CentreS. M. Ball, Department of ChemistryUniversity of Leicester

Page 2: Time-tagged photon imaging

Outline• Absorption Spectroscopy• Cavity Enhanced

• Imaging with capacitive readout

• Capacitive readout design

==

Page 3: Time-tagged photon imaging

Absorption Spectroscopy• Trace gas measurements...

• NO2 (air quality/exhaust fumes)

• I2 (biogenic seaweed emission)

• NO3 & N

2O

5 (night-time chemistry, nitrate aerosols)

• Water dimer, water continuum (climate feedback)

LED Sample Spectroscope

Detector

Page 4: Time-tagged photon imaging

• Goal: Detect atmospheric NO2 at the part-per-

billion level

• Long path length: Use Fabry-Perot cavity

• (99.995% > r > 99%)

Cavity Enhanced

LED Sample

Spectroscope

Detector

Fabry-Perot Cavity

Page 5: Time-tagged photon imaging

Cavity, LED, and sample wavelength curves are superimposed

N2

NO2

I2

Page 6: Time-tagged photon imaging

• Using a pulsed coherent light source

• Cavity output tails off exponentially

• Loss of spectral information

• Low sampling rate

Cavity RingDown Spectroscopy

Laser Input Pulse Detector

Pulse in cavity Cavity output

Time

Intensity

Page 7: Time-tagged photon imaging

flush wavelength

time

intensity

Empty cavity

sample wavelength

time

intensity

Cavity + sample

[Ball '09]

Page 8: Time-tagged photon imaging

• Demodulation extracts the phase delay

• From which we obtain ringdown time

Continuous CRDS[Engeln '96]

Sig. Gen. Trigger Freq. Mult. Trig. x2

Amplitude modulated input

Page 9: Time-tagged photon imaging

BroadBand Cavity Enhanced Absorption Spectrometry (BBCEAS)

y-axisdisplacement

fibre-optic

colour filter

alignment mirrors

• Photon-counting provides timing information directly.

MCP

ND filter

Page 10: Time-tagged photon imaging

BroadBand Cavity Enhanced Absorption Spectrometry (BBCEAS)

Page 11: Time-tagged photon imaging

Phase shift and intensity over modulation frequency

Page 12: Time-tagged photon imaging

MCP and Capacitive Readout

Page 13: Time-tagged photon imaging

Capacitive Readout Advantages• Capacitive coupling – no resistive noise, no bias

resistors, separate from MCP vacuum

• No geometric charge division – no partition noise

• High-speed – MCP limited timing

• Only electronic noise, dominated by preamp input capacitance

• Simple linear algorithm to decode position

• Excellent linearity - >80% anode dynamic range

Page 14: Time-tagged photon imaging

• Increased edge capacitance

• Horizontal and vertical capacitance emphasized

Capacitive Readout

Page 15: Time-tagged photon imaging

New Capacitive Readout Design• Capacitance built-in to pattern geometry – no

discrete components

• 25 x 25 mm2 C-DIR finite-element modelled with 8pF pattern capacitance

Page 16: Time-tagged photon imaging

Imaging detector• Single-channel

cavity (N2 flush with

I2 contamination)

output image

• Histogram across image, showing I

2

absorption spectrum from N

2

base spectrum

I2

N2

Page 17: Time-tagged photon imaging

Conclusions• BBCEAS is a powerful, flexible and simple technique

for point atmospheric studies• Time-resolution measures cavity ringdown

allowing cavity-calibration in the field

• Spectral resolution allows different species and concentrations to be identified together

• Our imaging, photon counting detector has read out broadband spectra from both cavity and reference beams at high sensitivity, with spectral and time resolution

Page 18: Time-tagged photon imaging

Bibliography & AcknowledgementsBall, S., Jones, R., 2009, 'Broadband cavity ring-down spectroscopy',

(Chapter 3, Berden,. G, Engeln, R., Cavity Ring-Down Spectroscopy:

Techniques and Applications), Blackwell Publishing Engeln, R., Vonhelden, G., Berden, G., & Meijer, G. 1996, 'Phase shift cavity

ring down absorption spectroscopy', Chemical Physics Letters, 262, 105