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Tunable Diode Laser Absorption Spectroscopy

Related products: HF2LI, MFLI, MF-MD, MF-DIG

Application Description

Tunable Diode Laser Absorption Spectroscopy Application Diagram

Tunable diode laser absorption spectroscopy (TDLAS) is one of the most common techniques to analyze the properties and constituents of gases such as concentration, temperature, pressure, and flow velocity. TDLAS measures the wavelength-dependent absorption of light through a gas medium. As the name implies, the technique usually employs a tunable-wavelength diode laser as the light source.  When the wavelength of light matches one absorption line of a gas species present in the sample, the photodetector records a reduction in the light intensity. When the gas concentration is ultra-low, the induced change in transmission becomes extremely small and difficult to detect sufficiently fast. The sensitivity of TDLAS is significantly enhanced by modulating the current of the laser, which leads to a modulation of the wavelength and of the light intensity. The information about the absorption response is then recovered by demodulating the signal from the photodetector at the modulating frequency and at its second-order harmonic.

Measurement Strategies

The diode laser is driven by a DC signal with a superimposed small AC component at a frequency between a few kHz and a few MHz. When the gas absorption lines are unknown or several absorption lines are under study, the laser frequency is swept across a wide range over a few seconds. Traditionally, two lock-in amplifiers are needed to acquire the signal from the photodetector and demodulate it at the modulation frequency or at its second-order harmonic; to enhance the signal-to-noise ratio (SNR), the amplitude of the AC signal – i.e., the demodulation depth – is optimized by sweeping the frequency when the DC signal is fixed. A data acquisition (DAQ) card is used to analyze the measurement signals from the lock-in amplifiers and from the driving signal.

The Benefits of Choosing Zurich Instruments

A single lock-in amplifier from Zurich Instruments integrates many of the functionalities required for TDLAS applications: one instrument replaces the function generator, multiple lock-in amplifiers, and the DAQ card. The LabOne software suite, included with all instruments, provides the necessary tools for signal tunability and data visualization. From reduced setup complexity to swifter data acquisition, Zurich Instruments' lock-in amplifiers can make a difference for your TDLAS measurements.

  • Less wiring: The MFLI Lock-in Amplifier can generate the complete signal for the diode laser. Adding the MF-MD option makes it possible to demodulate the signal at the fundamental frequency and at its harmonics simultaneously.
  • Better sensitivity: A small change in absorption is captured by the MFLI thanks to its ultra-low input noise of 2.5nV/sqrt(Hz).
  • Automated approach: The Sweeper tool in LabOne offers a straightforward way to tune the DC signal and the amplitude of the AC component.
  • Direct mapping: There is no need for triggers to synchronize the drive signal and the data acquisition. The Sweeper directly presents the results from the demodulators as a function of the DC offset (i.e., the wavelength of light).

Publications

He, Y., Ma, Y., Tong, Y., Yu, X. & Tittel, F.K.

Ultra-high sensitive light-induced thermoelastic spectroscopy sensor with a high Q-factor quartz tuning fork and a multipass cell

Opt. Lett. 44, 1904-1907 (2019)

Ma, Y., Tong, Y., He, Y., Jin, X. & Tittel, F.K.

Compact and sensitive mid-infrared all-fiber quartz-enhanced photoacoustic spectroscopy sensor for carbon monoxide detection

Opt. Express 27, 9302-9312 (2019)

Sun, H. et al.

Highly sensitive acetylene detection based on a compact multi-pass gas cell and optimized wavelength modulation technique

Infrared Physics & Technology, 102, 103012 (2019)

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