Abstract
Herein we report on a deep-learning method for the removal of instrumental noise and unwanted spectral artifacts in Fourier transform infrared (FTIR) or Raman spectra, especially in automated applications in which a large number of spectra have to be acquired within limited time. Automated batch workflows allowing only a few seconds per measurement, without the possibility of manually optimizing measurement parameters, often result in challenging and heterogeneous datasets. A prominent example of this problem is the automated spectroscopic measurement of particles in environmental samples regarding their content of microplastic (MP) particles. Effective spectral identification is hampered by low signal-to-noise ratios and baseline artifacts as, again, spectral post-processing and analysis must be performed in automated measurements, without adjusting specific parameters for each spectrum. We demonstrate the application of a simple autoencoding neural net for reconstruction of complex spectral distortions, such as high levels of noise, baseline bending, interferences, or distorted bands. Once trained on appropriate data, the network is able to remove all unwanted artifacts in a single pass without the need for tuning spectra-specific parameters and with high computational efficiency. Thus, it offers great potential for monitoring applications with a large number of spectra and limited analysis time with availability of representative data from already completed experiments.
Highlights
Vibrational spectroscopy techniques are ubiquitous in polymer analytics and widely used for unknown material identification or chemical composition characterization.[1,2] The most widely employed ones are Fourier transform infrared (FTIR) and Raman spectroscopies, both coming in a broad variety of different instruments ranging from highly sensitive laboratory instruments to portable or even handheld devices with portable convenience but weaker analytical figures of merit
The aim of the present study is to extend the application of autoencoders to the challenging domain of environmental particle analyses with both μFTIR and μRaman spectroscopies
We describe the application of the autoencoding network to different cases in vibrational spectroscopy and outline the possibilities and limitations of our method
Summary
Vibrational spectroscopy techniques are ubiquitous in polymer analytics and widely used for unknown material identification or chemical composition characterization.[1,2] The most widely employed ones are Fourier transform infrared (FTIR) and Raman spectroscopies, both coming in a broad variety of different instruments ranging from highly sensitive laboratory instruments to portable or even handheld devices with portable convenience but weaker analytical figures of merit. Both FTIR and Raman spectroscopies are commonly integrated in light microscopes for noninvasively studying very small specimens or features. Measuring longer usually translates into an increased spectral quality in terms of signal-to-noise ratio
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