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Abstract

An analytical formula to the depth-of-origin profile of transmission Raman spectroscopy in turbid media was derived from the one-dimensional (1D) Kubelka–Munk model. The depth-of-origin profile of the transmitted Raman is proportional to the excitation intensity profile and the transmittance profile, which are two functions of similar forms. The effect of scattering, absorption, and signal-enhancing reflectors are incorporated into the formula. Depth-of-origin profile of a model sample was measured at better than 0.2 mm resolution and fits the formula reasonably well. Conical reflective cavities placed at the front and/or back of the sample enhanced the signal significantly; the relationship among the enhancement functions is verified by the formula. Optical parameters derived from the fitting are compared to theoretical value predicted by optical ray tracing and direct measurements; discrepancies are related to deficiency of the 1D Kubelka–Munk model.

Keywords

Transmission Raman spectroscopy Kubelka–Munk model depth-of-origin profile excitation intensity profile transmittance profile enhancement function combined optical depth

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References

Buckley

Matousek

“Recent Advances in the Application of Transmission Raman Spectroscopy to Pharmaceutical Analysis”. J. Pharm. Biomed. Anal. 2011. 55(4): 645–652.

Griffen

J.A.

Owen

A.W.

Andrews

, et al. “Recent Advances in Pharmaceutical Analysis Using Transmission Raman Spectroscopy”. Spectroscopy. 2017. 32(4): 37–43.

Griffen

J.A.

Owen

A.W.

Matousek

“Quantifying Low Levels (<0.5% W/W) of Warfarin Sodium Salts in Oral Solid Dose Forms Using Transmission Raman Spectroscopy”. J. Pharm. Biomed. Anal. 2018. 155: 276–283.

Everall

Matousek

MacLeod

N.A.

, et al. “Temporal and Spatial Resolution in Transmission Raman Spectroscopy”. Appl. Spectrosc. 2010. 64(1): 52–60.

Everall

Priestnall

Dallin

, et al. “Measurement of Spatial Resolution and Sensitivity in Transmission and Backscattering Raman Spectroscopy of Opaque Samples: Impact on Pharmaceutical Quality Control and Raman Tomography”. Appl. Spectrosc. 2010. 64: 476–484.

Matousek

Everall

Littlejohn

, et al. “Dependence of Signal on Depth in Transmission Raman Spectroscopy”. Appl. Spectrosc. 2011. 65(7): 724–733.

Schrader

Bergmann

“Die intensität des Ramanspektrums Polykristalliner Substanzen”. Fresenius J. Anal. Chem. 1967. 225(2): 230–247.

Oelkrug

Ostertag

Kessler

R.W.

“Quantitative Raman Spectroscopy in Turbid Matter: Reflection or Transmission Mode?”. Anal Bioanal Chem. 2013. 405: 3367–3379.

F. Blechinger. Imaging Spectrometer Having a Wide Spectral Range. U.S. Patent 4773756. Filed 1987. Issued 1988.

10.

M.P. Chrisp. Convex Diffraction Grating Imaging Spectrometer. US Patent 5880834. Filed 1998. Issued 1999.

11.

Ramsey

Ranganathan

McCreery

R.L.

, et al. “Performance Comparison of Conventional and Line-Focused Raman Spectrometers”. Appl. Spectrosc. 2001. 55(6): 767.

12.

McMurdy

J.W.

III Berger

A.J.

“Raman Spectroscopy-Based Creatinine Measurement in Urine Samples from a Multipatient Population”. Appl. Spectrosc. 2003. 57(5): 522–525.

13.

Zhao

“Image Curvature Correction and Cosmic Removal for High Throughput Dispersive Raman Spectroscopy”. Appl. Spectrosc. 2003. 57(11): 1368–1375.

14.

Takahashi

Ahn

J.S.

Asaka

, et al. “Multichannel Fourier Transform Spectroscopy Using Two-Dimensional Detection of the Interferogram and its Application to Raman Spectroscopy”. Appl. Spectrosc. 1993. 47(7): 863–868.

15.

Zhao

Mccreery

R.L.

“Multichannel Fourier Transform Raman Spectroscopy: Combining the Advantages of CCDs with Interferometry”. Appl. Spectrosc. 1996. 50(9): 1209–1214.

16.

Zhao

McCreery

R.L.

“Multichannel FT-Raman Spectroscopy: Noise Analysis and Performance Assessment”. Appl. Spectrosc. 1997. 51(11): 1687–1697.

17.

Gomer

N.R.

Gordon

C.M.

Lucey

, et al. “Raman Spectroscopy Using a Spatial Heterodyne Spectrometer: Proof of Concept”. Appl. Spectrosc. 2011. 65(8): 849–857.

18.

Strange

K.A.

Paul

K.C.

Angel

S.M.

“Transmission Raman Measurements Using a Spatial Heterodyne Raman Spectrometer (SHRS)”. Appl. Spectrosc. 2017. 71(2): 250–257.

19.

Schrader

“Raman Spectroscopy of Small Amounts of Solid and Liquid Substances”. Fresenius' J. Anal. Chem. 1963. 197: 295–309.

20.

Matousek

“Raman Signal Enhancement in Deep Spectroscopy of Turbid Media”. Appl. Spectrosc. 2007. 61(8): 845–854.

21.

Matousek

“Enhancement of Laser Radiation Coupled into Turbid Media by Using a Unidirectional Mirror”. J. Opt. Soc. Am. B. 2008. 25(7): 1223–1230.

22.

Pelletier

M.J.

“Sensitivity-Enhanced Transmission Raman Spectroscopy”. Appl. Spectrosc. 2013. 67(8): 829–840.

23.

Kubelka

“New Contributions to the Optics of Intensely Light-Scattering Materials. Part I”. J. Opt. Soc. Am. 1948. 38(5): 448–457.

24.

Karlsson

Enberg

Rundlöf

, et al. “Determining Optical Properties of Mechanical Pulps”. Nordic Pulp and Paper Research Journal. 2012. 27(3): 531–541.

25.

J. Zhao, X.J. Zhou, S.X. Wang. Light Delivery and Collection Device for Performing Spectroscopic Analysis of a Subject. U.S. Patent Application No. 16053892. Filed 2018.

26.

Džimbeg-Malčić

Barbarić-Mikočević

Ž.

Itrić

“Kubelka–Munk Theory in Describing Optical Properties of Paper (I)”. Teh. Vjesn.—Sveucil. Osijeku [Technical Gazette]. 2011. 18(1): 117–124.

27.

Vahey

D.W.

Zhu

J.Y.

Houtman

C.J.

“On Measurements of Effective Residual Ink Concentration (ERIC) of Deinked Papers Using Kubelka–Munk Theory”. Progress in Paper Recycling. 2006. 16(1): 3–12.

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Analytical Solution to the Depth-of-Origin Profile of Transmission Raman Spectroscopy in Turbid Media Based on the Kubelka–Munk Model

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