In the first paper in this series, we proposed the use of a set of colored LEGO blocks as “standard” samples for the evaluation of fluorescence avoidance and mitigation schemes in Raman spectroscopy, as well as for use to evaluate the instruments’ performance on dark samples. In the second paper we described the spectra obtained on the same blocks from ten different handheld Raman instruments. We found that the combination of a series of colored blocks (white, yellow, red, and blue), and successively darker tone blocks (white, gray, and black) do challenge these instruments and shed light on the ways that their manufacturers have optimized these instruments in specific areas and for different purposes. In this paper we extend the work using an advanced Raman data collection technique: A fast-repetition-rate, short-pulse, laser with a single-photon avalanche photodiode (SPAD) array detector capable of providing a time-sequence output, commonly known as a “time-gating” or “time-resolved” approach. The results are evaluated and compared to those in the first two papers. In addition, X-ray fluorescence (XRF) spectra were also collected to confirm identifications of some of the blocks’ inorganic pigments, which were detected via their Raman spectra.
CrocombeR.A.KammrathB.W.LearyP.E.TagueT.J.Jr.CostaW.D.P.. “LEGO Blocks As ‘Standard’ Samples for Evaluation of Fluorescence Avoidance and Mitigation in Raman Spectroscopy”. Appl. Spectrosc. 2024. 78(3): 340–348. 10.1177/00037028231221585
LarkinP.J.. Infrared and Raman Spectroscopy: Principles and Spectral Interpretation. Amsterdam: Elsevier, 2018. P. 205.
4.
NavaV.FrezzottiM.L.LeoniB.. “Raman Spectroscopy for the Analysis of Microplastics Aquatic Systems”. Appl. Spectrosc. 2021. 75(11): 1341–1357. 10.1177/00037028211043119
5.
International Commission on Illumination (CIE). https://cie.co.at/ [accessed 7 November 2025].
6.
CrocombeR.A.LearyP.E.KammrathB.W.TagueT.J.Jr., et al. “Using LEGO Blocks for the Evaluation of Fluorescence Avoidance and Mitigation in Handheld Raman Spectrometers”. Appl. Spectrosc. 2025. 79(10): 1527–1548. 10.1177/00037028251348481
7.
WeiD.ChenS.LiuQ.. “Review of Fluorescence Suppression Techniques in Raman Spectroscopy”. Appl. Spectrosc. Rev. 2015. 50(5): 387–406. 10.1080/05704928.2014.999936
8.
YaneyP.P.. “Reduction of Fluorescence Background in Raman Spectra by the Pulsed Raman Technique”. J. Opt. Soc. Am. 1972. 62: 1297–1303. 10.1364/JOSA.62.001297
9.
Van DuyneR.P.JeanmaireD.L.ShriverD.F.. “Mode-Locked Laser Raman Spectroscopy: A New Technique for the Rejection of Interfering Background Luminescence Signals”. Anal. Chem. 1974. 46(2): 213–22. 10.1021/ac60338a012
10.
HarrisJ.M.ChrismanR.W.LytleF.E.TobiasR.S.. “Sub-Nanosecond Time-Resolved Rejection of Fluorescence from Raman Spectra”. Anal. Chem. 1976. 48(13): 1937–1943. 10.1021/ac50007a033
MatousekP.TowrieM.StanleyA.ParkerA.W.. “Efficient Rejection of Fluorescence from Raman Spectra Using Picosecond Kerr Gating”. Appl. Spectrosc. 1999. 53(12): 1485–1489. 10.1366/0003702991945993
15.
EverallN.HahnT.MatousekP.ParkerA.W.TowrieM.. “Picosecond Time-Resolved Raman Spectroscopy of Solids: Capabilities and Limitations for Fluorescence Rejection and the Influence of Diffuse Reflectance”. Appl. Spectrosc. 2001. 55(12): 1701–1708. 10.1366/0003702011954053
16.
EfremovE.V.BuijsJ.B.GooijerC.ArieseF.. “Fluorescence Rejection in Resonance Raman Spectroscopy Using a Picosecond-Gated Intensified Charge-Coupled Device Camera”. Appl. Spectrosc. 2007. 61(6): 571–578. 10.1366/000370207781269873
17.
MaruyamaY.BlacksbergJ.CharbonE.. “A 1024×8, 700-ps Timegated SPAD Line Sensor for Planetary Surface Exploration with Laser Raman Spectroscopy and LIBS”. IEEE J. Solid-State Circuits. 2014. 49(1): 179–189. 10.1109/jssc.2013.2282091
18.
BlacksbergJ.AlerstamE.MaruyamaY.CochraneC.J.RossmanG.R.. “Miniaturized Time-Resolved Raman Spectrometer for Planetary Science Based on a Fast Single Photon Avalanche Diode Detector Array”. Appl. Opt. 2016. 55(4): 739–748. 10.1364/AO.55.000739
19.
BruschiniC.HomulleH.AntolovicI.M. “Single-Photon Avalanche Diode Imagers in Biophotonics: Review and Outlook”. Light Sci. Appl. 2019. 8: 87. 10.1038/s41377-019-0191-5
20.
TalalaT.KaikkonenV.A.KeränenP.NikkinenJ., et al. “Time-Resolved Raman Spectrometer with High Fluorescence Rejection Based on a CMOS SPAD Line Sensor and a 573 nm Pulsed Laser”. IEEE Trans. Instrum. Meas. 2021. 70: 1–10. 10.1109/tim.2021.3054679
KostamovaaraJ.TenhunenJ.KöglerM.NissinenI., et al. “Fluorescence Suppression in Raman Spectroscopy Using a Time-Gated CMOS SPAD”. Opt. Express. 2013. 21(25): 31632–31645. 10.1364/OE.21.031632
25.
UsaiA.FinlaysonN.GregoryC.D.CampbellC.HendersonR.K.. “Separating Fluorescence from Raman Spectra Using a CMOS SPAD TCSPC Line Sensor for Biomedical Applications”. Proceedings Volume10873, Optical Biopsy XVII: Toward Real-Time Spectroscopic Imaging and Diagnosis. 2019. Art. No. 108730R. 10.1117/12.2508459
26.
DayD.. “Handheld Laser Induced Breakdown Spectroscopy (HHLIBS)”. In: CrocombeR.A.LearyP.E.KammrathB.W., editors. Portable Spectroscopy and Spectrometry. Chichester, UK; Hoboken, New Jersey: John Wiley, 2021. Chap. 13, Pp. 321–343. 10.1002/9781119636489.ch13
MonolaJ.KoivunotkoE.ZiniJ.NiemeläA., et al. “Freeze-Drying-Induced Mutarotation of Lactose Detected by Raman Spectroscopy”. Eur. J. Pharm. Biopharm. 2024. 205: 114534. 10.1016/j.ejpb.2024.114534
30.
ItkonenJ.GhemtioL.PellegrinoD.JokelaP.J., et al. “Analysis of Biologics Molecular Descriptors Towards Predictive Modelling for Protein Drug Development Using Time-Gated Raman Spectroscopy”. Pharmaceutics. 2022. 14(9): 1639. 10.3390/pharmaceutics14081639
31.
VillaF.SeveriniF.MadoniniF.ZappaF.. “SPADs and SiPMs Arrays for Long-Range High-Speed Light Detection and Ranging (LiDAR)”. Sensors. 2021. 21(11): 3839. 10.3390/s21113839
Canon Inc. “Canon Developing World-First Ultra-High-Sensitivity ILC Equipped with SPAD Sensor, Supporting Precise Monitoring Through Clear Color Image Capture of Subjects Several km Away, Even in Darkness”. https://global.canon/en/news/2023/20230403.html [accessed 7 November 2025].
LiN.HoC.P.WangI-T.PitchappaP., et al. “Spectral Imaging and Spectral LIDAR Systems: Moving Toward Compact Nanophotonics-Based Sensing” Nanophotonics. 2021. 10(5): 1437–1467. 10.1515/nanoph-2020-0625
38.
Sony Semiconductor Solutions Corporation. “Sony to Release a Stacked SPAD Depth Sensor for Automotive LiDAR Applications, an Industry First Contributing to the Safety and Security of Future Mobility with Enhanced Detection and Recognition Capabilities for Automotive LiDAR Applications”. https://www.sony-semicon.com/en/news/2021/2021090601.html [accessed 7 November 2025].
Pi Imaging. “SPAD Lambda (λ): A Linear Single-Photon Detector Array for Spectral Applications”. https://piimaging.com/product-spadlambda [accessed 7 November 2025].
MoodyG.SorgerV.J.BlumenthalD.J.JuodawlkisP.W, et al. “2022Roadmap on Integrated Quantum Photonics”. J. Phys. Photonics. 2022. 4(1): 012501. 10.1088/2515-7647/ac1ef4
LiZ.DeenM.J.. “Towards a Portable Raman Spectrometer Using a Concave Grating and Time-Gated CMOS SPAD”. Opt. Express. 2014. 22(15): 18736. 10.1364/OE.22.018736
BurgioL.ClarkR.J.. “Library of FT-Raman Spectra of Pigments, Minerals, Pigment Media and Varnishes, and Supplement to Existing Library of Raman Spectra of Pigments with Visible Excitation”. Spectrochim. Acta, Part A. 2001. 57(7) 1491–521. 10.1016/s1386-1425(00)00495-9
CaggianiM.C.CosentinoA.MangoneA.. “Pigments Checker Version 3.0, a Handy Set for Conservation Scientists: A Free Online Raman Spectra Database”. Microchem. J. 2016. 129: 123–132. 10.1016/j.microc.2016.06.020
58.
PozziF.BassoE.RizzoA.CesarattoA.TagueT.J.Jr. “Evaluation and Optimization of the Potential of a Handheld Raman Spectrometer: In Situ, Noninvasive Materials Characterization in Artworks”. J. Raman Spectrosc. 2019. 50(6): 861–872. 10.1002/jrs.5585
59.
LarsenR.ColuzziN.CosentinoA.. “Free XRF Spectroscopy Database of Pigments Checker”. Int. J. Conserv. Sci. 2016. 7(3) 659–668.
60.
McCreeryR.L.. Raman Spectroscopy for Chemical Analysis. New York: John Wiley and Sons, 2000. P. 91.
BonnerRF.NossalR.HavlinS.WeissG.H.. “Model for Photon Migration in Turbid Biological Media” J. Opt. Soc. Am. A. 1987. 4(3): 423. 10.1364/JOSAA.4.000423
ReichS.ThomsenC.. “Raman Spectroscopy of Graphite”. Philos. Trans. R. Soc., A. 2004. 362(1824): 2271–2288. 10.1098/rsta.2004.1454
67.
FerrariA.C.RobertsonJ.. “Raman Spectroscopy of Amorphous, Nanostructure, and Diamond-Like Carbon and Nanodiamond”. Philos. Trans. R. Soc., A. 2004. A. 362(1824): 2477–2512. 10.1098/rsta.2004.1452
68.
EndrissH..“Bismuth Vanadates”. In: FaulknerE.B.SchwartzR.J., editors. High Performance Pigments. Weinheim: Wiley-VCH, 2009. Chap. 2, Pp. 7–12. 10.1002/9783527626915.ch2
69.
GaftM.ReisfeldR.PanczerG.. Modern Luminescence Specroscopy of Minerals and Materials. Berlin; Heidelberg: Springer-Verlag, 2005. 10.1007/978-3-319-24765-6
70.
AzariA.RonsmansS.VanoirbeekJ.A.J.HoetP.H.M.GhoshM.. “Challenges in Raman Spectroscopy of (Micro)Plastics: The Interfering Role of Colourants”. Environ. Pollut. 2024. 363(2): 125250. 10.1016/j.envpol.2024.125250
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