Optical identification of liquid droplets, aerosols, or thin films is critical for many applications. While reference spectra are sometimes available for such measurements, they are not always applicable to the observed spectrum or the given sample morphology. Reference spectra for many forms can be modeled, however, if the n/k vectors (real and imaginary refractive indices) are available. In previous work we have reported protocols to determine the n/k vectors for dozens of liquids, primarily in the mid-infrared (MIR) spectral range from 7500 to 400 cm–1. In this work we extend the spectral range into the near-infrared (NIR) region, demonstrating a method to measure and merge the data sets to create composite n/k data ranging from 10 000 to 400 cm–1 (1.0 to 25 µm) with absorbance fidelity spanning over four orders of magnitude, and vastly improved signal-to-noise in the NIR. The precision of the composite data is evaluated for three different liquids, focusing primarily on the steps for converting the raw absorbance spectra to k values. The variability in both MIR and NIR data as well as in the final n/k vectors is also investigated for several liquids. For typical liquids, the overall variability (reported as 2σ) in the final n and k-vectors is determined to be ∼0.4% and 3%, respectively. Finally, the derived n/k data are used to calculate absorbance spectra for aerosol droplets, showing marginal variability due to the typical measurement errors in the final n/k vectors.
UotilaJ.KauppinenJ.. “Fourier Transform Infrared Measurement of Solid-, Liquid-, and Gas-Phase Samples with a Single Photoacoustic Cell”. Appl. Spectrosc. 2008. 62(6): 655–660. 10.1366/000370208784658048
2.
BakerT.J.TonkynR.G.ThompsonC.J.DunlapM.K., et al. “An Infrared Spectral Database for Gas-phase Quantitation of Volatile Per- and Polyfluoroalkyl Substances (PFAS)”. J. Quant. Spectrosc. Radiat. Transfer. 2023. 295: 108420. 10.1016/j.jqsrt.2022.108420
3.
SchneiderM.D.W.BakerT.J.ScharkoN.K.BlakeT.A., et al. “A Method for Generating Quantitative Vapor-Phase Infrared Spectra of Solids: Results for Phenol, Camphor, Menthol, Syringol, Dicyclopentadiene, and Naphthalene”. J. Quant. Spectrosc. Radiat. Transfer. 2024. 323: 109045. 10.1016/j.jqsrt.2024.109045
4.
ThériaultJ.-M.PuckrinE.HancockJ.LecavalierP., et al. “Passive Standoff Detection of Chemical Warfare Agents on Surfaces”. Appl. Opt. 2004. 43(31): 5870–5885. 10.1364/AO.43.005870
5.
HarigR.BraunR.DyerC.HowleC.TruscottB.. “Short-Range Remote Detection of Liquid Surface Contamination by Active Imaging Fourier Transform Spectrometry”. Opt. Express. 2008. 16(8): 5708–5714. 10.1364/OE.16.005708
6.
ThériaultJ.-M.PuckrinE.LavoieH.. “Remote Monitoring of Multi-Gas Mixtures by Passive Standoff Fourier Transform Infrared Radiometry”. Appl. Spectrosc. 2007. 61(6): 630–637. 10.1366/000370207781269882
7.
SchymanskiD.OßmannB.E.BenismailN.BoukermaK., et al. “Analysis of Microplastics in Drinking Water and Other Clean Water Samples with Micro-Raman and Micro-Infrared Spectroscopy: Minimum Requirements and Best Practice Guidelines”. Anal. Bioanal. Chem. 2021. 413(24): 5969–5994. 10.1007/s00216-021-03498-y
8.
LuoW.TianP.FanG.DongW., et al. “Non-Destructive Determination of Four Tea Polyphenols in Fresh Tea Using Visible and Near-Infrared Spectroscopy”. Infrared Phys. Technol. 2022. 123: 104037. 10.1016/j.infrared.2022.104037
9.
WangM.WangX.XiaQ.LiuM., et al. ‘'Application of Spectroscopy Technology in Detecting Toxic Effects of Environmental Pollutants'’. Proc. SPIE. 2024. 13283: 132832P. 10.1117/12.303688
10.
LiX.TangX.ChenH.WuT.WangB.. “Quantitative Analysis Method for the Fourier Transform Infrared Spectroscopy of Gases”. Proc. SPIE. 2024. 12972: 129720J. 10.1117/12.3022573
11.
M. Moniz Vieira Pinto, V.G. Poli de Lima, L.J. Raniero, E.A. Lo Schiavo Arisawa. “Saliva Diagnosis of Autistic Spectrum Disorder by FT-IR Spectroscopy”. Proc. SPIE. 2021. 11660: 116600E. 10.1117/12.2583257
12.
FringsK.A.BaumannL.HeineN.DebenerN., et al. “Spectroscopic Analysis and Classification of Oral Bacteria in Mixed Samples Using FT-IR Spectroscopy and Deep Learning”. Proc. SPIE. 2025. 13331: 1333104. 10.1117/12.3042855
13.
PetersonK.A.FrancisR.M.BanachC.A.BradleyA.M., et al. “Method to Derive the Infrared Complex Refractive Indices n(λ) and k(λ) for Organic Solids from KBr Pellet Absorption Measurements”. Appl. Opt. 2024. 63(6): 1553–1565. 10.1364/AO.514661
14.
BanachC.A.BradleyA.M.TonkynR.G.WilliamsO.N., et al. “Dynamic Infrared Gas Analysis from Longleaf Pine Fuel Beds Burned in a Wind Tunnel: Observation of Phenol in Pyrolysis and Combustion Phases”. Atmos. Meas. Tech. 2021. 14(3): 2359–2376. 10.5194/amt-14-2359-2021
15.
HugheyK.D.TonkynR.G.HarperW.W.YoungV.L., et al. “Preliminary Studies of UV Photolysis of Gas-Phase CH3I in Air: Time-Resolved Infrared Identification of Methanol and Formaldehyde Products”. Chem. Phys. Lett. 2021. 768: 138403. 10.1016/j.cplett.2021.138403
16.
ThompsonC.J.GallagherN.B.HugheyK.D.DunlapM.K., et al. “An Interactive Spectral Analysis Tool for Chemical Identification and Quantification of Gas-Phase Species in Complex Spectra”. Appl. Spectrosc. 2023. 77(6): 557–568. 10.1177/00037028231169304
17.
RadicaF.Della VenturaG.MalfattiL.Cestelli GuidiM., et al. “Real-time Quantitative Detection of Styrene in Atmosphere in Presence of Other Volatile-Organic Compounds Using a Portable Device”. Talanta. 2021. 233: 122510. 10.1016/j.talanta.2021.122510
18.
MustardJ.F.HaysJ.E.. “Effects of Hyperfine Particles on Reflectance Spectra from 0.3 to 25 μm”. Icarus. 1997. 125(1): 145–163. 10.1006/icar.1996.5583
19.
LaneM.D.. “Midinfrared Optical Constants of Calcite and Their Relationship to Particle Size Effects in Thermal Emission Spectra of Granular Calcite”. J. Geophys. Res.: Planets. 1999. 104(E6): 14099–14108. 10.1029/1999JE900025
20.
MoerschJ.E.ChristensenP.R.. “Thermal Emission from Particulate Surfaces: A Comparison of Scattering Models with Measured Spectra”. J. Geophys. Res.: Planets. 1995. 100(E4): 7465–7477. 10.1029/94JE03330
21.
MyersT.L.TonkynR.G.DanbyT.O.TaubmanM.S., et al. “Accurate Measurement of the Optical Constants n and k for a Series of 57 Inorganic and Organic Liquids for Optical Modeling and Detection”. Appl. Spectrosc. 2018. 72(4): 535–550. 10.1177/0003702817742848
22.
TonkynR.DanbyT.BirnbaumJ.TaubmanM., et al. “Measurement of Infrared Refractive Indices of Organic and Organophosphorous Compounds for Optical Modeling”. Proc. SPIE. 2017. 10183: 1018306. 10.1117/12.2264384
23.
MyersT.L.TonkynR.G.DanbyT.O.De VetterB.M., et al. “Accurate Measurement of the Optical Constants for Modeling Organic and Organophosphorous Liquid Layers and Drops”. Proc. SPIE. 2018. 10629: 1062912. 10.1177/0003702817742848
24.
BernackiB.E.JohnsonT.J.MyersT.L.. “Modeling Thin Layers of Analytes on Substrates for Spectral Analysis: Use of Solid/Liquid n and k Values to Model Reflectance Spectra”. Opt. Eng. 2020. 59(9): 092005. 10.1117/1.oe.59.9.092005
25.
BernackiB.E.JohnsonT.J.MyersT.L.BlakeT.A.. “Modeling Liquid Organic Thin Films on Substrates”. Proc. SPIE. 2018. 10629: 1062916. 10.1117/12.2299873
26.
HarrickN.J.BeckmannK.H.. “Internal Reflection Spectroscopy”. In: KaneP.F.LarrabeeG.B., editors. Characterization of Solid Surfaces. New York: Plenum Press, 1974. Pp. 215–245. 10.1007/978-1-4613-4490-2_11
27.
GriffithsP.R.De HasethJ.A.WinefordnerJ.D.. “Quantitative Analysis”. In: GriffithsP.R.de HasethJ.A., et al. Fourier Transform Infrared Spectrometry. Hoboken, New Jersey: Wiley-Interscience, 2007. Ch. 9, Pp. 197-224. 10.1002/9780470106310.ch9
TonauerC.M.KöckE.-M.HennR.SternJ.N., et al. “Near-Infrared Spectroscopy for Remote Sensing of Porosity, Density, and Cubicity of Crystalline and Amorphous H2O Ices in Astrophysical Environments”. Astrophys. J. 2024. 970(1): 82. 10.3847/1538-4357/ad4f82
30.
WuP.SieslerH.W.. “The Assignment of Overtone and Combination Bands in the near Infrared Spectrum of Polyamide 11”. J. Near Infrared Spectrosc. 1999. 7(2): 65–76. 10.1255/jnirs.236
31.
ClapsR.EnglichF.V.LeleuxD.P.RichterD., et al. “Ammonia Detection by Use of Near-Infrared Diode-Laser-Based Overtone Spectroscopy”. Appl. Opt. 2001. 40(24): 4387–4394. 10.1364/AO.40.004387
32.
Viscarra RosselR.A.McGlynnR.N.McBratneyA.B.. “Determining the Composition of Mineral-Organic Mixes Using UV–Vis-NIR Diffuse Reflectance Spectroscopy”. Geoderma. 2006. 137(1): 70–82. 10.1016/j.geoderma.2006.07.004
33.
IwamotoR.NaraA.MatsudaT.. “Near-Infrared Combination and Overtone Bands of the CH2 Sequence in CH2X2, CH2XCHX2, and CH3(CH2)5CH3 and their Characteristic Frequency Zones”. Appl. Spectrosc. 2006. 60(4): 450–458. 10.1366/000370205774783179
34.
VenturaM.SilvaJ.R.CatundaT.AndradeL.H.C.LimaS.M.. “Identification of Overtone and Combination Bands of Organic Solvents by Thermal Lens Spectroscopy with Tunable Ti:Sapphire Laser Excitation”. J. Mol. Liq. 2021. 328: 115414. 10.1016/j.molliq.2021.115414
35.
IwamotoR.NaraA.MatsudaT.. “Near-Infrared Combination and Overtone Bands of CH in CHX3, CHX2–CHX2, and CHX2–CX2–CHX2”. Appl. Spectrosc. 2005. 59(11): 1393–1398. 10.1366/000370205774783179
MyersT.L.TonkynR.G.LoringJ.S.OeckA.M., et al. “Accurate Optical Constants for Liquids in the Near-Infrared: Improved Methods for Obtaining n and k from 1 to 4 μm”. Proc. SPIE.2019. 11010: 110100O. 10.1117/12.2519499
38.
BertieJ.E.KeefeC.D.. “Infrared Intensities of Liquids XXIV: Optical Constants of Liquid Benzene-h6 at 25˚C Extended to 11.5 cm-1 and Molar Polarizabilities and Integrated Intensities of Benzene-h6 Between 6200 and 11.5 cm-1”. J. Mol. Struct. 2004. 695: 39–57. 10.1016/j.molstruc.2003.11.002
39.
BertieJ.E.KeefeC.D.JonesR.N.. “Infrared Intensities of Liquids VIII. Accurate Baseline Correction of Transmission Spectra of Liquids for Computation of Absolute Intensities, and the 1036 cm−1 Band of Benzene as a Potential Intensity Standard”. Can. J. Chem. 1991. 69(11): 1609–1618. 10.1139/v91-236
40.
BertieJ.E.MichaelianK.H.. “Comparison of Infrared and Raman Wave Numbers of Neat Molecular Liquids: Which is the Correct Infrared Wave Number to Use?”. J. Chem. Phys. 1998. 109(16): 6764–6771. 10.1063/1.477322
41.
BertieJ.E.ZhangS.L.Dale KeefeC.. “Measurement and Use of Absolute Infrared Absorption Intensities of Neat Liquids”. Vib. Spectrosc. 1995. 8(2): 215–229. 10.1016/0924-2031(94)00038-I
42.
BertieJ.E.ZhangS.L.KeefeC.D.. “Infrared Intensities of Liquids XVI. Accurate Determination of Molecular Band Intensities from Infrared Refractive Index and Dielectric Constant Spectra”. J. Mol. Struct. 1994. 324(1): 157–176. 10.1016/0022-2860(94)08237-5
MyersT.L.BernackiB.E.WilhelmM.J.JensenK.L., et al. “Influence of Intermolecular Interactions on the Infrared Complex Indices of Refraction for Binary Liquid Mixtures”. Phys. Chem. Chem. Phys. 2022. 24(36): 22206–22221. 10.1039/d2cp02920k
45.
LockwoodS.P.BernackiB.E.WilhelmM.J.MyersT.L., et al. “Modeling Aerosol Transmission Spectra from n(λ) and k(λ) Infrared Optical Constants Measurements of Organic Liquids and Solids”. Opt. Express.2024. 32(17): 30169–30181. 10.1364/OE.529439
46.
SharpeS.W.JohnsonT.J.SamsR.L.ChuP.M., et al. “Gas-Phase Databases for Quantitative Infrared Spectroscopy”. Appl. Spectrosc. 2004. 58(12): 1452–1461. 10.1366/0003702042641281
RochaW.R.M.PillingS.. “Determination of Optical Constants n and k of Thin Films from Absorbance Data Using Kramers–Kronig Relationship”. Spectrochim. Acta, Part A. 2014. 123: 436–446. 10.1016/j.saa.2013.12.075
49.
TatianB.. “Fitting Refractive-index Data with the Sellmeier Dispersion Formula”. Appl. Opt. 1984. 23(24): 4477–4485. 10.1364/AO.23.004477
50.
SchäferJ.LeeS.C.KienleA.. “Calculation of the Near Fields for the Scattering of Electromagnetic Waves by Multiple Infinite Cylinders at Perpendicular Incidence”. J. Quant. Spectrosc. Radiat. Transfer. 2012. 113(16): 2113–2123. 10.1016/j.jqsrt.2012.05.019
SalcidoJ.M.O.LockwoodS.ZelenyukA.BakerT., et al. “Quantitative Infrared Spectroscopy of Aerosols: Mie Theory Modeling with Experimental Validation”. Optica. 2025. 12(9): 1462–1468. 10.1364/OPTICA.566710
53.
CotterellM.I.KnightJ.W.ReidJ.P.Orr-EwingA.J.. “Accurate Measurement of the Optical Properties of Single Aerosol Particles Using Cavity Ring-Down Spectroscopy”. J. Phys. Chem. A. 2022. 126(17): 2619–2631. 10.1021/acs.jpapproximately2c01246
54.
BertieJ.E.EyselH.H.. “Infrared Intensities of Liquids I: Determination of Infrared Optical and Dielectric Constants by FT-IR Using the CIRCLE ATR Cell”. Appl. Spectrosc. 1985. 39(3): 392–401. 10.1366/0003702854248575
55.
JohnsonT.J.SharpeS.W.CovertM.A.. “Disseminator for Rapid, Selectable, and Quantitative Delivery of Low and Semivolatile Liquid Species to the Vapor Phase”. Rev. Sci. Instrum. 2006. 77(9). 10.1063/1.2349298
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