Abstract
Various single-ring aromatic compounds in water sources are of great concern due to its hazardous impact on the environment and human health. The fluorescence excitation-emission matrix (EEMs) spectrophotometry is a useful method to identify organic pollutants in water. This study provides a detailed insight into the fluorescence properties of the 14 selected toxic single-ring aromatic compounds by experimental and theoretical analysis. The theoretical analysis were done with Time-Dependent Density Functional Theory (TD-DFT) and B3LYP/6-31G (d,p) basis set, whereas, Polarizable Continuum Model (PCM) was used to consider water as solvent. The selected compounds displayed their own specific excitation-emission (Ex/Em) wavelengths region, at Ex < 280 nm and Em < 340 nm, respectively. Whereas the theoretical Ex/Em was observed as, Ex at 240 nm-260 nm and Em at 255 nm-300 nm. Aniline as a strong aromatic base has longer Em (340 nm) than alkyl, carbonyl, and halogens substituted benzenes. The lone pair of electrons at amide substituent serves as a π-electron contributor into the aromatic ring, hence increasing the stability and transition energy, which results in longer emission and low quantum yield for the aniline. The fluorescence of halogenated benzenes illustrates an increase in the HOMO-LUMO energy gap and a decrease in quantum yield associated with atomic size (F>Cl>Br>I). In this study the theoretical results are in line with experimental ones. The understanding of fluorescence and photophysical properties are of great importance in the identification of these compounds in the water.
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Abbas H, Shkir M, Alfaify S (2019). Density functional study of spectroscopy, electronic structure, linear and nonlinear optical properties of l-proline lithium chloride and l-proline lithium bromide monohydrate: For laser applications. Arabian Journal of Chemistry, 12(8): 2336–2346
Al-Ansari I A (2016). Effects of structure and environment on the spectroscopic properties of (3-Amino-Substituted-Thieno[2,3-b] Pyridine-2-yl)Pyridine/Quinolin-2-yl)(Phenyl)Methanones: Experimental and theoretical Study. Journal of Fluorescence, 26(3): 821–834
Al-Soliemy A M, Osman O I, Hussein M A, Asiri A M, El-Daly S A (2016). Fluorescence, photophysical behaviour and DFT investigation of E,E-2,5-bis[2-(3-pyridyl)ethenyl]pyrazine (BPEP). Journal of Fluorescence, 26(4): 1199–1209
Allafchian A R, Akhgar A, Ielbeigi V, Tabrizchi M (2016). Determination of xylene and toluene by solid-phase microextraction using Au nanoparticles-thiol silane film coupled to ion mobility spectrometry. Bulletin of Environmental Contamination and Toxicology, 97(5): 670–676
Ando D, Ijichi J, Uno T, Itoh T, Kubo M (2019). Preparation of donor-acceptor polyfluorenes with pendant carboxyl or amine functionalities and their photoluminescence properties. Polymer Bulletin, 76(12): 6137–6151
Anumol T, Sgroi M, Park M, Roccaro P, Snyder S A (2015). Predicting trace organic compound breakthrough in granular activated carbon using fluorescence and UV absorbance as surrogates. Water Research, 76: 76–87
Baimatova N, Koziel J A, Kenessov B (2015). Quantification of benzene, toluene, ethylbenzene and o-xylene in internal combustion engine exhaust with time-weighted average solid phase microextraction and gas chromatography mass spectrometry. Analytica Chimica Acta, 873: 38–50
Baker A (2002a). Fluorescence excitation-emission matrix characterization of river waters impacted by a tissue mill effluent. Environmental Science & Technology, 36(7): 1377–1382
Baker A (2002b). Fluorescence properties of some farm wastes: Implications for water quality monitoring. Water Research, 36(1): 189–195
Bao L J, Maruya K A, Snyder S A, Zeng E Y (2012). China’s water pollution by persistent organic pollutants. Environmental Pollution, 163: 100–108
Barik A, Priyadarsini K I (2013). Solvent dependent photophysical properties of dimethoxy curcumin. Spectrochimica Acta Part A-Molecular and Biomolecular Spectroscopy, 105: 267–272
Barone V, Bloino J, Monti S, Pedone A, Prampolini G (2011). Fluorescence spectra of organic dyes in solution: A time dependent multilevel approach. Physical Chemistry Chemical Physics, 13(6): 2160–2166
Belay A, Libnedengel E, Kim H K, Hwang Y H (2016). Effects of solvent polarity on the absorption and fluorescence spectra of chlorogenic acid and caffeic acid compounds: Determination of the dipole moments. Luminescence, 31(1): 118–126
Benelhadj K, Muzuzu W, Massue J, Retailleau P, Charaf-Eddin A, Laurent A D, Jacquemin D, Ulrich G, Ziessel R (2014). White emitters by tuning the excited-state intramolecular proton-transfer fluorescence emission in 2-(2′-hydroxybenzofuran)benzoxazole dyes. Chemistry (Weinheim an der Bergstrasse, Germany), 20(40): 12843–12857
Boo B H, Ryu S Y, Yoon M, Koh S G, Park K L (2010). Fluorescence spectroscopic and time-dependent DFT studies for intramolecular excimer formation of di-9H-fluoren-9-yldimethylsilane: dynamics and energetics for conformational change. Journal of Physical Chemistry A, 114(34): 8969–8974
Brocchieri L, Karlin S (1994). Geometry of interplanar residue contacts in protein structures. Proceedings of the National Academy of Sciences of the United States of America, 91(20): 9297–9301
Bursa B, Wrobel D, Barszcz B, Kotkowiak M, Vakuliuk O, Gryko D T, Kolanowski L, Baraniak M, Lota G (2016). The impact of solvents on the singlet and triplet states of selected fluorine corroles-absorption, fluorescence, and optoacoustic studies. Physical Chemistry Chemical Physics, 18(10): 7216–7228
Busetti F, Heitz A, Cuomo M, Badoer S, Traverso P (2006). Determination of sixteen polycyclic aromatic hydrocarbons in aqueous and solid samples from an Italian wastewater treatment plant. Journal of Chromatography. A, 1102(1–2): 104–115
Carstea E M, Bridgeman J, Baker A, Reynolds D M (2016). Fluorescence spectroscopy for wastewater monitoring: A review. Water Research, 95: 205–219
Cervantes-Navarro F, Glossman-Mitnik D (2012). DFT study of the effect of substituents on the absorption and emission spectra of Indigo. Chemistry Central Journal, 6(1): 70
Chen W, Westerhoff P, Leenheer J A, Booksh K (2003). Fluorescence excitation- Emission matrix regional integration to quantify spectra for dissolved organic matter. Environmental Science & Technology, 37(24): 5701–5710
Chidthong R, Hannongbua S (2010). Excited state properties, fluorescence energies, and lifetimes of a poly(fluorene-phenylene), based on TD-DFT investigation. Journal of Computational Chemistry, 31(7): 1450–1457
Christensen J, Ladefoged A M, Norgaard L (2005). Rapid determination of bitterness in beer using fluorescence spectroscopy and chemometrics. Journal of the Institute of Brewing, 111(1): 3–10
Dai J, Mckee M L, Samokhvalov A (2015). Fluorescence of A100 MOF and adsorption of water, indole, and naphthalene on A100 by the spectroscopic, kinetic, and DFT studies. Journal of Physical Chemistry C, 119(5): 2491–2502
Fleming S, Mills A, Tuttle T (2011). Predicting the UV-vis spectra of oxazine dyes. Beilstein Journal of Organic Chemistry, 7(1): 432–441
Franke S, Hildebrandt S, Schwarzbauer J, Link M, Francke W (1995). Organic-compounds as contaminants of the Elbe River and its tributaries. 2. Gc/Ms screening for contaminants of the Elbe Water. Fresenius’ Journal of Analytical Chemistry, 353(1): 39–49
Goldman J H, Rounds S A, Needoba J A (2012). Applications of fluorescence spectroscopy for predicting percent wastewater in an urban stream. Environmental Science & Technology, 46(8): 4374–4381
He W, Lee J H, Hur J (2016). Anthropogenic signature of sediment organic matter probed by UV-Visible and fluorescence spectroscopy and the association with heavy metal enrichment. Chemosphere, 150: 184–193
Henderson R K, Baker A, Murphy K R, Hambly A, Stuetz R M, Khan S J (2009). Fluorescence as a potential monitoring tool for recycled water systems: A review. Water Research, 43(4): 863–881
Jacquemin D, Perpete E A, Scalmani G, Frisch M J, Ciofini I, Adamo C (2007). Fluorescence of 1,8-naphthalimide: A PCM-TD-DFT investigation. Chemical Physics Letters, 448(1–3): 3–6
Karlowatz M, Kraft M, Mizaikoff B (2004). Simultaneous quantitative determination of benzene, toluene, and xylenes in water using Mid-infrared evanescent field spectroscopy. Analytical Chemistry, 76(9): 2643–2648
Kassaee M H, Keffer D J, Steele W V (2007). Theoretical calculation of thermodynamic properties of naphthalene, methylnaphthalenes, and dimethylnaphthalenes. Journal of Chemical and Engineering Data, 52(5): 1843–1850
Khamees H A, Mohammed Y H E, Swamynayaka A, Al-Ostoot F H, Sert Y, Alghamdi S, Khanum S A, Madegowda M (2019). Molecular structure, DFT, vibrational spectra with fluorescence effect, hirshfeld surface, docking simulation and antioxidant activity of thiazole derivative. ChemistrySelect, 4(15): 4544–4558
Khan M F S, Wu J, Liu B, Cheng C, Akbar M, Chai Y, Memon A (2018). Fluorescence and photophysical properties of xylene isomers in water: With experimental and theoretical approaches. Royal Society Open Science, 5(2): 171719
Khan M F S, Wu J, Liu B, Cheng C, Tang J K (2017). DFT investigation facilitating experimental fluorescence: Effect of substituent on photophysical properties of BTEX in water. Abstracts of Papers of the American Chemical Society, 254: 1155
Knapik H G, Fernandes C V, De Azevedo J C, Do Amaral Porto M F (2014). Applicability of fluorescence and absorbance spectroscopy to estimate organic pollution in rivers. Environmental Engineering Science, 31(12): 653–663
Lakowicz J R (1983). Effects of solvents on fluorescence emission spectra. In: Lakowicz J R, ed. Principles of Fluorescence Spectroscopy. Boston: Springer, 187–215
Lakowicz J R, Chowdhury M H, Ray K, Zhang J, Fu Y, Badugu R, Sabanayagam C R, Nowaczyk K, Szmacinski H, Aslan K, Geddes C D (2006). Plasmon-controlled fluorescence: A new detection technology. Plasmonics in Biology and Medicine III, 6099: 9909
Li F, Qiu Z Z, Zhang J D, Liu C Y, Cai Y, Xiao M S (2017). Spatial distribution and fuzzy health risk assessment of trace elements in surface water from Honghu Lake. International Journal of Environmental Research and Public Health, 14(9): 1011
Ma C, Liu Y F, Li C Z, Yang Y G (2017). The fluorescence quenching phenomenon in newly synthesized blue fluorescence protein molecule caused by anchoring group substitution: A DFT and TD-DFT study. RSC Advances, 7(22): 13561–13569
Markiewicz A, Bjorklund K, Eriksson E, Kalmykova Y, Stromvall A M, Siopi A (2017). Emissions of organic pollutants from traffic and roads: Priority pollutants selection and substance flow analysis. Science of the Total Environment, 580: 1162–1174
Min C G, Leng Y, Yang X K, Ren A M, Cui X Y, Xu M L, Wang S H (2013). TD-DFT accuracy in determining excited-state structures and fluorescence spectra of firefly emitter. Chemical Research in Chinese Universities, 29(5): 982–985
Pan H, Yu H, Song Y, Zhu L, Liu R, Du E (2017). Tracking fluorescent components of dissolved organic matter from soils in large-scale irrigated area. Environmental Science and Pollution Research, 24(7): 6563–6571
Peleato N M, Legge R L, Andrews R C (2017). Investigation of fluorescence methods for rapid detection of municipal wastewater impact on drinking water sources. Spectrochimica Acta. Part A: Molecular and Biomolecular Spectroscopy, 171: 104–111
Politzer P, Lane P, Concha M C, Ma Y, Murray J S (2007). An overview of halogen bonding. Journal of Molecular Modeling, 13(2): 305–311
Rahulan K M, Balamurugan S, Meena K S, Yeap G Y, Kanakam C C (2014). Synthesis and nonlinear optical absorption of novel chalcone derivative compounds. Optics & Laser Technology, 56: 142–145
Remko M, Soralova S (2012). Effect of water coordination on competition between π and non-π cation binding sites in aromatic amino acids: L-phenylalanine, L-tyrosine, and L-tryptophan Li+, Na+, and K+ complexes. Journal of Biological Inorganic Chemistry, 17(4): 621–630
Soh S C, Abdullah M P (2007). Determination of volatile organic compounds pollution sources in malaysian drinking water using multivariate analysis. Environmental Monitoring and Assessment, 124(1–3): 39–50
Sorensen J P, Lapworth D J, Marchant B P, Nkhuwa D C, Pedley S, Stuart M E, Bell R A, Chirwa M, Kabika J, Liemisa M, Chibesa M (2015). In-situ tryptophan-like fluorescence: A real-time indicator of faecal contamination in drinking water supplies. Water Research, 81: 38–46
Tan A, Bozkurt E, Kara Y (2017). Investigation of solvent effects on photophysical properties of new aminophthalimide derivatives-based on methanesulfonate. Journal of Fluorescence, 27(3): 981–992
Tugsuz T (2018). TD-DFT study of the absorption and emission spectra of blue to red phosphorescent Ir(III) complexes. Journal of Optoelectronics and Advanced Materials, 20(3–4): 149–158
Valeur B, Berberan-Santos M N (2011). A brief history of fluorescence and phosphorescence before the Emergence of Quantum Theory. Journal of Chemical Education, 88(6): 731–738
Wasswa J, Mladenov N, Pearce W (2019). Assessing the potential of fluorescence spectroscopy to monitor contaminants in source waters and water reuse systems. Environmental Science. Water Research & Technology, 5(2): 370–382
Williams R, Meares J, Brooks L, Watts R, Lemieux P (1994). Priority pollutant PAH analysis of incinerator emission particles using HPLC and optimized fluorescence detection. International Journal of Environmental Analytical Chemistry, 54(4): 299–314
Witkowski K M, Johnson N E (1992). Organic-solvent water pollution and low birth weight in Michigan. Social Biology, 39(1–2): 45–54
Wong Z C, Fan W Y, Chwee T S, Sullivan M B (2016). Modelling fluorescence lifetimes with TD-DFT: A case study with syn-bimanes. RSC Advances, 6(90): 87237–87245
Wu B, Zhang R, Cheng S P, Ford T, Li A M, Zhang X X (2011). Risk assessment of polycyclic aromatic hydrocarbons in aquatic ecosystems. Ecotoxicology, 20(5): 1124–1130
Yadav M K, Aryal R, Short M D, Saint C P (2019). Fluorescence excitation-emission spectroscopy: An analytical technique to monitor drugs of addiction in wastewater. Water (Basel), 11(2): 377
Yamin G, Borisover M, Cohen E, Van Rijn J (2017). Accumulation of humic-like and proteinaceous dissolved organic matter in zero-discharge aquaculture systems as revealed by fluorescence EEM spectroscopy. Water Research, 108: 412–421
Yan S, Yao B, Lian L, Lu X, Snyder S A, Li R, Song W (2017). Development of fluorescence surrogates to predict the photochemical transformation of pharmaceuticals in wastewater effluents. Environmental Science & Technology, 51(5): 2738–2747
Yang C, Li L, Shi J, Long C, Li A (2015a). Advanced treatment of textile dyeing secondary effluent using magnetic anion exchange resin and its effect on organic fouling in subsequent RO membrane. Journal of Hazardous Materials, 284: 50–57
Yang L, Han D H, Lee B M, Hur J (2015b). Characterizing treated wastewaters of different industries using clustered fluorescence EEM-PARAFAC and FT-IR spectroscopy: Implications for downstream impact and source identification. Chemosphere, 127: 222–228
Yang L, Hur J, Zhuang W (2015c). Occurrence and behaviors of fluorescence EEM-PARAFAC components in drinking water and wastewater treatment systems and their applications: A review. Environmental Science and Pollution Research, 22(9): 6500–6510
Zhang H, Wei X, Song X, Shah S, Chen J, Liu J, Chen Z (2018). Photophysical and photochemical insights into the photodegradation of sulfapyridine in water: A joint experimental and theoretical study. Chemosphere, 191: 1021–1027
Zhang Y Z, Yu T (2014). Quantitative characterization of Cu binding potential of dissolved organic matter (DOM) in sediment from Taihu Lake using multiple techniques. Frontiers of Environmental Science & Engineering, 8(5): 666–674
Acknowledgements
We are grateful for the financial support provided by the National Major Scientific Instrument Equipment Development Project (No. 2017YFF0408500).
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Highlights
• The fluorescence peak location of 14 compounds interpreted at protein-like region.
• The π-electron system inside aromatic ring contributes to the fluorophore region.
• Functional group variation effects the emission spectra.
• Decrease in quantum yield and increase in ΔE is due to atomic weight F>Cl>Br>I.
• Theoretically results are in line with experimental ones.
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Khan, M.F.S., Wu, J., Cheng, C. et al. Insight into fluorescence properties of 14 selected toxic single-ring aromatic compounds in water: Experimental and DFT study. Front. Environ. Sci. Eng. 14, 42 (2020). https://doi.org/10.1007/s11783-020-1219-z
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DOI: https://doi.org/10.1007/s11783-020-1219-z