[[1]]

Niu WJ, Li Y, Zhu RH, et al. Ethylenediamine-assisted hydrothermal synthesis of nitrogen-doped carbon quantum dots as fluorescent probes for sensitive biosensing and bioimaging. Sensor Actuat B Chem 2015;218(8):229-236.

[[2]]

Wu FS, Su HF, Wang K, et al. Facile synthesis of N-rich carbon quantum dots from porphyrins as efficient probes for bioimaging and biosensing in living cells. Int J Nanomedicine 2017;12(8):7375-7391.

[[3]]

Singh V, Rawat KS, Mishra S, et al. Biocompatible fluorescent carbon quantum dots prepared from beetroot extract for in vivo live imaging in C-elegans and BALB/c mice. J Mater Chem B 2018;6(20):3366-3371.

[[4]]

Zhang M, Wang WT, Zhou NL, et al. Near-infrared light triggered photo-therapy, in combination with chemotherapy using magnetofluorescent carbon quantum dots for effective cancer treating. Carbon 2017;118(7):752-764.

[[5]]

Lu SM, Li GL, Lyu ZX, et al. Facile and ultrasensitive fluorescence sensor platform for tumor invasive biomaker beta-glucuronidase detection and inhibitor evaluation with carbon quantum dots based on inner-filter effect. Biosens Bioelectron 2016;85(12):358-362.

[[6]]

Zhang M, Wang J, Wang WT, et al. Magnetofluorescent photothermal micelles packaged with GdN@CQDs as photothermal and chemical dual-modal therapeutic agents. Chem Eng J 2017;330(12):442-452.

[[7]]

Chiu SH, Gedda G, Girma WM, et al. Rapid fabrication of carbon quantum dots as multifunctional nanovehicles for dual-modal targeted imaging and chemotherapy. Acta Biomat 2016;46(12):151-164.

[[8]]

Zhang YQ, Ma DK, Zhang YG, et al. N-doped carbon quantum dots for TiO2-based photocatalysts and dye-sensitized solar cells. Nano Energy 2013;2(5):545-552.

[[9]]

Kong WQ, Liu J, Liu RH, et al. Quantitative and real-time effects of carbon quantum dots on single living HeLa cell membrane permeability. Nanoscale 2014;6(10):5116-5120.

[[10]]

Qiang R, Yang S, Hou K, et al. Synthesis of carbon quantum dots with green luminescence from potato starch. New J Chem 2019;43(27):10826-10833.

[[11]]

Alam AM, Park BY, Ghouri ZK, et al. Synthesis of carbon quantum dots from cabbage with down- and up-conversion photoluminescence properties: excellent imaging agent for biomedical applications. Green Chem 2015;17(7):3791-3797.

[[12]]

Mehta VN, Jha S, Kailasa SK. One-pot green synthesis of carbon dots by using Saccharum officinarum juice for fluorescent imaging of bacteria (Escherichia coli) and yeast (Saccharomyces cerevisiae) cells. Mater Sci Eng C Mater Biol Appl 2014;38(9):20-27.

[[13]]

Yadav PK, Singh VK, Chandra S, et al. Green synthesis of fluorescent carbon quantum dots from Azadirachta indica leaves and their peroxidase-mimetic activity for the detection of H2O2 and ascorbic acid in common fresh fruits. ACS Biomater Sci Eng 2019;5(2):623-632.

[[14]]

Sabet M, Mahdavi K. Green synthesis of high photoluminescence nitrogen-doped carbon quantum dots from grass via a simple hydrothermal method for removing organic and inorganic water pollutions. Appl Surf Sci 2019;436(1):283-291.

[[15]]

Gunjal DB, Gurav YM, Gore AH, et al. Nitrogen doped waste tea residue derived carbon dots for selective quantification of tetracycline in urine and pharmaceutical samples and yeast cell imaging application. Opt Mater 2019;98(12):109484.

[[16]]

Wang CJ, Shi HX, Yang M, et al. Facile synthesis of novel carbon quantum dots from biomass waste for highly sensitive detection of iron ions. Mater Res Bull 2020;124(4):110730. 1-110730.8.

[[17]]

Hu YP, Gao ZJ. Sewage sludge in microwave oven: a sustainable synthetic approach toward carbon dots for fluorescent sensing of para-Nitrophenol. J Hazard Mater 2020;382(1):121048.

[[18]]

Wang BB, Jin JC, Xu ZQ, et al. Single-step synthesis of highly photoluminescent carbon dots for rapid detection of Hg2+ with excellent sensitivity. J Colloid Interface Sci 2019;551(9):101-110.

[[19]]

Shang J, Zhang HR. Preparation of nitrogen doped carbon quantum dots and flavonoids analysis in Chinese herbal medicine. Shandong Chem Ind 2018;47(1):61-63.

[[20]]

Han Z, He L, Pan S, et al. Hydrothermal synthesis of carbon dots and their application for detection of chlorogenic acid. Luminescence 2020;35(7):989-997.

[[21]]

Liang JY, Han L, Liu SG, et al. Carbon dots-based fluorescent turn off/on sensor for highly selective and sensitive detection of Hg2+ and biothiols. Spectrochim Acta A 2019;222(80):117260.

[[22]]

Zhang J, Nan D, Pan S, et al. N.S co-doped carbon dots as a dual-functional fluorescent sensor for sensitive detection of baicalein and temperature. Spectrochim Acta A 2019;221(11):117161.

[[23]]

Xu XY, Ray R, Gu YL, et al. Electrophoretic analysis and purification of fluorescent single-walled carbon nanotube fragments. J Am Chem Soc 2004;126(40):12736-12737.

[[24]]

Sun Y-P, Zhou B, Lin Y, et al. Quantum-sized carbon dots for bright and colorful photoluminescence. J Am Chem Soc 2006;128(24):7756-7757.

[[25]]

Hu SL, Niu KY, Sun J, et al. One-step synthesis of fluorescent carbon nanoparticles by laser irradiation. J Mater Chem 2009;19(4):484-488.

[[26]]

Goncalves H, Jorge PAS, Fernandes JRA, et al. Hg(II) sensing based on functionalized carbon dots obtained by direct laser ablation. Sensor Actuat B Chem 2010;145(2):702-707.

[[27]]

Nguyen V, Yan LH, Si JH, et al. Femtosecond laser-assisted synthesis of highly photoluminescent carbon nanodots for Fe3+ detection with high sensitivity and selectivity. Opt Mater Express 2016;6(2):312-320.

[[28]]

Ren X, Zhang F, Guo BP, et al. Synthesis of N-doped micropore carbon quantum dots with high quantum yield and dual-wavelength photoluminescence emission from biomass for cellular imaging. Nanomaterials 2019;9(4):495.

[[29]]

Hou YX, Lu QJ, Deng JH, et al. One-pot electrochemical synthesis of functionalized fluorescent carbon dots and their selective sensing for mercury ion. Anal Chim Acta 2015;866(3):69-74.

[[30]]

Yao S, Hu YF, Li GK. A one-step sonoelectrochemical preparation method of pure blue fluorescent carbon nanoparticles under a high intensity electric field. Carbon 2014;66(66):77-83.

[[31]]

Patra S, Roy E, Madhuri R, et al. Economic and ecofriendly synthesis of biocompatible heteroatom doped carbon nanodots for graphene oxide assay and live cell imaging. ACS Sustain Chem Eng 2016;4(3):1463-1473.

[[32]]

Liu RH, Huang H, Li HT, et al. Metal nanoparticle/carbon quantum dot composite as a photocatalyst for high-efficiency cyclohexane oxidation. ACS Catal 2014;4(1):328-336.

[[33]]

Lopez C, Zougagh M, Algarra M, et al. Microwave-assisted synthesis of carbon dots and its potential as analysis of four heterocyclic aromatic amines. Talanta 2015;132(1):845-850.

[[34]]

Wang L, Bi YD, Hou J, et al. Facile, green and clean one-step synthesis of carbon dots from wool: application as a sensor for glyphosate detection based on the inner filter effect. Talanta 2016;160(11):268-275.

[[35]]

Huang QT, Li Q, Chen YF, et al. High quantum yield nitrogen-doped carbon dots: green synthesis and application as “off-on” fluorescent sensors for the determination of Fe3+ and adenosine triphosphate in biological samples. Sensor Actuat B Chem 2018;276(12):82-88.

[[36]]

Li HY, Xu Y, Ding J, et al. Microwave-assisted synthesis of highly luminescent N- and S-co-doped carbon dots as a ratiometric fluorescent probe for levofloxacin. Microchim Acta 2018;185(2):7.

[[37]]

Konar S, Kumar BNP, Mahto MK, et al. N-doped carbon dot as fluorescent probe for detection of cysteamine and multicolor cell imaging. Sensor Actuat B Chem 2019;286(5):77-85.

[[38]]

Edison T, Atchudan R, Sethuraman MG, et al. Microwave assisted green synthesis of fluorescent N-doped carbon dots: cytotoxicity and bio-imaging applications. J Photochem Photobiol B 2016;161(8):154-161.

[[39]]

Ding YY, Gong XJ, Liu Y, et al. Facile preparation of bright orange fluorescent carbon dots and the constructed biosensing platform for the detection of pH in living cells. Talanta 2018;189(11):8-15.

[[40]]

Song ZY, Fu YJ, Liang YT, et al. Determination of rutin based on fluorescence quenching of carbon quantum dots. Guangzhou Chem Ind 2019;47(4):98-100.

[[41]]

Liu LZ, Mi Z, Hu Q, et al. Green synthesis of fluorescent carbon dots as an effective fluorescence probe for morin detection. Anal Methods 2019;11(3):353-358.

[[42]]

Li CS, Liu ZM, Zhang HR. Microwave synthesis of carbon quantum dots and its fluorescence quenching by quercetin. Shandong Chem Ind 2018;47(3):14-15.

[[43]]

Wu Y, Zhang HR. One step synthesis of carbonate quantum dots by microwave and its analytical application. Chem Ind Times 2018;32(1):5-8.

[[44]]

Li HH, Liu LZ, Feng F. Facile synthesis of fluorescence carbon quantum dots and their application in detection of isorhamnetin in medicines. J Instrum Anal 2020;39(4):514-519.

[[45]]

Liu L, Mi Z, Guo Z, et al. A label-free fluorescent sensor based on carbon quantum dots with enhanced sensitive for the determination of myricetin in real samples. Microchem J 2020;157(9):104956.

[[46]]

Guo Y, Wang Z, Shao H, et al. Hydrothermal synthesis of highly fluorescent carbon nanoparticles from sodium citrate and their use for the detection of mercury ions. Carbon 2013;52(2):583-589.

[[47]]

Shen T, Wang Q, Guo Z, et al. Hydrothermal synthesis of carbon quantum dots using different precursors and their combination with TiO(2) for enhanced photocatalytic activity. Ceram Int 2018;44(10):11828-11834.

[[48]]

Liu W, Diao HP, Chang HH, et al. Green synthesis of carbon dots from rose-heart radish and application for Fe3+ detection and cell imaging. Sensor Actuat B Chem 2017;241(4):190-198.

[[49]]

Zhang B, Liu C-Y, Liu Y. A novel one-step approach to synthesize fluorescent carbon nanoparticles. Eur J Inorg Chem 2010;(28):4411-4414.

[[50]]

Atchudan R, Edison TNJI, Aseer KR, et al. Highly fluorescent nitrogen-doped carbon dots derived from Phyllanthus acidus utilized as a fluorescent probe for label-free selective detection of Fe3+ ions, live cell imaging and fluorescent ink. Biosens Bioelectron 2018;99(1):303-311.

[[51]]

Shangguan J, Huang J, He D, et al. Highly Fe3+-selective fluorescent nanoprobe based on ultrabright N/P codoped carbon dots and its application in biological samples. Anal Chem 2017;89(14):7477-7484.

[[52]]

Wang L, Li BQ, Xu F, et al. High-yield synthesis of strong photoluminescent N-doped carbon nanodots derived from hydrosoluble chitosan for mercury ion sensing via smartphone APP. Biosens Bioelectron 2016;79(4):1-8.

[[53]]

Huang K, He Q, Sun RS, et al. Preparation and application of carbon dots derived from cherry blossom flowers. Chem Phys Lett 2019;731(9):136586.

[[54]]

Dordevic L, Arcudi F, Prato M. Preparation, functionalization and characterization of engineered carbon nanodots. Nat Protoc 2019;14(10):2931-2953.

[[55]]

Hua XW, Bao YW, Wu FG. Fluorescent carbon quantum dots with intrinsic nucleolus-targeting capability for nucleolus imaging and enhanced cytosolic and nuclear drug delivery. ACS Appl Mater Interfaces 2018;10(13):10664-10677.

[[56]]

Shen J, Shang SM, Chen XY, et al. Highly fluorescent N, S-co-doped carbon dots and their potential applications as antioxidants and sensitive probes for Cr (VI) detection. Sensor Actuat B Chem 2017;248(9):92-100.

[[57]]

Yang H, Yang L, Yuan YS, et al. A portable synthesis of water-soluble carbon dots for highly sensitive and selective detection of chlorogenic acid based on inner filter effect. Spectrochim Acta A Mol Biomol Spectrosc 2018;189(1):139-146.

[[58]]

Wu B, Liu X, Shi X, et al. Highly photoluminescent and temperature-sensitive P, N, B-co-doped carbon quantum dots and their highly sensitive recognition for curcumin. RSC Adv 2019;9(15):8340-8349.

[[59]]

Han Z, Zhang H, He L, et al. One-pot hydrothermal synthesis of nitrogen and sulfur co-doped carbon dots and their application for sensitive detection of curcumin and temperature. Microchem J 2019;146(5):300-308.

[[60]]

Sun QQ, Long YW, Li HX, et al. Fluorescent carbon dots as cost-effective and facile probes for caffeic acid sensing via a fluorescence quenching process. J Fluoresc 2018;28(2):523-531.

[[61]]

Li MX, Li YX, Zhang Y, et al. Determination of pyrogallic acid in amino-functional carbon quantum dots fluorescence quenching. Chin J Lumin 2017;(1):117-123.

[[62]]

Ni PJ, Dai HC, Li Z, et al. Carbon dots based fluorescent sensor for sensitive determination of hydroquinone. Talanta 2015;144(11):258-262.

[[63]]

Wu XL, Song Y, Yan X, et al. Carbon quantum dots as fluorescence resonance energy transfer sensors for organophosphate pesticides determination. Biosens Bioelectron 2017;94(8):292-297.

[[64]]

He JH, Cheng YY, Yang T, et al. Functional preserving carbon dots-based fluorescent probe for mercury (II) ions sensing in herbal medicines via coordination and electron transfer. Anal Chim Acta 2018;1035(9):203-210.

[[65]]

Li NL, Jia LP, Ma RN, et al. A novel sandwiched electrochemiluminescence immunosensor for the detection of carcinoembryonic antigen based on carbon quantum dots and signal amplification. Biosens Bioelectron 2017;89(12):453-460.

[[66]]

Jahanbakhshi M, Habibi B. A novel and facile synthesis of carbon quantum dots via salep hydrothermal treatment as the silver nanoparticles support: application to electroanalytical determination of H2O2 in fetal bovine serum. Biosens Bioelectron 2016;81(3):143-150.

[[67]]

Ke J, Li XY, Zhao QD, et al. Upconversion carbon quantum dots as visible light responsive component for efficient enhancement of photocatalytic performance. J Colloid Interface Sci 2017;496(6):425-433.

[[68]]

Zhang Y, Xiao YT, Zhang YJ, et al. Carbon quantum dots as fluorescence turn-off-on probe for detecting Fe3+ and ascorbic acid. J Nanosci Nanotechnol 2020;20(6):3340-3347.

[[69]]

Yang XP, Xu J, Luo N, et al. N,Cl co-doped fluorescent carbon dots as nanoprobe for detection of tartrazine in beverages. Food Chem 2020;310(4):125832.

[[70]]

Al-Hashimi B, Omer KM, Rahman HS. Inner filter effect (IFE) as a simple and selective sensing platform for detection of tetracycline using milk-based nitrogen-doped carbon nanodots as fluorescence probe. Arab J Chem 2020;13(4):5151-5159.

[[71]]

Liu YX, Wang WK, Tian Q, et al. Construction and application of a fluorescence sensor for forsythin. Chin J Anal Lab 2020;39(4):438-442.

[[72]]

Liu YS, Zhao YA, Zhang YY. One-step green synthesized fluorescent carbon nanodots from bamboo leaves for copper(II) ion detection. Sensor Actuat B Chem 2014;196(6):647-652.

[[73]]

Dager A, Uchida T, Maekawa T, et al. Synthesis and characterization of mono-disperse carbon quantum dots from fennel seeds: photoluminescence analysis using machine learning. Sci Rep 2019;9(9):14004.

[[74]]

Hao J, Li LY, Zhao WW, et al. Synthesis and application of CCQDs as a novel type of environmentally friendly scale inhibitor. ACS Appl Mater Interfaces 2019;11(9):9277-9282.

[[75]]

Jiao XY, Li LS, Qin S, et al. The synthesis of fluorescent carbon dots from mango peel and their multiple applications. Colloids Surf A Physicochem Eng Asp 2019;577(9):306-314.

[[76]]

Ahmed GHG, Laino RB, Calzon JAG, et al. Fluorescent carbon nanodots for sensitive and selective detection of tannic acid in wines. Talanta 2015;132(1):252-257.

[[77]]

Liu L, Feng F, Paau MC, et al. Sensitive determination of kaempferol using carbon dots as a fluorescence probe. Talanta 2015;144(11):390-397.

[[78]]

Liu L, Mi Z, Hu Q, et al. One-step synthesis of fluorescent carbon dots for sensitive and selective detection of hyperin. Talanta 2018;186(8):315-321.

[[79]]

Larsson T, Wedborg M, Turner D. Correction of inner-filter effect in fluorescence excitation-emission matrix spectrometry using Raman scatter. Anal Chim Acta 2007;583(2):357-363.

[[80]]

Li GL, Fu HL, Chen XJ, et al. Facile and sensitive fluorescence sensing of alkaline phosphatase activity with photoluminescent carbon dots based on inner filter effect. Anal Chem 2016;88(5):2720-2726.

[[81]]

Zu FL, Yan FY, Bai ZJ, et al. The quenching of the fluorescence of carbon dots: a review on mechanisms and applications. Microchim Acta 2017;184(7):1899-1914.

[[82]]

Huang S, Wang LM, Huang CS, et al. A carbon dots based fluorescent probe for selective and sensitive detection of hemoglobin. Sensor Actuat B Chem 2015;221(12):1215-1222.

[[83]]

Yang H, Long YW, Li HX, et al. Carbon dots synthesized by hydrothermal process via sodium citrate and NH4HCO3 for sensitive detection of temperature and sunset yellow. J Colloid Interface Sci 2018;516(4):192-201.

[[84]]

Lim SY, Shen W, Gao ZQ. Carbon quantum dots and their applications. Chem Soc Rev 2015;44(1):362-381.