[1] S S CHENG, S Y YE, C N APTE et al. Improving the Kumada catalyst transfer polymerization with water-scavenging Grignard reagents. Acs Macro Letters, 10, 697-701(2021).

[2] S PAWAR, U KUMAR, T A BHATTACHARYA et al. Functionalized chitosan-carbon dots: a fluorescent probe for detecting trace amount of water in organic solvents. Acs Omega, 4, 11301-11311(2019).

[3] M KOSFELD, B WESTPHAL, A KWADE. Correct water content measuring of lithium-ion battery components and the impact of calendering via Karl-Fischer titration. Journal of Energy Storage, 51, 104398(2022).

[4] B DENG, J Y FENG, N DUAN et al. A novel fluorescence probe for the detection of water content in organic solvents and the distinction between deuterated and nondeuterated reagents. Luminescence, 37, 1427-1435(2022).

[5] Y C WU, J Q JI, Y B ZHOU et al. Ratiometric and colorimetric sensors for highly sensitive detection of water in organic solvents based on hydroxyl-containing polyimide-fluoride complexes. Analytica Chimica Acta, 1108, 37-45(2020).

[6] B B LI, W J WANG, Z X HONG et al. Ratiometric fluorescence detection of trace water in an organic solvent based on bimetallic lanthanide metal-organic frameworks. Chemical Communications, 55, 6926-6929(2019).

[7] Y J CHEN, C Y ZHANG, J Y XIE et al. Covalent organic frameworks as a sensing platform for water in organic solvent over a broad concentration range. Analytica Chimica Acta, 1109, 114-121(2020).

[8] M J MO, X S WANG, L Y YE et al. A simple paper-based ratiometric luminescent sensor for tetracyclines using copper nanocluster-europium hybrid nanoprobes. Analytica Chimica Acta, 1190, 339257(2022).

[9] Zhenxin QING, Junchao CUI, Ming WEN et al. Synthesis of high-efficiency fluorescent carbon dots for the detection of metal ions. Acta Photonica Sinica, 49, 0616001(2020).

[10] H Y CUI, J YANG, H LU et al. Near-infrared carbon dots for cell imaging and detecting ciprofloxacin by label-free fluorescence sensor based on aptamer. Microchimica Acta, 189, 170-179(2022).

[11] Y Y NI, P Y ZHOU, Q W JIANG et al. Room-temperature phosphorescence based on chitosan carbon dots for trace water detection in organic solvents and anti-counterfeiting application. Dyes and Pigments, 197, 109923(2022).

[12] Z Y WU, X K LI, Y ZHAO et al. Organic semiconductor/carbon dot composites for highly efficient hydrogen and hydrogen peroxide coproduction from water photosplitting. Acs Applied Materials & Interfaces, 13, 60561-60570(2021).

[13] D Y CHAO, LYU W , Y B LIU et al. Solvent-dependent carbon dots and their applications in the detection of water in organic solvents. Journal of Materials Chemistry C, 6, 7527-7532(2018).

[14] B ZHI, X X YAO, Y CUI et al. Synthesis, applications and potential photoluminescence mechanism of spectrally tunable carbon dots. Nanoscale, 11, 20411-20428(2019).

[15] J F WEI, H K LI, Y YUAN et al. A sensitive fluorescent sensor for the detection of trace water in organic solvents based on carbon quantum dots with yellow fluorescence. Rsc Advances, 8, 37028-37034(2018).

[16] X W MU, X N SONG, D J GAO et al. Reversible fluorescent test strip with red fluorescent carbon dots for monitoring water in organic solvents: visual detection via a smartphone. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 276, 121195(2022).

[17] J J BAI, J J CUI, Y D MA et al. Orange emissive N-doped carbon dots and their application in detection of water in organic solvents and the polyurethane composites. Optical Materials, 123, 111927(2022).

[18] Z P HUO, W Q XU, Z Z WANG et al. A carbonized polymer dot (CPD) nanosensor for trace water detection with a wide detection range. Dyes and Pigments, 196, 109805(2021).

[19] J WANG, J Y WANG, W X XIAO et al. Lignin-derived red-emitting carbon dots for colorimetric and sensitive fluorometric detection of water in organic solvents. Analytical Methods, 12, 3218-3224(2020).

[20] R KUMARI, S K SAHU. Effect of solvent-derived highly luminescent multicolor carbon dots for white-light-emitting diodes and water detection. Langmuir, 36, 5287-5295(2020).

[21] X Y WANG, X M TENG, X B SUN et al. Carbon dots with aggregation induced quenching effect and solvatochromism for the detection of H2O in organic solvents. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 267, 120547(2022).

[22] X K XU, G Q HU, L Q MO et al. Red, orange, yellow and green luminescence by carbon dots: hydrogen-bond-induced solvation effects. Nanoscale, 13, 6846-6856(2021).

[23] C L YE, Y J QIN, P C HUANG et al. Facile synthesis of carbon nanodots with surface state-modulated fluorescence for highly sensitive and real-time detection of water in organic solvents. Analytica Chimica Acta, 1034, 144-152(2018).

[24] W KASPRZYK, T SWIERGOSZ, S BEDNARZ et al. Luminescence phenomena of carbon dots derived from citric acid and urea-a molecular insight. Nanoscale, 10, 13889-13894(2018).

[25] A SHARMA, T GADLY, S NEOGY et al. Molecular origin and self-assembly of fluorescent carbon nanodots in polar solvents. The Journal of Physical Chemistry Letters, 8, 1044-1052(2017).

[26] J JIA, W J LU, S CUI et al. N, Cl-doped carbon dots for fluorescence and colorimetric dual-mode detection of water in tetrahydrofuran and development of a paper-based sensor. Microchimica Acta, 188, 324-333(2021).

[27] B Y WANG, S Y LU. The light of carbon dots: from mechanism to applications. Matter, 5, 110-149(2022).

[28] Pengtao PAN, Fanyu ZOU, Junlei YIN. CarbonNanodots as fluorescent probe for detection of water content in organic solvents. Laser & Optoelectronics Progress, 57, 231602(2022).

[29] S KHAN, A GUPTA, N C VERMA et al. Time-resolved emission reveals ensemble of emissive states as the origin of multicolor fluorescence in carbon dots. Nano Letters, 15, 8300-8305(2015).

[30] H J LEE, J JANA, NGO Y L THI et al. The effect of solvent polarity on emission properties of carbon dots and their uses in colorimetric sensors for water and humidity. Materials Research Bulletin, 119, 110564(2019).