Page 35 - 《精细化工》2022年第8期
P. 35

第 8 期                     李   洁,等:  三基色荧光碳点制备及呈色特性的研究进展                                 ·1535·


            [20]  YE C Q, XU L, CHEN S R, et al. Controllable excitation-dependent   fluorescent carbon nanoparticles and their use as probes for sensitive
                 fluorescence triggered by the increasing graphitic nitrogen in carbon   and selective detection of mercury(Ⅱ) ions[J]. Analytical Chemistry,
                 dots and its application in multi-analyte detection[J]. Dyes  and   2012, 84(12): 5351-5357.
                 Pigments, 2021, 184: 108772.                  [39]  BARMAN M K, JANA B, BHATTACHARYYA S, et al.
            [21]  GE G L, LI L, WANG D, et al. Carbon dots: Synthesis, properties   Photophysical properties of doped carbon dots (N, P, and B) and their
                 and biomedical applications[J]. Journal of Materials Chemistry B,   influence on electron/hole transfer  in carbon dots-nickel( Ⅱ )
                 2021, 9(33): 6553-6575.                           phthalocyanine conjugates[J]. Journal of Physical Chemistry C,
            [22]  MUTHAMMA K, SUNIL D, SHETTY P. Carbon dots as emerging   2014, 118(34): 20034-20041.
                 luminophores in security inks for anti-counterfeit applications—An   [40]  WANG Z R (王子儒), ZHANG G H (张光华), GUO M Y (郭明媛).
                 up-to-date review[J]. Applied Materials Today, 2021, 23: 101050.     Preparation and  optical properties of  N-doped carbon  dots as light
            [23]  MONDAL T K, SAHA S K. Facile approach to synthesize nitrogen-   stabilizer[J]. Chinese Journal of Luminescence (发光学报), 2016,
                 and oxygen-rich carbon  quantum dots for pH sensor, fluorescent   37(6): 655-661.
                 indicator, and invisible ink applications[J]. ACS Sustainable   [41]  WANG C J, WANG Y B, SHI H X, et al. A strong blue fluorescent
                 Chemistry & Engineering, 2019, 7(24): 19669-19678.     nanoprobe for highly sensitive and selective detection of mercury(Ⅱ)
            [24]  FU Q, LONG C C, QIN L F, et  al.  Fluorescent and colorimetric   based on sulfur doped carbon quantum dots[J]. Materials Chemistry
                 dual-mode detection  of  tetracycline in wastewater based on   and Physics, 2019, 232: 145-151.
                 heteroatoms-doped reduced state carbon dots[J]. Environmental   [42]  YANG X P, XU J, LUO N, et al. N, Cl co-doped fluorescent carbon
                 Pollution, 2021, 283: 117109.                     dots as nanoprobe for detection of tartrazine in beverages[J]. Food
            [25]  CHAHAL S, MACAIRAN J R, YOUSEFI N, et al. Green synthesis   Chemistry, 2020, 310: 125832.
                 of carbon dots and their applications[J]. RSC Advances, 2021,   [43]  SAHU S, BEHERA B, MAITI T K, et al. Simple one-step synthesis
                 11(41): 25354-25363.                              of highly luminescent carbon dots from orange juice: Application as
            [26]  ZHAO J L, LUO Q Y, RUAN Q, et al. Red/green tunable-emission   excellent bio-imaging agents[J]. Chemical Communications,  2012,
                 carbon nanodots for smart visual precision pH sensing[J]. Chemistry   48(70): 8835-8837.
                 of Materials, 2021, 33(15): 6091-6098.        [44]  YIN B D, DENG J H, PENG X, et al. Green synthesis of carbon dots
            [27]  SOHAL N, MAITY B,  BASU S. Recent advances in heteroatom-   with down- and up-conversion  fluorescent properties  for sensitive
                 doped graphene quantum dots for sensing applications[J]. RSC   detection of hypochlorite with a dual-readout assay[J]. Analyst, 2013,
                 Advances, 2021, 11(41): 25586-25615.              138(21): 6551-6557.
            [28]  ZHOU J J, SHENG Z H,  HAN H  Y, et al.  Facile synthesis of   [45]  ZHU S J, MENG  Q N, WANG L, et  al.  Highly photoluminescent
                 fluorescent carbon dots using watermelon peel as a carbon source[J].   carbon dots for multicolor patterning, sensors, and bioimaging[J].
                 Materials Letters, 2012, 66(1): 222-224.          Angewandte Chemie International Edition, 2013, 52(14): 3953-3957.
            [29]  DONG  Y Q, WANG R X, LI H, et al.  Polyamine-functionalized   [46]  LI W (李伟), TONG G  B (佟国宾), WANG M  R  (王梦茹), et al.
                 carbon quantum dots for chemical sensing[J]. Carbon, 2012, 50(8):   Preparation of the alkaline lignin pyrolytic based carbon quantum
                 2810-2815.                                        dots/TiO 2 composite photocatalyst[J]. Journal of Forestry
            [30]  NAIK V M, GUNJAL D B, GORE A H, et al. Quick and low cost   Engineering (林业工程学报), 2016, 1(5): 84-88.
                 synthesis of sulphur doped carbon dots by simple acidic   [47]  SHEN C, GE S Y, PANG Y Y, et al. Facile and scalable preparation
                                                3+
                 carbonization of sucrose for  the detection of  Fe  ions in highly   of highly luminescent N, S co-doped graphene quantum dots and
                 acidic environment[J]. Diamond and  Related Materials,  2018, 88:   their application for parallel detection of multiple metal ions[J].
                 262-268.                                          Journal of Materials Chemistry B, 2017, 5(32): 6593-6600.
            [31]  TIAN H, JU G X, LI M T, et al. Fluorescent "on-off-on" sensor based   [48]  FANG Y X,  GUO S J, LI D, et al.  Easy synthesis and imaging
                 on N, S co-doped carbon dots from seaweed (Sargassum   applications of cross-linked green fluorescent hollow carbon
                 carpophyllum) for specific detection of Cr(Ⅵ) and ascorbic acid[J].   nanoparticles[J]. ACS Nano, 2012, 6(1): 400-409.
                 RSC Advances, 2021, 11(57): 35946-35953.      [49]  KHAN W U, WANG D Y,  ZHANG  W, et al. High quantum yield
            [32]  XIA C L,  ZHU S  J, FENG T L, et al.  Evolution and synthesis  of   green-emitting carbon dots for Fe(Ⅲ) detection,  biocompatible
                 carbon dots: From carbon dots to  carbonized polymer dots[J].   fluorescent ink and cellular imaging[J]. Scientific Reports, 2017, 7:
                 Advanced Science, 2019, 6(23): 1901316.           14866.
            [33]  ZHU H,  WANG  X L, LI  Y L, et  al.  Microwave synthesis  of   [50]  MITRA S, CHANDRA S, KUNDU T, et al.  Rapid microwave
                 fluorescent carbon nanoparticles with electrochemiluminescence   synthesis of fluorescent hydrophobic carbon dots[J]. RSC Advances,
                 properties[J]. Chemical Communications, 2009, (34): 5118-5120.     2012, 2(32): 12129-12131.
            [34]  ZHAI X Y,  ZHANG P, LIU C J, et al. Highly luminescent carbon   [51]  LIU Y, XIAO N,  GONG  N Q, et al.  One-step microwave-assisted
                 nanodots by microwave-assisted pyrolysis[J]. Chemical Communications,   polyol synthesis of green luminescent carbon dots as optical
                 2012, 48(64): 7955-7957.                          nanoprobes[J]. Carbon, 2014, 68: 258-264.
            [35]  SHI Y P, PAN Y, ZHANG H, et al. A dual-mode nanosensor based on   [52]  ZHANG J  L (张俊莉), ZHAO X W (赵雪微), JIA J (贾晶), et al.
                 carbon  quantum dots and gold nanoparticles  for discriminative   Rapidly macroscopic preparation  of green luminescent carbon dots
                 detection of glutathione in human plasma[J]. Biosensors &   for cell imaging[J]. Journal of Shanxi University (Natural Science
                 Bioelectronics, 2014, 56: 39-45.                  Edition) (山西大学学报:  自然科学版), 2019, 42(1): 195-201.
            [36]  JIA X, HAN Y, PEI M L, et al. Multi-functionalized hyaluronic acid   [53]  WANG L  (王莉), LYU T (吕婷),  RUAN F T (阮枫萍), et al.
                 nanogels crosslinked with carbon  dots as  dual receptor-mediated   Synthesis of photoluminescent carbon nanoparticles by hydrothermal
                 targeting tumor theranostics[J]. Carbohydrate Polymers,  2016, 152:   method[J]. Chinese Journal of Luminescence (发光学报), 2014,
                 391-397.                                          35(6): 706-709.
            [37]  ZHANG Y Q, LIU X Y, FAN Y, et al. One-step microwave synthesis   [54]  XU J, WANG C L, LI H Z, et al. Synthesis of green-emitting carbon
                 of N-doped hydroxyl-functionalized carbon dots with ultra-high   quantum dots with double carbon sources and their application as a
                                                                                                  2+
                 fluorescence quantum  yields[J]. Nanoscale, 2016, 8(33): 15281-   fluorescent probe for selective detection of Cu  ions[J]. RSC
                 15287.                                            Advances, 2020, 10(5): 2536-2544.
            [38]  LU W B,  QIN X  Y, LIU S, et al.  Economical, green synthesis  of   [55]  ZHANG J C, SHEN W Q, PAN D Y, et al. Controlled synthesis of
   30   31   32   33   34   35   36   37   38   39   40