[1]	Rahman MM, Karim MR, Alharbi HF, Aldokhayel B, Uzzaman T, Zahir H. Cadmium selenide quantum dots for solar cell applications: a review. Chem Asian J. 2021; 16 (8): 902- 921.

[2]	Huang X, Li L, Qian H, Dong C, Ren J. A resonance energy transfer between chemiluminescent donors and luminescent quantum-dots as acceptors (CRET). Angew Chem Int Ed. 2006; 45 (31): 5140- 5143.

[3]	Xu S, Li J, Li X, et al. A chemiluminescence resonance energy transfer system composed of cobalt(II), luminol, hydrogen peroxide and CdTe quantum dots for highly sensitive determination of hydroquinone. Microchim Acta. 2016; 183 (2): 667- 673.

[4]	Du J, Wang Y, Zhang W. Gold nanoparticles-based chemiluminescence resonance energy transfer for ultrasensitive detection of melamine. Spectrochim Acta Part A. 2015; 149: 698- 702.

[5]	Huang X, Liang Y, Ruan L, Ren J. Chemiluminescent detection of cell apoptosis enzyme by gold nanoparticle-based resonance energy transfer assay. Anal Bioanal Chem. 2014; 406 (23): 5677- 5684.

[6]	Pang C, Han S, Li Y, Zhang J. Graphene quantum dot-enhanced chemiluminescence through energy and electron transfer for the sensitive detection of tyrosine. J Chin Chem Soc. 2018; 65 (12): 1504- 1509.

[7]	Xia H, Zheng X, Li J, et al. Identifying luminol electrochemiluminescence at the cathode via single-atom catalysts tuned oxygen reduction reaction. J Am Chem Soc. 2022; 144 (17): 7741- 7749.

[8]	Aiga F, Tada T. Design of novel efficient sensitizing dye for nanocrystalline TiO2 solar cell; tripyridine-thiolato (4,4′,4″-tricarboxy-2,2′:6′,2″-terpyridine)ruthenium(II). Sol Energy Mater Sol Cells. 2005; 85 (3): 437- 446.

[9]	Yin Z, Zhu L, Lv Z, Li M, Tang D. Persistent luminescence nanorods-based autofluorescence-free biosensor for prostate-specific antigen detection. Talanta. 2021; 233: 122563.

[10]	Yu Z, Gong H, Li Y, et al. Chemiluminescence-derived self-powered photoelectrochemical immunoassay for detecting a low-abundance disease-related protein. Anal Chem. 2021; 93 (39): 13389- 13397.

[11]	Zhang K, Lv S, Zhou Q, Tang D. CoOOH nanosheets-coated g-C3N4/CuInS2 nanohybrids for photoelectrochemical biosensor of carcinoembryonic antigen coupling hybridization chain reaction with etching reaction. Sens Actuator B. 2020; 307: 127631.

[12]	Zhang K, Lv S, Lin Z, Tang D. CdS:Mn quantum dot-functionalized g-C3N4 nanohybrids as signal-generation tags for photoelectrochemical immunoassay of prostate specific antigen coupling DNAzyme concatamer with enzymatic biocatalytic precipitation. Biosens Bioelectron. 2017; 95: 34- 40.

[13]	Zhuang J, Lai W, Xu M, Zhou Q, Tang D. Plasmonic AuNP/g‑C3N4 nanohybrid-based photoelectrochemical sensing platform for ultrasensitive monitoring of polynucleotide kinase activity accompanying DNAzyme-Catalyzed precipitation amplification. ACS Appl Mater Interfaces. 2015; 7 (15): 8330- 8338.

[14]	Yu Z, Tang D. Artificial neural network-assisted wearable flexible sweat patch for drug management in Parkinson's patients based on vacancy-engineered processing of g-C3N4. Anal Chem. 2022; 94 (51): 18000- 18008.

[15]	Jin-Bao C, Kai-Ning L, Xiao-Fang L, Jia-Jie F, Kang-Le L. Preparation and modification of crystalline carbon nitride. Chin J Inorg Chem. 2021; 37 (10): 1713- 1726.

[16]	Liu S, Sun H, O'Donnell K, Ang HM, Tade MO, Wang S. Metal-free melem/g-C3N4 hybrid photocatalysts for water treatment. J Colloid Interface Sci. 2016; 464: 10- 17.

[17]	Cohen ML. Calculation of bulk moduli of diamond and zinc-blende solids. Phys Rev B. 1985; 32 (12): 7988- 7991.

[18]

Jürgens B, Irran E, Senker J, Kroll P, Müller H, Schnick W. Melem (2,5,8-triamino-tri-s -triazine), an important intermediate during condensation of melamine rings to graphitic carbon nitride: synthesis, structure determination by X-ray powder diffractometry, solid-state NMR, and theoretical studies. J Am Chem Soc. 2003; 125 (34): 10288- 10300.

[19]	Vinu A, Ariga K, Mori T, et al. Preparation and characterization of well-ordered hexagonal mesoporous carbon nitride. Adv Mater. 2005; 17 (13): 1648- 1652.

[20]	Wang X, Maeda K, Chen X, et al. Polymer semiconductors for artificial photosynthesis: hydrogen evolution by mesoporous graphitic carbon nitride with visible light. J Am Chem Soc. 2009; 131 (5): 1680- 1681.

[21]	Dong F, Wang Z, Sun Y, Ho WK, Zhang H. Engineering the nanoarchitecture and texture of polymeric carbon nitride semiconductor for enhanced visible light photocatalytic activity. J Colloid Interface Sci. 2013; 401: 70- 79.

[22]	Zhang Y, Pan Q, Chai G, et al. Synthesis and luminescence mechanism of multicolor-emitting g-C3N4 nanopowders by low temperature thermal condensation of melamine. Sci Rep. 2013; 3 (1): 1943.

[23]	Yang H, Wang Z, Liu S, Shen Y, Zhang Y. Molecular engineering of CxNy: topologies, electronic structures and multidisciplinary applications. Chin Chem Lett. 2020; 31 (12): 3047- 3054.

[24]	Mahmood J, Lee EK, Jung M, et al. Nitrogenated holey two-dimensional structures. Nat Commun. 2015; 6: 6486.

[25]	Mahmood J, Lee EK, Jung M, et al. Two-dimensional polyaniline (C3N) from carbonized organic single crystals in solid state. Proc Natl Acad Sci USA. 2016; 113 (27): 7414- 7419.

[26]	Yang H, Zhou Q, Fang Z, et al. Carbon nitride of five-membered rings with low optical bandgap for photoelectrochemical biosensing. Chem. 2021; 7 (10): 2708- 2721.

[27]	Feng J, Li M. Large-scale synthesis of a new polymeric carbon nitride-C3N3 with good photoelectrochemical performance. Adv Funct Mater. 2020; 30 (23): 2001502.

[28]	Zhou G, Shan Y, Hu Y, et al. Half-metallic carbon nitride nanosheets with micro grid mode resonance structure for efficient photocatalytic hydrogen evolution. Nat Commun. 2018; 9: 3366.

[29]	Kumar P, Vahidzadeh E, Thakur UK, et al. C3N5: a low bandgap semiconductor containing an azo-linked carbon nitride framework for photocatalytic, photovoltaic and adsorbent applications. J Am Chem Soc. 2019; 141 (13): 5415- 5436.

[30]	Kim IY, Kim S, Jin X, et al. Ordered mesoporous C3N5 with a combined triazole and triazine framework and its graphene hybrids for the oxygen reduction reaction (ORR). Angew Chem. 2018; 130 (52): 17381- 17386.

[31]	Ma J, Peng X, Zhou Z, et al. Extended conjugation tuning carbon nitride for non-sacrificial H2O2 photosynthesis and hypoxic tumor therapy. Angew Chem Int Ed. 2022; 61 (43): e202210856.

[32]	Hong Q, Yang H, Fang Y, et al. Adaptable graphitic C6N6-based copper single-atom catalyst for intelligent biosensing. Nat Commun. 2023; 14: 2780.

[33]	Mane GP, Talapaneni SN, Lakhi KS, et al. Highly ordered nitrogen-rich mesoporous carbon nitrides and their superior performance for sensing and photocatalytic hydrogen generation. Angew Chem Int Ed. 2017; 56 (29): 8481- 8485.

[34]	Talapaneni SN, Mane GP, Mano A, et al. Synthesis of nitrogen-rich mesoporous carbon nitride with tunable pores, band gaps and nitrogen content from a single aminoguanidine precursor. ChemSusChem. 2012; 5 (4): 700- 708.

[35]	Kim IY, Kim S, Premkumar S, Yang JH, Umapathy S, Vinu A. Thermodynamically stable mesoporous C3N7 and C3N6 with ordered structure and their excellent performance for oxygen reduction reaction. Small. 2020; 16 (12): 1903572.

[36]	Ruban SM, Sathish CI, Ramadass K, et al. Ordered mesoporous carbon nitrides with tuneable nitrogen contents and basicity for knoevenagel condensation. ChemCatChem. 2021; 13 (1): 468- 474.

[37]	Zheng HB, Chen W, Gao H, et al. Melem: an efficient metal-free luminescent material. J Mater Chem C. 2017; 5 (41): 10746- 10753.

[38]	Li X, Zhang Y, Wei M, Wang M, Wang J, Zuo G. A rod-like melem with high fluorescence quantum yield for sensitive detection of reduced glutathione. Spectrochim Acta Part A. 2022; 282: 121709.

[39]	Kang Y, Yang Y, Yin LC, Kang X, Liu G, Cheng HM. An amorphous carbon nitride photocatalyst with greatly extended visible-light-responsive range for photocatalytic hydrogen generation. Adv Mater. 2015; 27 (31): 4572- 4577.

[40]	Zou R, Lin Y, Lu C. Nitrogen vacancy engineering in graphitic carbon nitride for strong, stable, and wavelength tunable electrochemiluminescence emissions. Anal Chem. 2021; 93 (4): 2678- 2686.

[41]	Liu L, Zhu Y, Wang H, Zhang Y, Chai Y, Yuan R. Enhanced electrochemiluminescence of graphitic carbon nitride by adjustment of carbon vacancy for supersensitive detection of microRNA. Anal Chem. 2022; 94 (36): 12444- 12451.

[42]	Dai X, Han Z, Fan H, Ai S. Sulfur doped carbon nitride quantum dots with efficient fluorescent property and their application for bioimaging. J Nanopart Res. 2018; 20 (12): 315.

[43]	Guo S, Zheng L, He W, et al. S,O-doped carbon nitride as a fluorescence probe for the label-free detection of folic acid and targeted cancer cell imaging. Arabian J Chem. 2023; 16 (3): 104520.

[44]	Zhao HM, Sun T, Wang J, Xu AJ, Jia ML, Xue B. Phosphorus-doped oligomeric carbon nitride for selective fluorescence detection of mercury (II) ions. Dyes Pigm. 2022; 207: 110739.

[45]	Li B, Zhang J, Luo Z, et al. Amorphous B-doped graphitic carbon nitride quantum dots with high photoluminescence quantum yield of near 90% and their sensitive detection of Fe2+/Cd2+. Sci China Mater. 2021; 64 (12): 3037- 3050.

[46]	Wang N, Fan H, Sun J, Han Z, Dong J, Ai S. Fluorine-doped carbon nitride quantum dots: ethylene glycol-assisted synthesis, fluorescent properties, and their application for bacterial imaging. Carbon. 2016; 109: 141- 148.

[47]	Zhang SQ, Liu X, Sun QX, Chen ML, Wang JH. Terbium doping of graphitic carbon nitride endows a highly sensitive ratiometric fluorescence assay of alkaline phosphatase. Chem Commun. 2021; 57 (70): 8746- 8749.

[48]	Yang H, Li X, Wang X, Chen W, Bian W, Choi MMF. Silver-doped graphite carbon nitride nanosheets as fluorescent probe for the detection of curcumin. Luminescence. 2018; 33 (6): 1062- 1069.

[49]	Yang H, Zhou Q, Fang Z, et al. Carbon nitride of five-membered rings with low optical bandgap for photoelectrochemical biosensing. Chem. 2021; 7 (10): 2708- 2721.

[50]	Akaike K, Hosokai A, Tajima K, Akiyama H, Nagashima H. Insights into chemical reactions of graphitic carbon nitride with alkali halides. J Phys Energy. 2023; 5 (1): 014007.

[51]	Liu J, Zhang T, Wang Z, Dawson G, Chen W. Simple pyrolysis of urea into graphitic carbon nitride with recyclable adsorption and photocatalytic activity. J Mater Chem. 2011; 21 (38): 14398- 14410.

[52]	Cui Y, Ding Z, Liu P, Antonietti M, Fu X, Wang X. Metal-free activation of H2O2 by g-C3N4 under visible light irradiation for the degradation of organic pollutants. Phys Chem Chem Phys. 2012; 14 (4): 1455- 1462.

[53]	Chen Y, Li J, Hong Z, Shen B, Lin B, Gao B. Origin of the enhanced visible-light photocatalytic activity of CNT modified g-C3N4 for H2 production. Phys Chem Chem Phys. 2014; 16 (17): 8106- 8113.

[54]	Zhao Y, Liu Z, Chu W, et al. Large-scale synthesis of nitrogen-rich carbon nitride microfibers by using graphitic carbon nitride as precursor. Adv Mater. 2008; 20 (9): 1777- 1781.

[55]	Li H, Li J, Ai Z, Jia F, Zhang L. Oxygen vacancy-mediated photocatalysis of BiOCL: reactivity, selectivity, and perspectives. Angew Chem Int Ed. 2018; 57 (1): 122- 138.

[56]	Nowotny J, Alim MA, Bak T, et al. Defect chemistry and defect engineering of TiO2-based semiconductors for solar energy conversion. Chem Soc Rev. 2015; 44 (23): 8424- 8442.

[57]	Zhang W, Yin J, Chen C, Qiu X. Carbon nitride derived nitrogen-doped carbon nanosheets for high-rate lithium-ion storage. Chem Eng Sci. 2021; 241: 116709.

[58]	He T, Tu M, Zhang J, Kong L, Ran F. Nanoparticles of iron nitride encapsulated in nitrogen-doped carbon bulk derived from polyaniline/Fe2O3 blends and its electrochemical performance. Part Part Syst Charact. 2020; 37 (7): 2000132.

[59]	Chen J, Mao Z, Zhang L, et al. Nitrogen-deficient graphitic carbon nitride with enhanced performance for lithium ion battery anodes. ACS Nano. 2017; 11 (12): 12650- 12657.

[60]	Liu G, Zhao G, Zhou W, et al. In situ bond modulation of graphitic carbon nitride to construct p-n homojunctions for enhanced photocatalytic hydrogen production. Adv Funct Mater. 2016; 26 (37): 6822- 6829.

[61]	Niu P, Yin LC, Yang YQ, Liu G, Cheng HM. Increasing the visible light absorption of graphitic carbon nitride (melon) photocatalysts by homogeneous self-modification with nitrogen vacancies. Adv Mater. 2014; 26 (47): 8046- 8052.

[62]	Lv C, Qian Y, Yan C, et al. Defect engineering metal-free polymeric carbon nitride electrocatalyst for effective nitrogen fixation under ambient conditions. Angew Chem. 2018; 130 (32): 10403- 10407.

[63]	Chen X, Liu L, Huang F. Black titanium dioxide (TiO2) nanomaterials. Chem Soc Rev. 2015; 44 (7): 1861- 1885.

[64]	Li X, Hartley G, Ward AJ, Young PA, Masters AF, Maschmeyer T. Hydrogenated defects in graphitic carbon nitride nanosheets for improved photocatalytic hydrogen evolution. J Phys Chem C. 2015; 119 (27): 14938- 14946.

[65]	Wang T, Nie C, Ao Z, Wang S, An T. Recent progress in g-C3N4 quantum dots: synthesis, properties and applications in photocatalytic degradation of organic pollutants. J Mater Chem A. 2020; 8 (2): 485- 502.

[66]	Rahman MZ, Davey K, Mullins CB. Tuning the intrinsic properties of carbon nitride for high quantum yield photocatalytic hydrogen production. Adv Sci. 2018; 5 (10): 1800820.

[67]	Zhang W, Xu D, Wang F, Chen M. Element-doped graphitic carbon nitride: confirmation of doped elements and applications. Nanoscale Adv. 2021; 3 (15): 4370- 4387.

[68]	Lv S, Zhang K, Zhou Q, Tang D. Plasmonic enhanced photoelectrochemical aptasensor with D-A F8BT/g-C3N4 heterojunction and AuNPs on a 3D-printed device. Sens Actuator B. 2020; 310: 127874.

[69]	Qiu Z, Shu J, Tang D. Plasmonic resonance enhanced photoelectrochemical aptasensors based on g-C3N4/Bi2MoO6. Chem Commun. 2018; 54 (52): 7199- 7202.

[70]	Lv Z, Zhu L, Yin Z, Li M, Tang D. Signal-on photoelectrochemical immunoassay mediated by the etching reaction of oxygen/phosphorus co-doped g-C3N4/AgBr/MnO2 nanohybrids. Anal Chim Acta. 2021; 1171: 338680.

[71]	Lv S, Li Y, Zhang K, Lin Z, Tang D. Carbon dots/g-C3N4 nanoheterostructures-based signal-generation tags for photoelectrochemical immunoassay of cancer biomarkers coupling with copper nanoclusters. ACS Appl Mater Interfaces. 2017; 9 (44): 38336- 38343.

[72]	Xia P, Antonietti M, Zhu B, Heil T, Yu J, Cao S. Designing defective crystalline carbon nitride to enable selective CO2 photoreduction in the gas phase. Adv Funct Mater. 2019; 29 (15): 1900093.

[73]	Shalom M, Inal S, Fettkenhauer C, Neher D, Antonietti M. Improving carbon nitride photocatalysis by supramolecular preorganization of monomers. J Am Chem Soc. 2013; 135 (19): 7118- 7121.

[74]	Zhang G, Li G, Lan ZA, et al. Optimizing optical absorption, exciton dissociation, and charge transfer of a polymeric carbon nitride with ultrahigh solar hydrogen production activity. Angew Chem. 2017; 129 (43): 13630- 13634.

[75]	Wang X, Blechert S, Antonietti M. Polymeric graphitic carbon nitride for heterogeneous photocatalysis. ACS Catal. 2012; 2 (8): 1596- 1606.

[76]	Chamorro-Posada P, Dante RC, Vázquez-Cabo J, et al. From urea to melamine cyanurate: study of a class of thermal condensation routes for the preparation of graphitic carbon nitride. J Solid State Chem. 2022; 310: 123071.

[77]	Das D, Banerjee D, Pahari D, et al. Defect induced tuning of photoluminescence property in graphitic carbon nitride nanosheets through synthesis conditions. J Lumin. 2017; 185: 155- 165.

[78]	Wu P, Wang J, Zhao J, Guo L, Osterloh FE. Structure defects in g-C3N4 limit visible light driven hydrogen evolution and photovoltage. J Mater Chem A. 2014; 2 (47): 20338- 20344.

[79]	Stagi L, Chiriu D, Carbonaro CM, Corpino R, Ricci PC. Structural and optical properties of carbon nitride polymorphs. Diamond Relat Mater. 2016; 68: 84- 92.

[80]	Dong G, Zhang Y, Pan Q, Qiu J. A fantastic graphitic carbon nitride (g-C3N4) material: electronic structure, photocatalytic and photoelectronic properties. J Photochem Photobiol C. 2014; 20: 33- 50.

[81]	Mubeen M, Deshmukh K, Peshwe DR, Dhoble SJ, Deshmukh AD. Alteration of the electronic structure and the optical properties of graphitic carbon nitride by metal ion doping. Spectrochim Acta Part A. 2019; 207: 301- 306.

[82]	Wu J, Yang S, Li J, et al. Electron injection of phosphorus doped g-C3N4 quantum dots: controllable photoluminescence emission wavelength in the whole visible light range with high quantum yield. Adv Opt Mater. 2016; 4 (12): 2095- 2101.

[83]	Rong M, Song X, Zhao T, Yao Q, Wang Y, Chen X. Synthesis of highly fluorescent P,O-g-C3N4 nanodots for the label-free detection of Cu2+ and acetylcholinesterase activity. J Mater Chem C. 2015; 3 (41): 10916- 10924.

[84]	Patir K, Gogoi SK. Facile synthesis of photoluminescent graphitic carbon nitride quantum dots for Hg2+ detection and room temperature phosphorescence. ACS Sustainable Chem Eng. 2018; 6 (2): 1732- 1743.

[85]	Lu YC, Chen J, Wang AJ, et al. Facile synthesis of oxygen and sulfur co-doped graphitic carbon nitride fluorescent quantum dots and their application for mercury(II) detection and bioimaging. J Mater Chem C. 2015; 3 (1): 73- 78.

[86]	Wang H, Lu Q, Li M, et al. Electrochemically prepared oxygen and sulfur co-doped graphitic carbon nitride quantum dots for fluorescence determination of copper and silver ions and biothiols. Anal Chim Acta. 2018; 1027: 121- 129.

[87]	Chen L, Song J. Tailored graphitic carbon nitride nanostructures: synthesis, modification, and sensing applications. Adv Funct Mater. 2017; 27 (39): 1702695.

[88]	Zhang X, Xie X, Wang H, Zhang J, Pan B, Xie Y. Enhanced photoresponsive ultrathin graphitic-phase C3N4 nanosheets for bioimaging. J Am Chem Soc. 2013; 135 (1): 18- 21.

[89]	Liang J, Yang X, Wang Y, et al. A review on g-C3N4 incorporated with organics for enhanced photocatalytic water splitting. J Mater Chem A. 2021; 9 (22): 12898- 12922.

[90]	Zhuo Z, Jiao Y, Chen L, et al. Ultra-high quantum yield ultraviolet fluorescence of graphitic carbon nitride nanosheets. Chem Commun. 2019; 55 (100): 15065- 15068.

[91]	Barman S, Sadhukhan M. Facile bulk production of highly blue fluorescent graphitic carbon nitride quantum dots and their application as highly selective and sensitive sensors for the detection of mercuric and iodide ions in aqueous media. J Mater Chem. 2012; 22 (41): 21832.

[92]	Yang L, Wu X, Luo L, Liu Y, Wang F. Facile preparation of graphitic-C3N4 quantum dots for application in two-photon imaging. New J Chem. 2019; 43 (7): 3174- 3179.

[93]	Zhou Z, Niu X, Ma L, Wang J. Revealing the pH-dependent photoluminescence mechanism of graphitic C3N4 quantum dots. Adv Theory Simulations. 2019; 2 (9): 1900074.

[94]	He X, Liu Y, Butch CJ, et al. One-pot exfoliation of graphitic C3N4 quantum dots for blue qleds by methylamine intercalation. Small. 2019; 15 (44): 1902735.

[95]	He L, Fei M, Chen J, et al. Graphitic C3N4 quantum dots for next-generation QLED displays. Mater Today. 2019; 22: 76- 84.

[96]	Liu W, Xu S, Guan S, et al. Confined synthesis of carbon nitride in a layered host matrix with unprecedented solid-state quantum yield and stability. Adv Mater. 2018; 30 (2): 1704376.

[97]	Wang Y, Hong J, Zhang W, Xu R. Carbon nitride nanosheets for photocatalytic hydrogen evolution: remarkably enhanced activity by dye sensitization. Catal Sci Technol. 2013; 3 (7): 1703.

[98]	Kaczmarek M, Lis S. Chemiluminescence characterisation of the reaction system Tb(III)-amino acid-peroxynitrous acid. J Alloys Compd. 2008; 451 (1-2): 186- 189.

[99]	Liu X, Freeman R, Golub E, Willner I. Chemiluminescence and chemiluminescence resonance energy transfer (CRET) aptamer sensors using catalytic hemin/G-quadruplexes. ACS Nano. 2011; 5 (9): 7648- 7655.

[100]

Yuan Y, Zhang L, Xing J, et al. High-yield synthesis and optical properties of g-C3N4. Nanoscale. 2015; 7 (29): 12343- 12350.

[101]

Zhen X, Zhang C, Xie C, Miao Q, Lim KL, Pu K. Intraparticle energy level alignment of semiconducting polymer nanoparticles to amplify chemiluminescence for ultrasensitive in vivo imaging of reactive oxygen species. ACS Nano. 2016; 10 (6): 6400- 6409.

[102]

Sudarsanakumar C, Thomas S, Mathew S, et al. Selective sensing of curcumin using L-cysteine derived blue luminescent graphene quantum dots. Mater Res Bull. 2019; 110: 32- 38.

[103]

Singh A, Mohapatra PK, Kalyanasundaram D, Kumar S. Self-functionalized ultrastable water suspension of luminescent carbon quantum dots. Mater Chem Phys. 2019; 225: 23- 27.

[104]

Ma X, Li S, Hessel V, Lin L, Meskers S, Gallucci F. Synthesis of luminescent carbon quantum dots by microplasma process. Chem Eng Process. 2019; 140: 29- 35.

[105]

Aziz SB, Abdullah OG, Brza MA, Azawy AK, Tahir DA. Effect of carbon nano-dots (CNDs) on structural and optical properties of PMMA polymer composite. Results Phys. 2019; 15: 102776.

[106]

Liu G, Wang S, Gondal MA, Shen K, Xu Q. Enhanced visible light photocatalytic performance of g-C3N4 photocatalysts co-doped with gold and sulfur for degradation of persistent pollutant (rhodamine B). J Nanosci Nanotechnol. 2019; 19 (2): 713- 720.

[107]

Dutta K, De S, Das B, et al. Development of an efficient immunosensing platform by exploring single-walled carbon nanohorns (SWCNHs) and nitrogen doped graphene quantum dot (N-GQD) nanocomposite for early detection of cancer biomarker. ACS Biomater Sci Eng. 2021; 7 (12): 5541- 5554.

[108]

Liu B, Tao J, Pan J, Li C, Li F, Zheng Y. Construction of green fluorescent carbon dots with high quantum yield for cancer cell recognition and Fe3+ detection. Opt Mater. 2021; 113: 110892.

[109]

Xie N, Tan L, Li HF, et al. Manipulation of 3D nanocarbon hybrids toward synthesis of N-doped graphene quantum dots with high photoluminescence quantum yield. J Lumin. 2020; 219: 116827.

[110]

Chu S, Wang C, Feng J, Wang Y, Zou Z. Melem: a metal-free unit for photocatalytic hydrogen evolution. Int J Hydrogen Energy. 2014; 39 (25): 13519- 13526.

[111]

Fan X, Feng Y, Su Y, Zhang L, Lv Y. A green solid-phase method for preparation of carbon nitride quantum dots and their applications in chemiluminescent dopamine sensing. RSC Adv. 2015; 5 (68): 55158- 55164.

[112]

Fan X, Su Y, Deng D, Lv Y. Carbon nitride quantum dot-based chemiluminescence resonance energy transfer for iodide ion sensing. RSC Adv. 2016; 6 (80): 76890- 76896.

[113]

Tang Y, Song H, Su Y, Lv Y. Turn-on persistent luminescence probe based on graphitic carbon nitride for imaging detection of biothiols in biological fluids. Anal Chem. 2013; 85 (24): 11876- 11884.

[114]

Wu P, Hou X, Xu JJ, Chen HY. Electrochemically generated versus photoexcited luminescence from semiconductor nanomaterials: bridging the valley between two worlds. Chem Rev. 2014; 114 (21): 11027- 11059.

[115]

Xiong J, Di J, Xia J, Zhu W, Li H. Surface defect engineering in 2D nanomaterials for photocatalysis. Adv Funct Mater. 2018; 28 (39): 1801983.

[116]

Hou Y, Fang Y, Zhou Z, et al. Growth of robust carbon nitride films by double crystallization with exceptionally boosted electrochemiluminescence for visual DNA detection. Adv Opt Mater. 2023; 11 (6): 2202737.

[117]

Cheng C, Huang Y, Wang J, Zheng B, Yuan H, Xiao D. Anodic electrogenerated chemiluminescence behavior of graphite-like carbon nitride and its sensing for rutin. Anal Chem. 2013; 85 (5): 2601- 2605.

[118]

Kitte SA, Bushira FA, Xu C, Wang Y, Li H, Jin Y. Plasmon-enhanced nitrogen vacancy-rich carbon nitride electrochemiluminescence aptasensor for highly sensitive detection of miRNA. Anal Chem. 2022; 94 (2): 1406- 1414.

[119]

Liu L, Liu Y, Zhang Y, Yuan R, Wang H. K-doped graphitic carbon nitride with obvious less electrode passivation for highly stable electrochemiluminescence and its sensitive sensing analysis of microRNA. Anal Chem. 2022; 94 (20): 7191- 7199.

[120]

Zhou Y, Lv W, Zhu B, et al. Template-free one-step synthesis of g-C3N4 nanosheets with simultaneous porous network and s-doping for remarkable visible-light-driven hydrogen evolution. ACS Sustainable Chem Eng. 2019; 7 (6): 5801- 5807.

[121]

Jiao Y, Hu R, Wang Q, et al. Tune the fluorescence and electrochemiluminescence of graphitic carbon nitride nanosheets by controlling the defect states. Chem Eur J. 2021; 27 (42): 10925- 10931.

[122]

Dong G, Zhao K, Zhang L. Carbon self-doping induced high electronic conductivity and photoreactivity of g-C3N4. Chem Commun. 2012; 48 (49): 6178.

[123]

Zuo F, Wang L, Wu T, Zhang Z, Borchardt D, Feng P. Self-doped Ti3+ enhanced photocatalyst for hydrogen production under visible light. J Am Chem Soc. 2010; 132 (34): 11856- 11857.

[124]

Zhang S, Gu P, Ma R, et al. Recent developments in fabrication and structure regulation of visible-light-driven g-C3N4-based photocatalysts towards water purification: a critical review. Catal Today. 2019; 335: 65- 77.

[125]

Fang Y, Hou Y, Yang H, et al. Elucidating orbital delocalization effects on boosting electrochemiluminescence efficiency of carbon nitrides. Adv Opt Mater. 2022; 10 (18): 2201017.

[126]

Cao W, Liu L, Yuan R, Wang H. High efficiency electrochemiluminescence of 3D porous g-C3N4 with dissolved O2 as co-reactant and its sensing application for ultrasensitive detection of microRNA in tumor cells. Biosens Bioelectron. 2022; 214: 114506.

[127]

Zhao B, Luo Y, Qu X, et al. Graphite-like carbon nitride nanotube for electrochemiluminescence featuring high efficiency, high stability, and ultrasensitive ion detection capability. J Phys Chem Lett. 2021; 12 (45): 11191- 11198.

[128]

Chen L, Huang D, Ren S, Dong T, Chi Y, Chen G. Preparation of graphite-like carbon nitride nanoflake film with strong fluorescent and electrochemiluminescent activity. Nanoscale. 2013; 5 (1): 225- 230.

[129]

Zhou X, Zhang W, Wang Z, Han J, Xie G, Chen S. Ultrasensitive aptasensing of insulin based on hollow porous C3N4/S2O82−/AuPtAg ECL ternary system and DNA walker amplification. Biosens Bioelectron. 2020; 148: 111795.

[130]

Jiang D, Qin M, Zhang L, Shan X, Chen Z. Ultrasensitive all-solid-state electrochemiluminescence platform for kanamycin detection based on the pore confinement effect of 0D g-C3N4 quantum dots/3D graphene hydrogel. Sens Actuator B Chem. 2021; 345: 130343.

[131]

Lv S, Tang Y, Zhang K, Tang D. Wet NH3-triggered NH2-MIL-125(Ti) structural switch for visible fluorescence immunoassay impregnated on paper. Anal Chem. 2018; 90 (24): 14121- 14125.

[132]

Qiu Z, Shu J, Tang D. Bioresponsive release system for visual fluorescence detection of carcinoembryonic antigen from mesoporous silica nanocontainers mediated optical color on quantum dot-enzyme-impregnated paper. Anal Chem. 2017; 89 (9): 5152- 5160.

[133]

Dong YP, Gao TT, Zhou Y, Zhu JJ. Electrogenerated chemiluminescence resonance energy transfer between luminol and CdSe@ZnS quantum dots and its sensing application in the determination of thrombin. Anal Chem. 2014; 86 (22): 11373- 11379.

[134]

Gu J, Isaji T, Xu Q, et al. Potential roles of N-glycosylation in cell adhesion. Glycoconj J. 2012; 29 (8-9): 599- 607.

[135]

Zhao YY, Takahashi M, Gu JG, et al. Functional roles of N-glycans in cell signaling and cell adhesion in cancer. Cancer Sci. 2008; 99 (7): 1304- 1310.

[136]

Marth JD, Grewal PK. Mammalian glycosylation in immunity. Nat Rev Immunol. 2008; 8 (11): 874- 887.

[137]

Gao Y, Chachadi VB, Cheng PW, Brockhausen I. Glycosylation potential of human prostate cancer cell lines. Glycoconj J. 2012; 29 (7): 525- 537.

[138]

Jin Y, Kang Q, Guo X, Zhang B, Shen D, Zou G. Electrochemical-signal-amplification strategy for an electrochemiluminescence immunoassay with g-C3N4 as tags. Anal Chem. 2018; 90 (21): 12930- 12936.

[139]

Peng X, Ma J, Zhou Z, et al. Molecular assembly of carbon nitride-based composite membranes for photocatalytic sterilization and wound healing. Chem Sci. 2023; 14 (16): 4319- 4327.

[140]

Huang C, Wen J, Shen Y, et al. Dissolution and homogeneous photocatalysis of polymeric carbon nitride. Chem Sci. 2018; 9 (41): 7912- 7915.

[141]

Zhou Z, Wang J, Yu J, et al. Dissolution and liquid crystals phase of 2D polymeric carbon nitride. J Am Chem Soc. 2015; 137 (6): 2179- 2182.

[142]

Miller TS, Suter TM, Telford AM, et al. Single crystal, luminescent carbon nitride nanosheets formed by spontaneous dissolution. Nano Lett. 2017; 17 (10): 5891- 5896.

[143]

Gao S, Wang X, Song C, Zhou S, Yang F, Kong Y. Engineering carbon-defects on ultrathin g-C3N4 allows one-pot output and dramatically boosts photoredox catalytic activity. Appl Catal B. 2021; 295: 120272.