Highly Photoluminescent RGB-Carbon Dots and Their Integration Applications in Light-Emitting Diodes and Luminescent Solar Concentrators

Bin Liu; Genghong Huang; Yaling Wang; Huijie Bai; Suping Jia; Fu-de Ren; Xinghong Zhang

doi:10.1002/agt2.70167

Aggregate ›› 2025, Vol. 6 ›› Issue (12) :e70167 DOI: 10.1002/agt2.70167

RESEARCH ARTICLE

Highly Photoluminescent RGB-Carbon Dots and Their Integration Applications in Light-Emitting Diodes and Luminescent Solar Concentrators

Author information +

History +

PDF

Abstract

Carbon dots (CDs) have emerged as a promising platform for constructing optoelectronic devices. However, the synthesis of multicolor CDs with high quantum yield (QY) and the elucidation of their luminescence mechanisms remain challenges. Here, we successfully synthesize RGB-CDs by precisely controlling the ratio of o-phenylenediamine and phytic acid. The QYs of the RGB-CDs are up to 60.3%, 68.7%, and 19.0%, respectively. Experimental data and DFT calculations reveal that the fluorescence emission of the RGB-CDs originates from molecule state (5,14-dihydroquinoxalino[2,3-b] phenazine), carbon core state, and clusteroluminescence state induced by the through-space interactions of heteroatom groups, respectively. Moreover, leveraging the outstanding fluorescence properties of the RGB-CDs, we fabricate both a white light-emitting diode (WLED) with an ultra-high color rendering index of 98 and a luminescent solar concentrator achieving a high power conversion efficiency of 1.6%. Finally, we integrate a self-powered lighting system combining the WLED and LSC, which provides approximately 6 h of continuous illumination to a 0.1 W WLED after a single day's charging. Our results demonstrate a facile method for preparing multicolor CDs with high QYs, enabling their use as phosphor sources for various optoelectronic device applications.

Keywords

carbon dots / light-emitting diodes / luminescent solar concentrators / self-powered lighting system

Cite this article

Download citation ▾

Bin Liu, Genghong Huang, Yaling Wang, Huijie Bai, Suping Jia, Fu-de Ren, Xinghong Zhang. Highly Photoluminescent RGB-Carbon Dots and Their Integration Applications in Light-Emitting Diodes and Luminescent Solar Concentrators. Aggregate, 2025, 6(12): e70167 DOI:10.1002/agt2.70167

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	X. Xu, R. Ray, Y. Gu, et al., “Electrophoretic Analysis and Purification of Fluorescent Single-Walled Carbon Nanotube Fragments,” Journal of the American Chemical Society 126 (2004): 12736–12737.

[2]	L. Ai, Y. Yang, B. Wang, et al., “Insights Into Photoluminescence Mechanisms of Carbon Dots: Advances and Perspectives,” Science Bulletin 66 (2021): 839–856.

[3]	C. Ji, W. Xu, Q. Han, T. Zhao, J. Deng, and Z. Peng, “Light of Carbon: Recent Advancements of Carbon Dots for LEDs,” Nano Energy 114 (2023): 108623.

[4]	K. Jiang, S. Sun, L. Zhang, et al., “Red, Green, and Blue Luminescence by Carbon Dots: Full-Color Emission Tuning and Multicolor Cellular Imaging,” Angewandte Chemie International Edition 54 (2015): 5360–5363.

[5]	L. Wang, W. Li, L. Yin, et al., “Full-Color Fluorescent Carbon Quantum Dots,” Science Advances 6 (2020): eabb6772.

[6]	H. Ding, J. Wei, P. Zhang, Z. Zhou, Q. Gao, and H. Xiong, “Solvent-Controlled Synthesis of Highly Luminescent Carbon Dots With a Wide Color Gamut and Narrowed Emission Peak Widths,” Small 14 (2018): 1800612.

[7]	F. Yuan, T. Yuan, L. Sui, et al., “Engineering Triangular Carbon Quantum Dots With Unprecedented Narrow Bandwidth Emission for Multicolored LEDs,” Nature Communications 9 (2018): 2249.

[8]	Z. Yan, T. Chen, L. Yan, et al., “One-Step Synthesis of White-Light-Emitting Carbon Dots for White LEDs With a High Color Rendering Index of 97,” Advanced Science 10 (2023): 2206386.

[9]	H. Ding, S.-B. Yu, J.-S. Wei, and H.-M. Xiong, “Full-Color Light-Emitting Carbon Dots With a Surface-State-Controlled Luminescence Mechanism,” ACS Nano 10 (2016): 484–491.

[10]	X. Yang, X. Li, B. Wang, et al., “Advances, Opportunities, and Challenge for Full-Color Emissive Carbon Dots,” Chinese Chemical Letters 33 (2022): 613–625.

[11]	Y. Wang, Y. Qin, W. Tian, et al., “Dye-Incorporated Carbonized Polymer Dots With Tunable Solid-State Emission Based on Intraparticle Förster Resonance Energy Transfer,” Advanced Functional Materials 34 (2024): 2402825.

[12]	J. Lin, L. Wang, Q. Jing, and H. Zhao, “Highly Efficient and High Color Rendering Index Multilayer Luminescent Solar Concentrators Based on Colloidal Carbon Quantum Dots,” Chemical Engineering Journal 481 (2024): 148441.

[13]	L. Ai, Z. Song, M. Nie, et al., “Solid-State Fluorescence From Carbon Dots Widely Tunable From Blue to Deep Red Through Surface Ligand Modulation,” Angewandte Chemie International Edition 62 (2023): e202217822.

[14]	Y. Li, Q. Li, S. Meng, et al., “Ultrabroad-Band, White Light Emission From Carbon Dot-Based Materials With Hybrid Fluorescence/Phosphorescence for Single Component White Light-Emitting Diodes,” Chinese Chemical Letters 34 (2023): 107794.

[15]	J. Chen, H. Zhao, Z. Li, X. Zhao, and X. Gong, “Highly Efficient Tandem Luminescent Solar Concentrators Based on Eco-Friendly Copper Iodide Based Hybrid Nanoparticles and Carbon Dots,” Energy & Environmental Science 15 (2022): 799–805.

[16]	H. Zhao, G. Liu, S. You, et al., “Gram-Scale Synthesis of Carbon Quantum Dots With a Large Stokes Shift for the Fabrication of Eco-Friendly and High-Efficiency Luminescent Solar Concentrators,” Energy & Environmental Science 14 (2021): 396–406.

[17]	H. Guo, P. Xia, S. Huang, et al., “Self-Powered Luminescent Solar Concentrators-Integrated Temperature Detection System With High Thermal Tolerance by Reversible Thermal Photoluminescence Luminophores,” Advanced Functional Materials 34 (2024): 2409232.

[18]	J. Li, J. Chen, X. Zhao, A. Vomiero, and X. Gong, “High-Loading of Organosilane-Grafted Carbon Dots in High-Performance Luminescent Solar Concentrators With Ultrahigh Transparency,” Nano Energy 115 (2023): 108674.

[19]	P. Li, S. Xue, L. Sun, et al., “Formation and Fluorescent Mechanism of Red Emissive Carbon Dots From o-Phenylenediamine and Catechol System,” Light: Science & Applications 11 (2022): 298.

[20]	Y. Yao, L. Ren, S. Gao, and S. Li, “Histogram Method for Reliable Thickness Measurements of Graphene Films Using Atomic Force Microscopy (AFM),” Journal of Materials Science and Technology 33 (2017): 815–820.

[21]	R. Jain and S. Mishra, “Electrical and Electrochemical Properties of Graphene Modulated Through Surface Functionalization,” RSC Advances 6 (2016): 27404–27415.

[22]	F. Yuan, Z. Wang, X. Li, et al., “Bright Multicolor Bandgap Fluorescent Carbon Quantum Dots for Electroluminescent Light-Emitting Diodes,” Advanced Materials 29 (2017): 1604436.

[23]	M. S. Dresselhaus, A. Jorio, M. Hofmann, G. Dresselhaus, and R. Saito, “Perspectives on Carbon Nanotubes and Graphene Raman Spectroscopy,” Nano Letters 10 (2010): 751–758.

[24]	P. H. Tan, W. P. Han, W. J. Zhao, et al., “The Shear Mode of Multilayer Graphene,” Nature Materials 11 (2012): 294–300.

[25]	X. Gong, Q. Hu, M. C. Paau, et al., “Red-Green-Blue Fluorescent Hollow Carbon Nanoparticles Isolated From Chromatographic Fractions for Cellular Imaging,” Nanoscale 6 (2014): 8162.

[26]	B. Wang, Z. Wei, L. Sui, et al., “Electron–Phonon Coupling-Assisted Universal Red Luminescence of o-Phenylenediamine-Based Carbon Dots,” Light Science Applications 11 (2022): 172.

[27]	A. Cravcenco, Y. Yu, F. Edhborg, et al., “Exciton Delocalization Counteracts the Energy Gap: A New Pathway Toward NIR-Emissive Dyes,” Journal of the American Chemical Society 143 (2021): 19232–19239.

[28]	Y. Wu, J. Li, X. Zhao, and X. Gong, “Nickel-Doped Carbon Dots With Enhanced and Tunable Multicolor Fluorescence Emission for Multicolor Light-Emitting Diodes,” Carbon 201 (2023): 796–804.

[29]	M. Zhou, T. Higaki, Y. Li, et al., “Three-Stage Evolution From Nonscalable to Scalable Optical Properties of Thiolate-Protected Gold Nanoclusters,” Journal of the American Chemical Society 141 (2019): 19754–19764.

[30]	X. Yao, R. E. Lewis, and C. L. Haynes, “Synthesis Processes, Photoluminescence Mechanism, and the Toxicity of Amorphous or Polymeric Carbon Dots,” Accounts of Chemical Research 55 (2022): 3312–3321.

[31]	B. Liu, B. Chu, L. Zhu, et al., “Clusteroluminescence: A Gauge of Molecular Interaction,” Chinese Chemical Letters 34 (2023): 107909.

[32]	H. Lu, G. Huang, Y.-L. Wang, et al., “White-Light Clusteroluminescence of Poly(β-Hydroxyvinyl N-Substituted Carbamate)s via Through-Space Interactions,” European Polymer Journal 210 (2024): 112991.

[33]	Y. Wang, J. Zhang, Q. Xu, et al., “Narrowband Clusteroluminescence With 100% Quantum Yield Enabled by Through-Space Conjugation of Asymmetric Conformation,” Nature Communications 15 (2024): 6426.

[34]	B. Liu, G. Huang, H. Lu, et al., “Polymerization-Induced Clusteroluminescence of Poly(Cyclic Carbonate)s,” Journal of Materials Chemistry C 11 (2023): 13142–13150.

[35]	Y.-L. Wang, K. Chen, H.-R. Li, et al., “Hydrogen Bonding-Induced Oxygen Clusters and Long-Lived Room Temperature Phosphorescence From Amorphous Polyols,” Chinese Chemical Letters 34 (2023): 107684.

[36]	T. Zhang, J. Zhou, H. Li, et al., “Stable Lignin-Based Afterglow Materials With Ultralong Phosphorescence Lifetimes in Solid-State and Aqueous Solution,” Green Chemistry 25 (2023): 1406–1416.

[37]	L. Li, L. Shi, J. Jia, et al., “Dual Photoluminescence Emission Carbon Dots for Ratiometric Fluorescent GSH Sensing and Cancer Cell Recognition,” ACS Applied Materials & Interfaces 12 (2020): 18250–18257.

[38]	S. Hayashi, “Elastic Organic Crystals of π-Conjugated Molecules: New Concept for Materials Chemistry,” Symmetry 12 (2020): 2022.

[39]	A. Haque, K. M. Alenezi, M. S. Khan, W.-Y. Wong, and P. R. Raithby, “Non-Covalent Interactions (NCIs) in π-Conjugated Functional Materials: Advances and Perspectives,” Chemical Society Reviews 52 (2023): 454–472.

[40]	P. Li, S. Xue, L. Sun, et al., “Formation and Fluorescent Mechanism of Multiple Color Emissive Carbon Dots From o-Phenylenediamine,” Small 20 (2024): 2310563.

[41]

A. Das, D. Roy, M. Mandal, C. Jaiswal, M. Ta, and P. K. Mandal, “Carbon Dot With pH Independent Near-Unity Photoluminescence Quantum Yield in an Aqueous Medium: Electrostatics-Induced Förster Resonance Energy Transfer at Submicromolar Concentration,” Journal of Physical Chemistry Letters 9 (2018): 5092–5099.

[42]	T. Lu and Q. Chen, “Interaction Region Indicator: A Simple Real Space Function Clearly Revealing Both Chemical Bonds and Weak Interactions*,” Chemistry-Methods* 1 (2021): 231–239.

[43]	J. Stejskal, “Polymers of Phenylenediamines,” Progress in Polymer Science 41 (2015): 1–31.

[44]	L. Cao, M. Zan, F. Chen, et al., “Formation Mechanism of Carbon Dots: From Chemical Structures to Fluorescent Behaviors,” Carbon 194 (2022): 42–51.

[45]	Q. Zhang, R. Wang, B. Feng, X. Zhong, and K. Ostrikov, “Photoluminescence Mechanism of Carbon Dots: Triggering High-Color-Purity Red Fluorescence Emission Through Edge Amino Protonation,” Nature Communications 12 (2021): 6856.

[46]	Y. Zhang, S. Ding, J. Yu, et al., “Unveiling the Photoluminescence Mechanisms of Carbon Dots Through Tunable Near-Infrared Dual-Wavelength Lasing,” Matter 7 (2024): 3518–3536.

[47]	B. Liu, B. Chu, Y.-L. Wang, L.-F. Hu, S. Hu, and X.-H. Zhang, “Carbon Dioxide Derived Carbonized Polymer Dots for Multicolor Light-Emitting Diodes,” Green Chemistry 23 (2021): 422–429.

[48]	H. Guo, Z. Liu, X. Shen, and L. Wang, “One-Pot Synthesis of Orange Emissive Carbon Quantum Dots for All-Type High Color Rendering Index White Light-Emitting Diodes,” ACS Sustainable Chemistry & Engineering 10 (2022): 8289–8296.

[49]	K. Wu, H. Li, and V. I. Klimov, “Tandem Luminescent Solar Concentrators Based on Engineered Quantum Dots,” Nature Photonics 12 (2018): 105–110.

[50]	F. Meinardi, F. Bruni, and S. Brovelli, “Luminescent Solar Concentrators for Building-Integrated Photovoltaics,” Nature Reviews Materials 2 (2017): 17072.

[51]	M. R. Bergren, N. S. Makarov, K. Ramasamy, A. Jackson, R. Guglielmetti, and H. McDaniel, “High-Performance CuInS 2 Quantum Dot Laminated Glass Luminescent Solar Concentrators for Windows,” ACS Energy Letters 3 (2018): 520–525.

[52]	C. Yang, H. A. Atwater, M. A. Baldo, et al., “Consensus Statement: Standardized Reporting of Power-Producing Luminescent Solar Concentrator Performance,” Joule 6 (2022): 8–15.

[53]	M. J. Frisch, G. W. Trucks, and H. B. Schlegel, et al., Gaussian 09, Revision D.01 (Gaussian Inc., 2013).

[54]	A. D. Becke, “Density-Functional Thermochemistry. III. The Role of Exact Exchange,” Journal of Chemical Physics 98 (1993): 5648–5652.

[55]	P. C. Hariharan and J. A. Pople, “Accuracy of AH n Equilibrium Geometries by Single Determinant Molecular Orbital Theory,” Molecular Physics 27 (1974): 209–214.

[56]	S. Grimme, J. Antony, S. Ehrlich, and H. Krieg, “A Consistent and Accurate Ab Initio Parametrization of Density Functional Dispersion Correction (DFT-D) for the 94 Elements H-Pu,” Journal of Chemical Physics 132 (2010): 154104.

[57]	S. Grimme, S. Ehrlich, and L. Goerigk, “Effect of the Damping Function in Dispersion Corrected Density Functional Theory,” Journal of Computational Chemistry 32 (2011): 1456–1465.

[58]	J.-D. Chai and M. Head-Gordon, “Long-Range Corrected Hybrid Density Functionals With Damped Atom–Atom Dispersion Corrections,” Physical Chemistry Chemical Physics 10 (2008): 6615.

[59]	T. Lu and F. Chen, “Multiwfn: A Multifunctional Wavefunction Analyzer,” Journal of Computational Chemistry 33 (2012): 580–592.

[60]	W. Humphrey, A. Dalke, and K. Schulten, “VMD: Visual Molecular Dynamics,” Journal of Molecular Graphics 14 (1996): 33–38.

[61]	V. I. Klimov, T. A. Baker, J. Lim, K. A. Velizhanin, and H. McDaniel, “Quality Factor of Luminescent Solar Concentrators and Practical Concentration Limits Attainable With Semiconductor Quantum Dots,” ACS Photonics 3 (2016): 1138–1148.