Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (08): 28-36.doi: 10.13475/j.fzxb.20241101401

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Optimization of preparation technology for polyethylene terephthalate-based carbom dots and its application in polyamide 66

MA Chaohui1, CUI Tongran1, BING Linhan1, ZHU Zhiguo1, WANG Rui1,2,3, WEI Jianfei1,2,3()   

  1. 1. School of Material Design and Engineering, Beijing Institute of Fashion Technology, Beijing 100029, China
    2. Beijing Key Laboratory of Clothing Materials R&D and Assessment, Beijing Institute of Fashion Technology, Beijing 100029, China
    3. Beijing Engineering Research Center of Textile Nanofibers, Beijing 100029, China
  • Received:2024-11-07 Revised:2025-04-16 Online:2025-08-15 Published:2025-08-15
  • Contact: WEI Jianfei E-mail:weijianfei@bift.edu.cn

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Abstract:

Objective Carbon dots (CDs) are a sort of zero-dimensional fluorescent nanomaterials that can be widely utilized across various fields due to their excellent biocompatibility and biosecurity. Research has demonstrated that carbon dots possess significant potential as flame retardants, but the current methods for preparing carbon dots are still limited to laboratory-scale production and have not yet achieved large-scale manufacturing. This limitation poses challenges for their application in flame retardant formulations that require substantial quantities. The objective of this study is to explore a method that not only enables the efficient recycling of waste but also facilitates the flame retardant modification of polyamide 66(PA66).

Method In this study, polyethylene terephthalate (PET) carbon dots (PET-CDs) were synthesized using a hydrothermal method with PET oligomers, urea, and phosphomolybdic acid (PMA) as precursors. The optimal synthesis conditions were determined through orthogonal experiments, which allowed for the optimization of reaction temperature, reaction time, and loading volume. A series of characterization tests were conducted on the prepared carbon dots, including optical and morphological assessments. Additionally, CDs-PA66 was created by blending PET-CDs with PA66, and the thermal stability, flame retardancy, and combustion properties of CDs-PA66 were evaluated. The influence of PET-CDs on fluorescence anti-counterfeiting and fingerprint recognition was also investigated.

Results Using PET oligomer, urea, and PMA as precursors, the optimal process conditions were determined to be 3 g of PET oligomer, 5 g of PMA, 4 g of urea, and 15 mL of H2O. The reaction was conducted in a drying oven at 260 ℃ for 18 h. It is observed that the loading volume had minimal impact on the fluorescence intensity of PET carbon dots (PET-CDs), which was prepared in a 5 L kettle in equal proportions. PET-CDs were characterized using a fluorescence spectrometer, among other techniques, and the results indicate that PET-CDs exhibited no dependence on the excitation wavelength. The optimal excitation wavelength was found to be 410 nm, while the optimal emission wavelength was 485 nm, resulting in a fluorescence quantum yield of 70.78%. PET-CDs possess a spherical structure with an average particle size of 1.37 nm and a lattice spacing of 0.25 nm. The surface of the particles was rich in functional groups, including hydroxyl groups. When PET-CDs were utilized for the flame retardant modification of PA66, with an addition of 4% PET-CDs, the limiting oxygen index indicating a refractory level reached 28%. Additionally, the combustion time following the initial flame ignition decreased significantly from 188.7 s to 5.2 s. The fluorescence of PET-CDs can be specifically quenched by Fe3+, allowing for the quantitative detection of Fe3+ through the linear relationship between the degree of quenching of PET-CDs and the concentration of Fe3+ within the range of 0.00 to 10 μmol/L. Furthermore, fluorescent inks containing PET-CDs produced patterns that was invisible under natural light but become visible under ultraviolet light, demonstrating their anti-counterfeiting capabilities. Starch containing 1.5% PET-CDs can also be employed for fingerprint identification.

Conclusion PET oligomer, urea, and PMA serve as precursors with excellent fluorescence properties and a high fluorescence quantum yield. These materials can be utilized in PA66 flame retardants, fluorescent anti-counterfeiting applications, and fingerprint recognition technologies.

Key words: carbon dot, polyamide 66, flame retardant, modification, Fe3+ detection, anti-counterfeiting, fingerprint detection

CLC Number: 

  • TQ322.3

Fig.1

Optimization results of PET-CDs preparation conditions.(a)Raw material ratio;(b)Reaction temperature;(c)Reaction time;(d)Loading volume"

Tab.1

Optimization of factors and levels of PET-CDs by Orthogonal method"

水平 A
PET低聚物
质量/g		 B
PMA质
量/g		 C
尿素质
量/g		 D
去离子水
体积/mL
1 1 3 3 15
2 2 4 4 10
3 3 5 5 5

Tab.2

Orthogonal experimental results"

编号 A B C D 荧光强
度/(105a.u.)
1 1 1 1 1 2.05
2 1 2 2 2 3.07
3 1 3 3 3 1.18
4 2 1 2 3 1.69
5 2 2 3 1 4.86
6 2 3 1 2 4.25
7 3 1 3 2 2.80
8 3 2 1 3 3.35
9 3 3 2 1 6.82
K1 2.10×105 2.18×105 3.22×105 4.58×105
K2 3.60×105 3.76×105 3.86×105 3.38×105
K3 4.32×105 4.09×105 2.95×105 2.08×105
R 2.22×105 1.90×105 9.13×104 2.50×105

Fig.2

Results of topographic optical characteristics of PET-CDs.(a)UV-vis absorption spectrum; (b)Photoluminescence spectrum;(c)Excitation and emission wavelength; (d)Absolute fluorescence quantum yield"

Tab.3

Effect of metal ions and pH on fluorescence intensity"

金属离子 I/I0 pH值 荧光强度/(105 a.u.)
Fe3+ 0.30 1 1.63
Li+ 0.99 2 1.54
Cu2+ 0.89 3 2.45
Cr3+ 0.95 4 2.99
Ca2+ 1.02 5 3.27
Ba2+ 0.99 6 3.34
Mg2+ 0.99 7 3.33
Na+ 1.00 8 3.39
Ag+ 0.97 9 3.35
K+ 1.00 10 3.36
Zn2+ 0.99 11 3.41
Cd2+ 0.99 12 2.63

Fig.3

TEM image of PET-CDs(a) and histogram of particle size distribution(b) of PET-CDs"

Fig.4

Structural characterization results of PET-CDs. (a) FT-IR spectra; (b) C1s spectrum; (c) N1s spectrum; (d) O1s spectrum"

Tab.4

DSC analysis data for PET-CDs and PET-CDs-PA66"

试样 T5%/℃ Tmax/℃
PET-CDs 194.76 330.39
PA66 403.70 458.21
1%-PET-CDs-PA66 395.57 461.71
2%-PET-CDs-PA66 398.88 461.84
3%-PET-CDs-PA66 397.63 462.21
4%-PET-CDs-PA66 402.03 465.42

Fig.5

DSC curves of PA66 and PET-CDs-PA66. (a) Warming curves; (b) Cooling curves"

Fig.6

CONE of PA66 and PET-CDs-PA66"

Tab.5

LOI and vertical combustion test results"

PET-CDs名称 LOI
值/
%		 UL-94
防火
等级		 t1/
s		 t2/
s		 是否
熔滴		 熔滴是
否引燃
脱脂棉
PA66 25 NR 188.7 0
1%-PET-CDs-PA66 25 V-2 42.6 11.8
2%-PET-CDs-PA66 27 V-2 9.4 7.0
3%-PET-CDs-PA66 28 V-2 6.5 5.5
4%-PET-CDs-PA66 28 V-2 5.2 3.6

Tab.6

Mechanical tensile data of PA66 and PET-CDs-PA66"

样品 拉伸强度/
MPa		 弹性模量/
MPa		 断裂伸长
率/%
PA66 57.84 483.98 348.45
1%-PET-CDs-PA66 59.88 467.14 373.55
2%-PET-CDs-PA66 52.56 450.38 240.69
3%-PET-CDs-PA66 52.96 505.65 282.40
4%-PET-CDs-PA66 52.20 442.70 286.11

Fig.7

Fluorescence spectra(a) and line plots(b) of different Fe3+ concentrations"

Fig.8

Print under ultraviolet light (365 nm)"

Fig.9

Fingerpint recognition result.(a)Fluorescence intensity of CDs-starch with different proportions of PET-CDs;(b)Starch-CDs fluorescent powder under natural light; (c)Starch-CDs and fingerprints exposed to UV light at 365 nm after powder spreading"

[1] 王婧茹, 严娟, 许铭育, 等. 利用废弃聚对苯二甲酸乙二醇酯制备共聚酯PBCAT[J]. 高分子材料科学与工程, 2024, 40(9): 9-18.
WANG Jingru, YAN Juan, XU Mingyu, et al. Preparation of copolyester PBCAT using waste polyethylene terephthalate[J]. Polymer Materials Science and Engineering, 2024, 40(9): 9-18.
[2] 陈汇凯, 黄锦圳, 鲁国强, 等. 碳点缓蚀剂的研究进展[J]. 材料研究与应用, 2024, 18(4): 538-549.
CHEN Huikai, HUANG Jinzhen, LU Guoqiang, et al. Research progress on carbon dot corrosion inhibi-tors[J]. Materials Research and Application, 2024, 18(4): 538-549.
[3] XU Yuanlin, WANG Boyang, ZHANG Mingming, et al. Carbon dots as a potential therapeutic agent for the treatment of cancer-related anemia[J]. Advanced Materials, 2022, 34(19): e2200905-e2200905.
[4] WU Zhaofan, WANG Baojuan, NI Jiawen, et al. Green fluorescent Carbon dots with critically controlled surface states: make silk shine via feeding silkworms[J]. Nano Letters, 2024, 24(31): 9675-9682.
[5] 刘俊, 张熙荣, 熊焕明. 荧光碳点在指纹检测中的应用[J]. 发光学报, 2021, 42(8):1095-1113.
LIU Jun, ZHANG Xirong, XIONG Huanming. Application of fluorescent carbon dots in fingerprint detection[J]. Journal of Luminescence, 2021, 42(8): 1095-1113.
[6] WANG Linjie, JI Yang, CHEN Yixin, et al. Recent research progress of fluorescence biosensors based on carbon dots in early diagnosis of diseases[J]. Trends in Analytical Chemistry, 2024, 180: 117962.
[7] NGUYEN Vannghia, PHAM Hoanglong, NGUYEN Xuantruong. Recent progress in organic carbon dot-based photosensitizers for photodynamic cancer therapy[J]. Dyes and Pigments, 2024, 230: 112359-112359.
[8] 邴琳涵, 王锐, 吴雨航, 等. 聚对苯二甲酸乙二醇酯基碳点热解法制备及其在阻燃改性中的应用[J]. 纺织学报, 2024, 45(10):1-8.
doi: 10.13475/j.fzxb.20230708301
BING Linhan, WANG Rui, WU Yuhang, et al. Preparation of PET-based carbon dots by pyrolysis and its application in PET flame retardancy[J]. Journal of Textile Research, 2024, 45(10):1-8.
doi: 10.13475/j.fzxb.20230708301
[9] 王锐, 刘彦麟, 刘蕴钰, 等. 以聚对苯二甲酸乙二醇酯为前驱体的碳点制备及其应用[J]. 纺织学报, 2022, 43(2): 10-18.
WANG Rui, LIU Yanlin, LIU Yunyu, et al. Preparation and application of carbon point using polyethylene terephthalate as precursor[J]. Journal of Textile Research, 2022, 43(2): 10-18.
[10] LIU Jiahui, LI Deyu, HE Jiahui, et al. Polarity-sensitive polymer carbon dots prepared at room-temperature for monitoring the cell polarity dynamics during autophagy[J]. ACS Applied Materials & Interfaces, 2020, 12(4): 4815-4820.
[11] JIANG Yongjian, LIN Min, YANG Tong, et al. Nitrogen and phosphorus doped polymer carbon dots as a sensitive cellular mapping probe of nitrite[J]. Journal of Materials Chemistry B, 2019, 7(12): 2074-2080.
doi: 10.1039/c8tb02998a pmid: 32254811
[12] GUO Zhenli, BIAN Yanfang, ZHANG Longyan, et al. Multi-stimuli-responsive carbon dots with intrinsic photochromism and in situ radical afterglow[J]. Advanced Materials, 2024, 36(45): e2409361.
[13] QU Dan, ZHENG Min, ZHANG Ligong, et al. Formation mechanism and optimization of highly luminescent N-doped graphene quantum dots[J]. Scientific Reports, 2014, 4(1): 5294.
[14] DING Hui, WEI Jishi, XIONG Huanming. Nitrogen and sulfur co-doped carbon dots with strong blue luminescence[J]. Nanoscale, 2014, 6(22): 13817-13823.
doi: 10.1039/c4nr04267k pmid: 25297983
[15] HOU Juan, WANG Wei, ZHOU Tianyu, et al. Synthesis and formation mechanistic investigation of nitrogen-doped carbon dots with high quantum yields and yellowish-green fluorescence[J]. Nanoscale, 2016, 8(21): 11185-11193.
doi: 10.1039/c6nr02701f pmid: 27180833
[16] WANG Min, HOU Aiying, YANG Dou, et al. Application of carbon dots synthesized with amino acid as precursor in the detection of phloroglucinol[J]. Microchemical Journal, 2024, 204: 111099.
[17] XU Quan, LIU Yao, GAO Chun, et al. Synthesis, mechanistic investigation, and application of photoluminescent sulfur and nitrogen co-doped carbon dots[J]. Journal of Materials Chemistry C, 2015, 3(38): 9885-9893.
[18] 刘举, 廖明磊, 邓德元, 等. 微硅粉改性耐热低烟无卤阻燃电缆复合材料的制备及性能研究[J]. 聚酯工业, 2024, 37(5):1-4.
LIU Ju, LIAO Minglei, DENG Deyuan, et al. Preparation and performance study of micro silicon powder modified heat resistant low smoke zero halogen flame retardant cable composite materials[J]. Polyester Industry, 2024, 37 (5): 1-4.
[19] 薛宝霞, 张铭铄, 杨色, 等. 一种碳点阻燃聚对苯二甲酸乙二醇酯的性能[J]. 高分子材料科学与工程, 2022, 38(7):53-59.
XUE Baoxia, ZHANG Mingshuo, YANG Se, et al. Properties of a carbon dot flame retardant polyethylene terephthalate[J]. Polymer Materials Science and Engineering, 2022, 38 (7): 53-59.
[20] CAI Huijuan, ZHU Yalin, XU Huilin, et al. Fabrication of fluorescent hybrid nanomaterials based on carbon dots and its applications for improving the selective detection of Fe (Ⅲ) in different matrices and cellular imaging[J]. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2021, 246: 119033.
[21] 冯瑞琪. 荧光碳点的制备及在Fe3+检测, 指纹检测和光电材料中的应用[D]. 天津: 河北工业大学, 2019: 1-65.
FENG Ruiqi. Preparation of fluorescent carbon dots and their applications in Fe3+ detection, fingerprint detection and photoelectric materials[D]. Tianjin: Hebei University of Technology, 2019: 1-65.
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