| 光谱学与光谱分析 |
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| Resonance Scattering Spectral Properties of CdTe Nanoparticles and Its Application |
| WANG Su-mei,JIANG Zhi-liang,LIANG Ai-hui* |
| Department of Material and Chemical Engineering, Guilin University of Technology, Key Laboratory of New Processing Technology for Nonferrous Metals and Materials, Ministry of Education, Guilin 541004, China |
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Abstract In the present paper, CdTe quantum dots were prepared, and the resonance scattering, fluorescence and absorption spectral properties of CdTe quantum dots in aqueous solution were studied in details. The fluorescence spectral results showed that the CdTe quantum dots of 3.8,4.0 and 4.6 nm in diameter have fluorescence peaks at 601,625 and 654 nm, respectively, the fluorescence peak (λF) red shifts,and the fluorescence intensity is proportional to the CdTe concentration. The linear relationship was found between the fluorescence peak wavelength and the logarithm of the diameter. The relationships was λF=126.74 ln(d)+395.92, with a related coefficient of 0.994 5. For CdTe quantum dots of 3.8 nm in size, the fluorescence intensity at 601 nm was proportional to the concentration in the range of 11.25-540 μmol·L-1. The regression equation is F601 nm=0.722 3c+3.28, with a correlation coefficient of 0.998 0. The absorption spectral results showed that the CdTe quantum dots of 3.8,4.0 and 4.6 nm in diameter have absorption peak at 550,573 and 590 nm, respectively. The absorption value is proportional to CdTe quantum dots concentration. For CdTe quantum dots of 3.8 nm in size, the concentration in the range of 11.25-180.0 μmol·L-1 obeys Lamb-Beer’s law. The absorption peak (λA) also red shifted and widened, absorption value decreased with the diameter(d). The linear relationship was found between the absorption peak wavelength and the logarithm of the diameter. The relationships was λA =155.01 ln(d)+415.52, with a related coefficient of 0.995 6. The resonance scattering (RS) spectra showed that the CdTe quantum dots of 3.8,4.0,4.6,4.8,5.2,6.5 and 8.6 nm in diameter have resonance scattering peaks at 597.94, 622.02, 645.94, 654.05,656.95, 700.98, 735 nm respectively. The RS peak wavelength λR is also proportional to the logarithm of the diameter of CdTe quantum dots . Its regression equation is λR =148.37 ln(d)+418.08 and the correlation coefficient is 0.995 2. For CdTe quantum dots with the same diameter such as 3.8 nm, the resonance scattering intensity at 597 nm is proportional to the CdTe concentration. The linear range is 22.5-180.0 μmol·L-1, the regression equation is I597 nm=0.572 1c+5.884, and the correlation coefficient is 0.997 5. A new resonance scattering method was applied to the determination of the diameter of CdTe quantum dots, with the advantages of simplicity, quick operation and good practical values.
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Received: 2007-05-26
Accepted: 2007-09-29
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Corresponding Authors:
LIANG Ai-hui
E-mail: ahliang@glite.edu.cn
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[1] WAN Yi, LIN Zhang-bi, CHEN Qi-dan,et al(万 异,林章碧,陈奇丹, 等). Anal. Instr.(分析仪器),2004,(3):41.
[2] ZHENG Hua-jing,ZHENG Jia-gui,FENG Liang-huan,et al(郑华靖,郑家贵,冯良桓, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2005,25(7):1071.
[3] WANG Wei, ZHANG Ji-mei, GUO Ning,et al(王 韦,张纪梅,郭 宁, 等). Chinese Journal of Applied Chemistry (应用化学),2006, 23(4): 435.
[4] CHEN Chen-jia, WANG Xue-zhong, Bellani V(陈辰嘉, 王学忠, Bellani V). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006,26(3):396.
[5] QIN Yuan-bin, YANG Xi, YU Jun-sheng(秦元斌,杨 曦,于俊生). Chinese Journal of Inorganic Chemistry(无机化学学报),2006,22(5):851.
[6] WANG Ke-min, WANG Yi-lin, LI Zhao-hui,et al(王柯敏,王益林,李朝辉, 等). Chinese Journal of Analytical Chemistry(分析化学),2005,33(3):1.
[7] ZHANG Peng, LI Zi-jun, XIAO Jing-lin(张 鹏,李子军,肖景林). Journal of Optoelectronics·Laser(光电子·激光),1999,10(5):451.
[8] LI Jun, YUAN Hang, ZHAO Kui, et al(李 军,袁 航,赵 奎, 等). Chem. J. Chinese Universities(高等学校化学学报),2003,24(7):1293.
[9] Lin Z B, Cui S X, Zhang H, et al. Anal. Biochem., 2003, 319: 239.
[10] Ellen R. Goldman I L, Medintz H M. Anal. Bioanal. Chem., 2006, 384: 560.
[11] Andrei S S, Almudena M J, Wofgang J P, et al. Colloids and Surfaces, 2006, 281: 40.
[12] Jiang Z L, Sun S J, Liang A H, et al. Clin. Chemistry, 2006, 52: 1389.
[13] Jiang Z L, Zhou S M, Liang A H, et al. Environ. Sci. Technol., 2006, 40: 4286.
[14] DENG Jun-yao, SUN Shuang-jiao, JIANG Zhi-liang, et al(邓峻耀, 孙双娇, 蒋治良, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006, 26(8): 1487.
[15] LIANG Ai-hui, CHEN Yuan-yuan, JIANG Zhi-liang(梁爱惠,陈媛媛,蒋治良). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006, 26(6): 1088.
[16] Liang A H, Zhou S M, Jiang Z L. Talanta, 2006, 70: 444.
[17] CHENG Yun-yan, JIANG Zhi-liang, LIANG Ai-hui(程云燕,蒋治良,梁爱惠). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006, 26(10):1888.
[18] JIANG Zhi-liang, CHEN Yuan-yuan, LIANG Ai-hui, et al(蒋治良,陈媛媛,梁爱惠, 等). Science in China, Series B(中国科学-B辑), 2006, 36(5):418.
[19] Yu W W, Qu L H, Guo W Z, et al. Chem. Mater., 2003, 15(14): 2854.
[20] Mahtab R, Rogers J P, Singleton C P M, et al. Journal of Am. Chem. Soc., 1996, 118:7028. |
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