[1] BISCHOF K, PERALTA G, KRABS G, et al. Effects of solar UV-B radiation on canopy structure of Ulva communities from southern Spain［J］. J Experimental Botany, 2002, 53(379): 2411-2421.

[2] KAKANI V G, REDDY K R, ZHAO D, et al. Effects of ultraviolet-B radiation on cotton (Gossypium hirsutum L.) morphology and anatomy［J］. Annals Botany, 2003, 91(7): 817-826.

[3] BAKER N R, ROSENQVIST E. Applications of chlorophyll fluorescence can improve crop production strategies: an examination of future possibilities［J］. J Experimental Botany, 2004, 55(403):1607-1621.

[4] HULSEN K, TOP E M, HOFTE M. Biodegradation of linuron in a phaseolus bioassay detected by chlorophyll fluorescence［J］. New Phytologist, 2000, 154(3): 821-829.

[5] GMEZ I, FIGUEROA F L. Effects of solar UV stress on chlorophyll fluorescence kinetics of intertidal macroalgae from southern Spain: a case study in Gelidium species［J］. J Applied Phycology 1998, 10(3): 285-294.

[6] LIN Wen-xiong, WU Xing-chun, LIANG Yi-yuan, et al. Effects of enhanced UV-B radiation stress on kinetics of chlorophyll fluorescence in rice (Oryza sativa L.)［J］. Chinese Journal of Eco-Agriculture, 2002, 10(1): 8-12.

[7] PRABHA G L, KULANDAIVELU G. Induced UV-B resistance against photosynthesis damage by adaptive mutagenesis in synechococcus PCC 7924［J］. Plant Science, 2002, 162(55): 663-669.

[8] LIU Li-xia, Xu Shou-min, WOO K C. Solar UV-B radiation on growth, photosynthesis and the xanthophyll cycle in tropical acacias and eucalyptus［J］. Environmental and Experimental Botany, 2005, 54(2): 121-130.

[9] WANG Xiao-jin, ZHANG Yu, ZHANG Li-xing, et al. Nariclasine effects on chlorophyll fluorescence parameters and thylakoid-membrane protein com plexes in in vitro virescent cotyledons of radish［J］. Acta Botanic Borea1i-Occidentalia Sinica, 2006, 26(2): 0259-0265

[10] DU Ling-fang. Preparation and storage of PS II particles with high oxygen-evolution activity［J］. Plant Physiology Communications, 1995, 31(3): 212-215.

[11] SHENG Lan-sun, BAI Mei. Study on the spectral interference and correction method in ICP-AES［J］.J Data Acquisition and Processing, 1989,4(A10):72-76.

[12] GARLASCHI F M, ZUCCHELLI G, GIAVAZZI P. Gaussian band analysis of absorption, fluorescence and photobleaching difference spectra of D1/D~cyt b-559 complex［J］. Photosynth Res, 1994, 41(3): 465-473.

[13] VASIL′EV S, ORTH P, ZOUNI A, et al. Excited-state dynamics in photosystem II: Insights from the X-ray crystal structure［J］. PNAS, 2001, 98(15): 8602-8607.

[14] GROOT M L, FRESE R N, DE WEERD F L, et al. Spectroscopic properties of the CP43 core antenna protein of photosystem II［J］. Biophys J, 1999, 77(6): 3328-3340.

[15] GOPAL R, MISHRA K B, ZEESHAN M, et al. Laser-induced chlorophyll fluorescence spectra of mung plants growing under nickel stress［J］. Curr Sci, 2002, 83(7): 880-884.

[16] LIU Z F, YAN H C, WANG K B, et al. Crystal structure of spinach major light-harvesting complex at 2.72 resolution［J］. Nature, 2004, 428(3): 287-292.

[17] MISHRA K B, GOPAL R. Study of laser-induced fluorescence signatures from leaves of wheat seedlings growing under cadmium stress［J］. Gen Appl Plant Physiol, 2005, 31(3-4): 181-196.

[18] WEN X G, GONG H M, LU C M. Heat stress induces an inhibition of excitation energy transfer from phycobilisomes to photosystem II but not to photosystem I in a cyanobacterium Spirulina platensis［J］. Plant Physiol Bioch, 2005, 43(4): 389-395.

[19] XU Si-chuan, AI Xi-chen, SHUN Zhao-yong, et al. Ultrafast spectroscopic studies on the isolated PS if particles from pseudo ginseng, water hyacinth and spinach leaves［J］. Acta Chimica Sinica, 2001, 59(6): 937-944.

[20] VELITCHKOVA M, POPOVA A. High light-induced changes of 77 K fluorescence emission of pea thylakoid membranes with altered membrane fluidity［J］. Bioelectrochemistry, 2005, 67(1): 81-90.

[21] VASS I, KIRILOVSKY D, PEREWOSKA I, et al. UV-B radiation induced exchange of the D1 reaction centre subunits produced from the psbA2 and psbA3 genes in the cyanobacterium Synechocystis sp. PCC 6803［J］. European Journal of Biochemistry, 2000, 267(9): 2640-2648.

[22] CAI Xia, WANG Shui-cai, HE Jun-fang, et al. Effect of temperature ascending on energy transfer of Chl a in CP47 and CP47/D1/D2/Cyt b559 of PSⅡ［J］. Acta Botanic Borea1i-Occidentalia Sinica, 2003, 23(7): 853-855.

[23] LIU Xiao, WANG Shui-cai, HE Jun-fang, et al. Fluorescence spectra properties of PSⅡ particle complex at low temperature［J］.Acta Photonic Sinica, 2004, 33(1): 60-64.

[24] UNDERWOOD G J C, NILSSON C, SUNDCK K, et al. Short-term effects of UV-B radiation on chlorophyll fluorescence, biomass, pigments, and carbohydrate fractions in a benthic diatom mat［J］. J Phycology, 1999, 35(4): 656-666.

[25] TAKEUCHI A, YAMAGUCHI T, HIDEMA J, et al. Changes in synthesis and degradation of Rubisco and LHCII with leaf age in rice (Oryza sativa L.) growing under supplementary UV-B radiation［J］. Plant Cell Environment, 2002, 25(6): 695-706.

[26] YU S G, BJRN L O. Ultraviolet B stimulates grana formation in chloroplasts in the African desert plant Dimorphotheca Pluvialis［J］. J Photochemistry Photobiolgy B：Biology, 1999, 49(1): 65-70.

[27] ALLEN D J, NOGUS S, MORISON J I L, et al. A thirty percent increase in UV-B has no impact on photosynthesis in well-watered and droughted pea plants in the field［J］. Global Change Biology, 1995, 5(2): 235-244.

[28] SHI S B, LI W Y, HUI M, et al. Photosynthes is of Saussurea superba and Gentiana straminea is not reduced after long-term enhancement of UV-B radiation［J］. Environmental and Experimental Botany, 2004, 51(1): 75-83.

[29] XIONG F S. Evidence that UV-B tolerance of the photosynthetic apparatus in microalgae is related to the D1-turnover mediated repair cycle in vivo［J］. J Plant Physiology, 2001, 158(3): 285-294.

[30] FENG H Y, AN L Z, CHEN T, et al. The effect of enhanced ultraviolet-B radiation on growth, photosynthesis and stable carbon isotope composition (δ13C) of two soybean cultivars (Glycine max) under field condition［J］. Environmental and Experimental Botany, 2003, 49(1): 1-8.

[31] CAI Heng-jiang, TANG Xu-er, ZHANG Pei-yu, et al. Effects of UV-B radiation on the growth and physiological characteristics of Platymonas gelgolandica［J］. Advances in Marine Science, 2005, 23(4): 460-465.

[32] WEI Ai-li, WANG Zhi-min. Research advances of molecular mechanism of photoinhibition and photodamage mechanism in PS Ⅱof higher plants［J］. Acta Botany Borea1 Occident Sinica, 2004, 24(7): 1342-1347.

[33] ZHANG Jin-min, ZHAO Jin-quan, JIANG Li-jin. Study of energy transfer mechanism in phycobilisomes-thylakoid membrane complex-the state conversion technology and spectroscopy deconvolution methods［J］. Chinese Science Bu1letin, 1997, 42(21): 2296-2299.

[34] SHAN J X, WANG J H, RUAN X, et al. Changes of absorption spectra during heat -induced denaturation of Photosystem II core antenna complexes CP43 and CP47: revealing the binding states of chlorophyll molecules in these two complexes［J］. Biochimica et Biophysica Acta, 2001, 1504(2-3): 396-408.

[35] CAI Xia, WANG Shui-cai, HE Jun-fang, et al. Low-temperature fluorescence spectroscopy and kinetics in the photosystem II core complex［J］. Acta Photonic Sinica, 2008, 37(7): 1441-1445.

[36] JI Qian-ru, LIU Xiao, HE Jun-fang, et al. Stead-state fluorescence spectrum analysis of thylakoid membranes of etiolated maize seedlings［J］. Acta Photonic Sinica, 2008, 37(12): 2486-2491.

[37] KUANG Ting-yun. Principle and control of the process of primary light energy conversion of photosynthesis［M］. Jiangsu: Phoenix Science Press, 2003: 39.

[38] BARBATO R, FRISO G, RIGONI F, et al. Structural changes and lateral redistribution of photosystem II during donor side photoinhibition of thylakoids［J］. The Journal of Cell Biology, 1992, 119(2): 325-335.