Chin J Plant Ecol ›› 2010, Vol. 34 ›› Issue (6): 727-740.DOI: 10.3773/j.issn.1005-264x.2010.06.012
• Review • Previous Articles Next Articles
Received:
2009-10-10
Accepted:
2010-02-05
Online:
2010-10-10
Published:
2010-06-01
Contact:
YE Zi-Piao
YE Zi-Piao. A review on modeling of responses of photosynthesis to light and CO2[J]. Chin J Plant Ecol, 2010, 34(6): 727-740.
Fig. 1 Light-response curve of photosynthesis for Triticum aestivum (Cited from Yu et al., 2004). A, Light-response curve of photosynthesis for T. aestivum fitted by four photosynthetic light response models. ○, measured points; —, points fitted by modified model; ☆, points fitted by rectangular hyperbola; ┅, points fitted by non-rectangular hyperbola; ▽, pointed fitted by exponential equation. B, Saturation irradiance estimated by four photosynthetic light response models. a, saturation irradiance obtained by a method combined non-rectangular hyperbola with line equation; b, saturation irradiance obtained by a method combined rectangular hyperbola with line equation; c, saturation irradiance, i.e. irradiance at 0.9Pnmax; d, saturation irradiance obtained by the modified model.
光合参数 Photosynthetic parameters | 初始斜率 Initial slope α | 最大净光合速率 Pnmax (μmol·m-2·s-1) | 饱和光强 Isat (μmol·m-2·s-1) | 光补偿点 Ic (μmol·m-2·s-1) | 暗呼吸速率 Rd (μmol·m-2·s-1) | 决定系数 Determination coefficient R2 |
---|---|---|---|---|---|---|
直角双曲线 Rectangular hyperbola | 0.076 | 31.01 | 671.25* | 27.08 | -1.93 | 0.996 2 |
非直角双曲线 Non-rectangular hyperbola | 0.055 | 26.78 | 583.18* | 23.10 | -1.25 | 0.998 9 |
指数方程 *** Exponential equation*** | 0.058 | 24.40 | 1 288.80** | 23.03 | -1.30 | 0.999 1 |
修正的直角双曲线 Modified rectangular hyperbola | 0.062 | 22.76 | 1 799.18 | 23.75 | -1.43 | 0.999 2 |
测量数据 Measured data | 无 None | $\approx $22.87 | $\approx $1 800 | ≈20 | -1.25 | 无 None |
Table 1 Results fitted by four models of light-response curve of photosynthesis and measured values for Triticum aestivum at 30 ℃ and 365 μmol·mol-1 CO2 concentration (Cited from Yu et al., 2004)
光合参数 Photosynthetic parameters | 初始斜率 Initial slope α | 最大净光合速率 Pnmax (μmol·m-2·s-1) | 饱和光强 Isat (μmol·m-2·s-1) | 光补偿点 Ic (μmol·m-2·s-1) | 暗呼吸速率 Rd (μmol·m-2·s-1) | 决定系数 Determination coefficient R2 |
---|---|---|---|---|---|---|
直角双曲线 Rectangular hyperbola | 0.076 | 31.01 | 671.25* | 27.08 | -1.93 | 0.996 2 |
非直角双曲线 Non-rectangular hyperbola | 0.055 | 26.78 | 583.18* | 23.10 | -1.25 | 0.998 9 |
指数方程 *** Exponential equation*** | 0.058 | 24.40 | 1 288.80** | 23.03 | -1.30 | 0.999 1 |
修正的直角双曲线 Modified rectangular hyperbola | 0.062 | 22.76 | 1 799.18 | 23.75 | -1.43 | 0.999 2 |
测量数据 Measured data | 无 None | $\approx $22.87 | $\approx $1 800 | ≈20 | -1.25 | 无 None |
Fig. 2 Light-response curve of photosynthesis for Bidens pilosa grown under low light condition (Cited from Ye & Zhao, 2008). A, Light-response curve of photosynthesis for Bidens pilosa fitted by four photosynthetic light response models. ○, measured points; —, points fitted by modified model; ☆, points fitted by rectangular hyperbola; ┅, points fitted by non-rectangular hyperbola; ▽, pointed fitted by exponential equation. B, Saturation irradiance estimated by four photosynthetic light response models. a, saturation irradiance obtained by a method combined non-rectangular hyperbola with line equation; b, saturation irradiance obtained by a method combined rectangular hyperbola with line equation; c, saturation irradiance, i.e. irradiance at 0.9Pnmax; d, saturation irradiance obtained by the modified model.
光合参数 Photosynthetic parameters | 初始斜率 Initial slope α | 最大净光合速率 Pnmax (μmol·m-2·s-1) | 饱和光强 Isat (μmol·m-2·s-1) | 光补偿点 Ic (μmol·m-2·s-1) | 暗呼吸速率 Rd (μmol·m-2·s-1) | 决定系数 Determination coefficient R2 |
---|---|---|---|---|---|---|
直角双曲线模型 Rectangular hyperbola | 0.118 | 6.69 | 199.58* | 4.39 | -0.48 | 0.939 6 |
非直角双曲线模型 Non-rectangular hyperbola | 0.042 | 5.79 | 171.33* | 无 None | 0.02 | 0.964 6 |
指数方程*** Exponential equation | 0.068 | 6.02 | 247.92** | 3.45 | -0.23 | 0.966 6 |
直角双曲线的修正模型 Modified rectangular hyperbola | 0.071 | 6.49 | 646.70 | 3.17 | -0.22 | 0.996 8 |
测量数据 Measured data | 无 None | $\approx $6.5 | $\approx $650 | ≈3 | -0.15 | 无 None |
Table 2 Results fitted by four models of light-response curve of photosynthesis and measured values for Bidens pilosa grown under low light condition (Cited from Ye & Zhao, 2008)
光合参数 Photosynthetic parameters | 初始斜率 Initial slope α | 最大净光合速率 Pnmax (μmol·m-2·s-1) | 饱和光强 Isat (μmol·m-2·s-1) | 光补偿点 Ic (μmol·m-2·s-1) | 暗呼吸速率 Rd (μmol·m-2·s-1) | 决定系数 Determination coefficient R2 |
---|---|---|---|---|---|---|
直角双曲线模型 Rectangular hyperbola | 0.118 | 6.69 | 199.58* | 4.39 | -0.48 | 0.939 6 |
非直角双曲线模型 Non-rectangular hyperbola | 0.042 | 5.79 | 171.33* | 无 None | 0.02 | 0.964 6 |
指数方程*** Exponential equation | 0.068 | 6.02 | 247.92** | 3.45 | -0.23 | 0.966 6 |
直角双曲线的修正模型 Modified rectangular hyperbola | 0.071 | 6.49 | 646.70 | 3.17 | -0.22 | 0.996 8 |
测量数据 Measured data | 无 None | $\approx $6.5 | $\approx $650 | ≈3 | -0.15 | 无 None |
Fig. 3 Intercellular CO2 response of photosynthesis for Triticum aestivum (Cited from Yu et al., 2004). A, CO2 response curve of photosynthesis for T. aestivum fitted by three CO2 response models of phtosynthesis. ○, measured points; —, points fitted by a modified model; ┅, points fitted by rectangular hyperbola or Michaelis-Menten model. B, Saturation CO2 estimated by three CO2 response models of photosynthesis. a, saturation intercellular CO2 concentration, i.e. Ci at 0.6Pnmax; b, saturation intercellular CO2 concentration obtained by the modified model.
光合参数 Photosynthesis parameter | MichaelisMenten 模型 MichaelisMenten model | 直角双曲线模型 Rectangular hyperbola model | 修正模型 Modified model | 测量值 Measured data |
---|---|---|---|---|
初始羧化效率 (mol·m-2·s-1) Initial slope α | 无None | 0.331 | 0.228 | 无None |
光合能力 (μmol·m-2·s-1) Photosynthetic capacity | 68.54 | 68.54 | 42.26 | $\approx $42.3 |
饱和胞间CO2浓度(μmol·mol-1) saturation intercellular CO2 concentration Cisat | 687.02* | 687.02* | 886.74 | $\approx $900 |
CO2补偿点 (μmol·mol-1) CO2 compensation point Γ | 45.58 | 45.58 | 47.40 | $\approx $48 |
光呼吸速率 (μmol·m-2·s-1) Rate of photorespiration Rp | -12.36 | -12.36 | -9.51 | 无 None |
决定系数 Determination coefficient (R2) | 0.991 3 | 0.991 3 | 0.998 7 | 无 None |
Table 3 Simulated results of CO2 response of photosynthesis with three models for Triticum aestivum
光合参数 Photosynthesis parameter | MichaelisMenten 模型 MichaelisMenten model | 直角双曲线模型 Rectangular hyperbola model | 修正模型 Modified model | 测量值 Measured data |
---|---|---|---|---|
初始羧化效率 (mol·m-2·s-1) Initial slope α | 无None | 0.331 | 0.228 | 无None |
光合能力 (μmol·m-2·s-1) Photosynthetic capacity | 68.54 | 68.54 | 42.26 | $\approx $42.3 |
饱和胞间CO2浓度(μmol·mol-1) saturation intercellular CO2 concentration Cisat | 687.02* | 687.02* | 886.74 | $\approx $900 |
CO2补偿点 (μmol·mol-1) CO2 compensation point Γ | 45.58 | 45.58 | 47.40 | $\approx $48 |
光呼吸速率 (μmol·m-2·s-1) Rate of photorespiration Rp | -12.36 | -12.36 | -9.51 | 无 None |
决定系数 Determination coefficient (R2) | 0.991 3 | 0.991 3 | 0.998 7 | 无 None |
[1] |
Al-Taweel K, Iwaki T, Yabuta Y, Shigeoka S, Murata N, Wadano A (2007). A bacterial transgene for catalase protects translation of D1 protein during exposure of salt-stressed tobacco leaves to strong light. Plant Physiology, 145, 258-265.
DOI URL PMID |
[2] |
Awada T, Radoglou K, Fotelli MN, Constantinidou HIA (2003). Ecophysiology of seedlings of three Mediterranean pine species in contrasting light regimes. Tree Physiology, 23, 33-41.
DOI URL PMID |
[3] | Bernacchi CJ, Singsaas EL, Pimentel C, Portis AR, Long SP (2001). Improved temperature response functions for models of Rubisco-limited photosynthesis. Plant, Cell & Environment, 24, 253-259. |
[4] | Bernacchi GJ, Pimentel C, Long SP (2003). In vivo temperature response functions of parameters required to model RuBP-limited photosynthesis. Plant, Cell & Environment, 26, 1419-1430. |
[5] |
Bassman J, Zwier JC (1991). Gas exchange characteristics of Populus trichocarpa, Populus deltoids and Populus trichocarpa × P. deltoids clone. Tree Physiology, 8, 145-159.
URL PMID |
[6] | Blackman FF (1905). Optima and limiting factors. Annals of Botany, 19, 281-295. |
[7] | Baly EC (1935). The kinetics of photosynthesis. Proceedings of the Royal Society of London Series B (Biological Sciences), 117, 218-239. |
[8] | Cai SQ, Xu DQ (2000). Relationship between the CO2 compensation point and photoresp iration in soybean leaves. Acta Phytophysiologica Sinica, 26, 545-550. |
[9] | Cao XD (曹雪丹), Li WH (李文华), Lu ZM (鲁周民), Zhang ZL (张忠良), Wu WX (吴万兴) (2008). The photosynthetic characteristics of Eriobotrya japonica in northern marginal cultivation area in Spring. Journal of Northwest Forestry University (西北林学院学报), 23(6), 33-37.(in Chinese with English abstract) |
[10] |
Chen CP, Zhu XG, Long SP (2008). The effect of leaf-level spatial variability in photosynthetic capacity on biochemical parameter estimates using the Farquhar Model: a theoretical analysis. Plant Physiology, 148, 1139-1147.
DOI URL PMID |
[11] | Damesin C (2003). Respiration and photosynthesis characteristics of current 2 year stems of Fagus sylvatica: from the seasonal pattern to an annual balance. New Phytologist, 158, 465-475. |
[12] | Ethier GJ, Livingston NJ (2004). On the need to incorporate sensitivity to CO2 transfer conductance into the Farquhar-von Caemmerer-Berry leaf photosynthesis model. Plant, Cell & Environment, 27, 137-153. |
[13] |
Farquhar GD, Caemmerers S, Berry JA (1980). A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species. Planta, 149, 78-90.
DOI URL PMID |
[14] | Geider RJ, MacIntyre HL, Kana TM (1998). A dynamic regulatory model of phytoplanktonic acclimation to, nutrients and temperatures. Limnology and Oceanography, 43, 679-694. |
[15] | Govindjee (1995). Sixty-three years since Kautsky: chlorophyll a fluorescence. Australian Journal of Plant Physiology, 22, 131-160. |
[16] | Harley PC, Sharkey TD (1991). An improved model of C3 photosynthesis at high CO2: reversed O2 sensitivity explained by lack of glycerate reentry into the chloroplast. Photosynthesis Research, 27, 169-178. |
[17] | Harley PC, Thomas RB, Reynolds JF, Strain BR (1992). Modelling photosynthesis of cotton grown in elevated CO2. Plant, Cell & Environment, 15, 271-282. |
[18] |
He QY, Liu Y (2005). Molecular mechanism of light responses in Neurospora: from light-induced transcription to photoadaptation. Genes and Development, 19, 2888-2899.
DOI URL PMID |
[19] | Hu WH (胡文海), Hu XH (胡雪华), Zeng JJ (曾建军), Duan ZH (段智辉), Ye ZP (叶子飘) (2008). Effects of drought on photosynthetic characteristics in two pepper cultivars. Journal of Huazhong Agricultural University (华中农业大学学报), 27, 776-781. (in Chinese with English abstract) |
[20] | Huang HY (黄红英), Dou XY (窦新永), Sun PY (孙蓓育), Deng B (邓斌), Wu GJ (吴国江), Peng CL (彭长连) (2009). Comparison of photosynthetic characteristics in two ecotypes of Jatropha curcas in summer. Acta Ecologica Sinica (生态学报), 29, 2861-2867. (in Chinese with English abstract) |
[21] | Hou ZY (侯智勇), Hong W (洪伟), Li J (李键), Lin H (林晗), Fan HL (范海兰), Chen C (陈灿), Wu CZ (吴承祯) (2009). Study on light response curves of photosynthesis of different Ecucalyptus clones. Journal of Fujian College of Forestry (福建农林学院学报), 29, 97-102. (in Chinese with English abstract) |
[22] |
Hymus GJ, Baker NR, Long SP (2001). Growth in elevated CO2 can both increase and decrease photochemistry and photoinhibition of photosynthesis in a predictable manner. Dactylis glomerata grown in two levels of nitrogen nutrition. Plant Physiology, 127, 1204-1211.
URL PMID |
[23] |
Inoué S, Shimomura O, Goda M, Shribak M, Tran PT (2002). Fluorescence polarization of green fluorescence protein. Proceedings of the National Academy of Sciences of the United States of America, 99, 4272-4277.
DOI URL PMID |
[24] |
Ishikita H, Loll B, Biesiadka J, Saenger W, Knapp EW (2005). Redox potentials of chlorophylls in the photosystem II reaction center. Biochemistry, 44, 4118-4124.
URL PMID |
[25] | Jia CF (贾彩凤), Li AL (李艾莲) (2008). Studies on photosynthetic characteristics of medicinal plant Fagoyrum cymosum. China Journal of Chinese Materia Medica (中国中药杂志), 33(2), 129-132. (in Chinese with English abstract) |
[26] | Kyei-Boahen S, Lada R, Astatkie T, Gordon R, Caldwell C (2003). Photosynthetic response of carrots to varying irradiances. Photosynthetica, 41, 1-5. |
[27] | Krause GH, Weis E (1991). Chlorophyll fluorescence and photosynthesis: the basics. Annual Review of Plant Physiology and Plant Molecular Biology, 42, 313-349. |
[28] |
Leakey ADB, Uribelarrea M, Ainsworth EA, Naidu SL, Rogers A, Ort DR, Long SP (2006). Photosynthesis, productivity, and yield of maize are not affected by Open-Air elevation of CO2 concentration in the absence of drought. Plant Physiology, 140, 779-790.
URL PMID |
[29] | Li WC (李伟成), Wang SD (王树东), Zhong ZK (钟哲科), Ding XC (丁兴萃), Zhou Y (周妍) (2009). Application of several empirical models in simulating photosynthesis light response of two sympodial bamboos. Journal of Bamboo Research (竹子研究汇刊), 28(3), 20-24. (in Chinese with English abstract) |
[30] | Lichtenthaler HK (1992). The Kautsky effect: 60 years of chlorophyll fluorescence induction kinetics. Photosynthetica, 27, 45-55. |
[31] |
Liu Z, Yan H, Wang K, Kuang T, Zhang J, Gui L, An X, Chang W (2004). Crystal structure of spinach major light-harvesting complex at 2.72Å resolution. Nature, 428, 287-292.
DOI URL |
[32] | Lombardini L, Restrepo-Diaz H, Volder A (2009). Photosynthetic light response and epidermal characteristics of sun and shade pecan leaves. Journal of the Americal Society for Horticultural Science, 134, 372-378. |
[33] |
Long SP, Bernacchi CJ (2003). Gas exchange measurements, what can they tell us about the underlying limitations to photosynthesis? Procedures and sources of error. Journal of Experimental Botany, 54, 2393-2401.
DOI URL PMID |
[34] |
Long SP, Humpheris S, Falkowski PG (1994). Photoinhibition of photosynthesis in nature. Annual Review of Plant Physiology and Plant Molecular Biology, 45, 633-662.
DOI URL |
[35] |
Marra J (1978a). Effect of short term variation in light intensity on photosynthesis of a marine phytoplankton: a laboratory simulation study. Marine Biology, 46, 191-202.
DOI URL |
[36] |
Marra J (1978b). Phytoplankton photosynthesis response vertical movement in a mixing layer. Marine Biology, 46, 203-208.
DOI URL |
[37] |
Moreno-Sotomayor A, Weiss A, Paparozzi ET, Arkebauer TJ (2002). Stability of leaf anatomy and light response curves of field grown maize as a function of age and nitrogen status. Journal of Plant Physiology, 159, 819-826.
DOI URL |
[38] |
Navarro-Sampedro L, Yanofsky C, Corrochano LM (2008). A genetic selection for Neurospora crassa mutants altered in their light regulation of transcription. Genetics, 178, 171-183.
DOI URL PMID |
[39] | Osmond CB (1994). What is photoinhibition? Some insights from comparisons of shade and sun plants. In: Baker NR ed. Photoinhibition of Photosynthesis: from Molecular Mechanisms to Field BIOS Scientific Publishers, Oxford. 1-24. |
[40] |
Posada JM, Lechowicz MJ, Kitajima K (2009). Optimal photosynthetic use of light by tropical tree crowns achieved by adjustment of individual leaf angles and nitrogen content. Annals of Botany, 103, 795-805.
DOI URL PMID |
[41] |
Prado CHBA, Moraes JAPV (1997). Photosynthetic capacity and specific leaf mass in twenty woody species of Cerrado vegetation under field condition. Photosynthetica, 33, 103-112.
DOI URL |
[42] | Raszewski G, Saenger W, Renger T (2005). Theory of optical spectra of photosystem II reaction centers: location of the triplet state and the identity of the primary electron donor. Biophysiology Journal, 88, 986-998. |
[43] |
Robert ES, Mark A, John SB (1984). Kok effect and the quantum yield of photosynthesis. Plant Physiology, 75, 95-101.
URL PMID |
[44] | Sekatskii SK (2004). Fluorescence resonance energy transfer scanning near-field optical microscopy. Philosophical Transactions of the Royal Society A: Mathematical Physical & Engineering Sciences, 362, 901-919. |
[45] |
Sharkey TD (1985). O2-insensitive photosynthesis in C3 plants. its occurrence and a possible explanation. Plant Physiology, 78, 71-75.
DOI URL PMID |
[46] |
Sharkey TD, Bernacchi CJ, Farquhar GD, Singsaas EL (2007). Fitting photosynthetic carbon dioxide response curves for C3 leaves. Plant, Cell & Environment, 30, 1035-1040.
DOI URL PMID |
[47] |
Springer CJ, Thomas RB (2007). Photosynthetic responses of forest understory tree species to long-term exposure to elevated carbon dioxide concentration at the Duke Forest FACE experiment. Tree Physiology, 27, 25-32.
DOI URL PMID |
[48] | Sun XS (孙旭生), Lin Q (林琪), Jiang W (姜雯), Li LY (李玲燕), Zhai YJ (翟延举) (2009). Effects of different amount of nitrogen supply on the CO2-response curve in flag leaves of super high-yield winter wheat at flowering stage. Journal of Triticeae Crops (麦类作物学报), 29, 303-307. (in Chinese with English abstract) |
[49] |
Takahashi S, Milward SE, Fan DY, Chow WS, Badger MR (2009). How does cyclic electron flow alleviate photoinhibition in Arabidopsis? Plant Physiology, 149, 1560-1567.
DOI URL PMID |
[50] | Thornley JHM (1976). Mathematical Models in Plant Physiology. Academic Press, London. 86-110. |
[51] | van der Weij-de Wit CD, Doust AB, van Stokkum IH, Dekker JP, Wilk KE, Curmi PM, van Grondelle R (2008). Phycocyanin sensitizes both photosystem I and photosystem II in cryptophyte Chroomonas CCMP270 cells. Biophysio- logy Journal, 94, 2423-2433. |
[52] |
van der Weij-de Wit CD, Ihalainen JA, van Grondelle R, Dekker JP (2007). Excitation energy transfer in native and unstacked thylakoid membranes studied by low temperature and ultrafast fluorescence spectroscopy. Photosynthesis Research, 93, 173-182.
URL PMID |
[53] | Vasil’ev S, Bruce D (2006). A protein dynamics study of photosystem II: the effects of protein conformation on reaction center function. Biophysiology Journal, 90, 3062-3073. |
[54] | von Caemmerer S (2000). Biochemical Models of Leaf Photosynthesis, Techniques in Plant Sciences No. 2. CSIRO Publishing, Collingwood, Victoria, Australia. 1-165. |
[55] |
von Caemmerer S, Farquhar GD (1981). Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta, 153, 376-387.
DOI URL PMID |
[56] | Wang JL (王建林), Yu GR (于贵瑞), Wang BL (王伯伦), Qi H (齐华), Xu ZJ (徐正进) (2005). Response of photosynthetic rate and stomatal conductance of rice to light intensity and CO2 concentration in Northern China. Acta Phytoecologica Sinica (植物生态学报), 29, 16-25. (in Chinese with English abstract) |
[57] | Wang ML (王满莲), Feng YL (冯玉龙), Li X (李新) (2006). Effects of soil phosphorus level on morphological and photosynthetic characteristics of Ageratina adenophora and Chromolaena odorata. Chinese Journal of Applied Ecology (应用生态学报), 17, 602-606. (in Chinese with English abstract) |
[58] | Wang ZL (王照兰), Yang C (杨持), Du JC (杜建材), Hu HF (胡卉芳), Zhao LL (赵丽丽), Mao XT (毛小涛) (2009). Photosynthetic characteristics and photo-adapt ability of four Melilotoides ruthenica ecotypes. Chinese Journal of Plant Ecology (生态学杂志), 28, 1035-1040. (in Chinese with English abstract) |
[59] | Watling JR, Press MC, Quick WP (2000). Elevated CO2 induces biochemical and ultrastructural changes in leaves of the C4 cereal sorghum. Plant Physiology, 123, 1143-1152. |
[60] | Weis E, Berry JA (1987). Quantum efficiency of PSII in relation to energy dependent quenching of chlorophyll fluorescence. Biochimica Biophysica Acta, 894, 198-208. |
[61] | Xu DQ (许大全) (2002). Photosynthetic Efficiency (光合作用效率). Shanghai Science and Technology Press, Shanghai. 15. (in Chinese) |
[62] | Xu CH (徐春和), Mi HL (米华玲) (2001). The primary reaction of photosynthesis. In: Yu SW (余叔文), Tang ZC (汤章城) eds. Plant Physiology and Molecular Biology (植物生理与分子生物学). Science Press, Beijing. 188-197. (in Chinese) |
[63] | Yan GG (严国光) (1987). Light energy absorption and transmission. In: Yan GG (严国光), Zhou PZ (周佩珍), Guo C (郭础), Dai YL (戴云玲) eds. Primary Process of Photosynthesis (光合作用的原初过程). Science Press, Beijing. 62-102. (in Chinese) |
[64] |
Ye ZP (2007). A new model for relationship between light intensity and the rate of photosynthesis in Oryza sativa. Photosynthetica, 45, 637-640.
DOI URL |
[65] | Ye ZP (叶子飘), Yu Q (于强) (2008). Comparison of new and several classical models of photosynthesis in response to irradiance. Journal of Plant Ecology (Chinese Version) (植物生态学报), 32, 1356-1361. (in Chinese with English abstract) |
[66] |
Ye ZP, Yu Q (2008). A coupled model of stomatal conductance and photosynthesis for winter wheat. Photosynthetica, 46, 637-640.
DOI URL |
[67] | Ye ZP, Zhao ZH (2008). Primary application on a light-response model to describe light response curve of Bidens pilosa leaf net photosynthesis, grown at two different light intensities. Proceedings of the 6th Conference of Biomathematics. World Academic Press, England, UK. 889-892. |
[68] | Ye ZP (叶子飘), Yu Q (于强) (2009). Comparison of photosynthetic response to intercellular CO2 and air CO2. Chinese Journal of Ecology (生态学杂志), 28, 2233-2238. (in Chinese with English abstract) |
[69] |
Yu Q, Zhang YQ, Liu YF, Shi PL (2004). Simulation of the stomatal conductance of winter wheat in response to light, temperature and CO2 changes. Annals of Botany, 93, 435-441.
DOI URL PMID |
[70] | Zhang ZF (张中峰), Huang YQ (黄玉清), Mo L (莫凌), You YM (尤业明), Jiao JF (焦继飞) (2009). Comparison of two photosynthesis-light response curve—fitting models of the karst plant. Journal of Wuhan Botanical Research (武汉植物学研究), 27, 340-344. (in Chinese with English abstract) |
[71] | Zhang XS (张雪松) , Shen SH (申双和), Song J (宋洁) (2009). The vertical distribution of cotton leaf nitrogen content and photosynthetic characteristics in the North China Plain. Acta Ecologica Sinica (生态学报), 29, 1893-1898. (in Chinese with English abstract) |
[1] | Zi-Piao YE, Shi-Hua DUAN, Ting AN, Hua-Jing KANG. Determination of maximum electron transport rate and its impact on allocation of electron flow [J]. Chin J Plant Ecol, 2018, 42(4): 498-507. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||
Copyright © 2022 Chinese Journal of Plant Ecology
Tel: 010-62836134, 62836138, E-mail: apes@ibcas.ac.cn, cjpe@ibcas.ac.cn