The Theory and Simulation Studies of Stomatal Conductance at Night

doi:10.13466/j.cnki.lyzygl.2019.02.020

Abstract

Abstract:

Stomata is an important organ in plant physiological process.It is important to analyze the stomatal behavior of plant leaves in order to simulate their physiological and ecological processes and hydrological cycles.Traditional theory thinks that the stomata of plants is closed,while more and more evidences show that the stomata is not completely shut down,and this phenomenon may exist widely in plant.Previous theories and researches have not fully explained the night stomatal conductance response to various environmental factors,and the relationships between them still have some obscure places.In this study,we then synthesized the recent developments and lessons in night stomatal conductance theory and simulation,including the change characteristics and driving factors of night stomatal conductance on the time scale,and analyzed the stomatal conductance model.Future research will focus on time scale expansion and related model simulation analysis.

Key words: the stomatal conductance at night, change characteristics, environmental factors, response, model

CLC Number:

Q945.1

GONG Yinting, ZHENG Guilian, REN Zhengxing. The Theory and Simulation Studies of Stomatal Conductance at Night[J]. FOREST RESOURCES WANAGEMENT, 2019, 0(2): 137-141.

References 45

[1]	袁国富, 庄伟, 罗毅. 冬小麦叶片气孔导度模型水分响应函数的参数化[J]. 植物生态学报, 2012,36(5):463-470.
[2]	孙谷畴, 赵平, 曾小平, 等. 亚热带森林演替树种叶片气孔导度对环境水分的水力响应[J]. 生态学报, 2009,29(2):698-705.
[3]	赵平, 刘惠, 孙谷畴. 4种植物气孔对水汽压亏缺敏感度的种间差异[J]. 中山大学学报:自然科学版, 2007,46(4):63-68.
[4]	Gao Qiong, Zhao Ping, Zeng Xiaoping,et al.A model of stomatal conductance to quantify the relationship between leaf transpiration,microclimate and soil water stress[J]. Plant,Cell and Environment, 2002,25:1373-1381.
[5]	高冠龙, 张小由, 常宗强, 等. 植物气孔导度的环境响应模拟及其尺度扩展[J]. 生态学报, 2016,36(6):1-10.
[6]	司建华, 冯起, 鱼腾飞, 等. 植物夜间蒸腾及其生态水文效应研究进展[J]. 水科学进展, 2014,25(6):907-914.
[7]	Fishier J B, Baldocchi D D, Misson L. What the towers don’t see at night:Nocturnal sap flow in trees and shrubs at two AmeriFlux sites in California[J]. Tree Physiology, 2007,27:597-610. doi: 10.1093/treephys/27.4.597 pmid: 17242001
[8]	Snyder K A, Richards J H, Donovan L A. Night-time conductance in C₃ and C₄ species:Do plants lose water at night[J]? Journal of Experimental Botany, 2003,54:861-865. pmid: 12554729
[9]	Dawson T E, Burges S S O, Tu K P,et al.Nighttime transpiration in woody plants from contrasting ecosystems[J]. Tree Physiology, 2007,27:561-575. doi: 10.1093/treephys/27.4.561 pmid: 17241998
[10]	Bucci S J, Scholz F G, Goldstein G, et al. Processes preventing nocturnal equilibration between leaf and soil water potential in tropical savanna woody species[J]. Tree Physiology, 2004,24:1119-1127. pmid: 15294758
[11]	Baldocchi D. A comparative study of mass and energy exchange rates over a closed C₃ (wheat) and an open C₄ (corn) crop:II.CO₂ exchange and water use efficiency[J]. Agricultural & Forest Meteorology, 1994,67(3-4):291-321.
[12]	Caird M A, Richards J H, Donovan L A. Nighttime stomatal conductance and transpiration in C₃ and C₄ plants[J]. Plant Physiology, 2007,143:4-10. doi: 10.1104/pp.106.092940 pmid: 17210908
[13]	Novick K A, Oren R, Stoy P C, et al. Nocturnal evapotranspiration in eddy-covariance records from three co-located ecosystems in the Southeastern US:implications for annual fluxes[J]. Agricultural and Forest Meteorology, 2009,149:1491-1504.
[14]	Philips N G, Ryan M G, Bond B J, et al. Reliance on stored water increases with tree size in three species in the Pacific Northwest[J]. Tree Physiology, 2003,23:237-245. pmid: 12566259
[15]	Loftfield J V G. The behavior of stomata[M]. Carnegie Institution of Washington, 1921.
[16]	Donovan L A, Richiards J H, Linton M J. Magnitude and mechanisms of disequilibrium between predawn plant and soil water potentials[J]. Ecology, 2003,84:463-470.
[17]	Ludwig F, Jewitt R A, Donovan L A. Nutrient and water addition effects on day-and night-time conductance and transpiration in a C₃ desert annual[J]. Oecologia, 2006,148:219-225. pmid: 16456684
[18]	Bucci S J, Goldstein G, Meinzer F C, et al. Mechanisms contributing to seasonal homeostasis of minimum leaf water potential and predawn disequilibrium between soil and plant water potential in neotropical savanna trees[J]. Trees Structure and Function, 2005,19:296-304.
[19]	Domec J C, Scholz F G, Bucci S J, et al. Diurnal and seasonal variation in root xylem embolism in neotropical savanna woody species:impact on stomatal control of plant water status[J]. Plant Cell Environ, 2006,29:26-35. doi: 10.1111/j.1365-3040.2005.01397.x pmid: 17086750
[20]	Scholz F G, Bucci S J, Goldstein G, et al. Removal of nutrient limitations by long-term fertilization decreases nocturnal water loss in savanna trees[J]. Tree Physiology, 2007,27(4):551-9. doi: 10.1093/treephys/27.4.551 pmid: 17241997
[21]	Barbour M M, Buckley T N. The stomatal response to evaporative demand persists at night in Ricinuscommunis plants with high nocturnal conductance[J]. Plant,Cell and Environment, 2007,30:711-721. doi: 10.1111/j.1365-3040.2007.01658.x pmid: 17470147
[22]	Daley M J, Phillips N G. Interspecific variation in nighttime transpiration and stomatal conductance in a mixed New England deciduous forest[J]. Tree Physiol, 2006,26:411-419. doi: 10.1093/treephys/26.4.411 pmid: 16414920
[23]	Kavanagh K L, Pangle R, Schotzko A D. Nocturnal transpiration causing disequilibrium between soil and stem predawn water potential in mixed conifer forests of Idaho[J]. Tree Physiology, 2007,27(4):621-629. doi: 10.1093/treephys/27.4.621 pmid: 17242003
[24]	Donovan L A, Richiards J H, Linton M J. Magnitude and mechanisms of disequilibrium between predawn plant and soil water potentials[J]. Ecology, 2003,84:463-470.
[25]	Dodd A N, Salathia N, Hall A, et al. Plant circadian clocks increase photosynjournal,growth,survival,and competitive advantage[J]. Science, 2005,309:630-633. doi: 10.1126/science.1115581 pmid: 16040710
[26]	Howard A R, Donovan L A. Helianthus nighttime conductance and transpiration respond to soil water but not nutrient availability[J]. Plant Physiol, 2007,143:145-155. doi: 10.1104/pp.106.089383 pmid: 17142487
[27]	Lasceve G, Leymarie J, Vavasseur A. Alterations in light-induced stomatal opening in a starch-deficient mutant of Arabidopsis thaliana L.deficient in chloroplast phosphoglucomutase activity. Plant Cell Environ, 1997,20:350-358.
[28]	Drake P L, Froend R H, Franks P J. Smaller,faster stomata:scaling of stomatal size,rate of response,and stomatalconductance[J]. Journal of Experimental Botany, 2013,64(2):495-505. doi: 10.1093/jxb/ers347 pmid: 23264516
[29]	Franks P J, Farquhar G D. The mechanical diversity of stomata and its significance in gas-exchange control[J]. Plant Physiology, 2007,143:78-87. doi: 10.1104/pp.106.089367 pmid: 17114276
[30]	Barbour M M, Cernusak L A, Whitehead D, et al. Nocturnal stomatal conductance and implications for modeling δ¹⁸Oof leaf-respired CO₂ in temperate tree species[J]. Functional Plant Biology, 2005,32:1107-1121. doi: 10.1071/FP05118 pmid: 32689205
[31]	Marks C O, Lechowicz M J. The ecological and functional correlates of nocturnal transpiration[J]. Tree Physiology, 2007,27:577-584. pmid: 17241999
[32]	Grulke N E, Alonso R, Nguyen T, et al. Stomata open at night in pole-sized and mature ponderosa pine:implications for O₃ exposure metrics[J]. Tree Physiol, 2004,24:1001-1010. doi: 10.1093/treephys/24.9.1001 pmid: 15234897
[33]	Zeppel M, Lewis J, Chaszar B, et al. Nocturnal stomatal conductance responses to rising CO₂,temperature and drought[J]. New Phytologist, 2012,193:929-938. doi: 10.1111/j.1469-8137.2011.03993.x pmid: 22150067
[34]	Zeppel M J B, Lewis J D, Medlyn B E, et al. Interactive effects of elevatedCO₂and drought on nocturnal water fluxes in Eucalyptus saligna[J]. Tree Physiology, 2011,31:932-944. doi: 10.1093/treephys/tpr024 pmid: 21616926
[35]	Oren R, Sperry J S, Ewers B E, et al. Sensitivity of mean canopy stomatal conductance to vapor pressure deficit in flooded Taxodiumdistichum L.forest:hydraulic and nonhydraulic effects[J]. Oecologia, 2001,126:21-29. doi: 10.1007/s004420000497 pmid: 28547434
[36]	Iritz Z, Lindroth A. Nighttime evaporation from a shortrotation willow stand[J]. J Hydrol, 1994,157:235-245.
[37]	Benyon R. Nighttime water use in an irrigated Eucalyptus grandis plantation[J]. Tree Physiology, 1999,19:853-859. doi: 10.1093/treephys/19.13.853 pmid: 10562402
[38]	Ludwig F, Jewitt R A, Donovan L A. Nutrient and water addition effects on day- and night-time conductance and transpiration in a C₃ desert annual. Oecologia, 2006,148:219-225.
[39]	Jarvis P G. The interpretation of the variations in leaf water potential and stomatal conductance found in canopies in the field[J]. Philosophical Transactions of the Royal Society of London.Series B, 1976,273:593-610.
[40]	Ball J T, Woodrow I E, Berry J A. A model predicting stomatal conductance and its contribution to the control of photosynconfproc under different environmental conditions [C]//Progress in Photosynconfproc Research.Dordrecht,Netherlands:MartinusNijhoff Publishers, 1987: 221-224.
[41]	White D A, Beadle C, Sands P J, et al. Quantifying the effect of cumulative water stress on stomatal conductance of Eucalyptus globulus and Eucalyptus nitens:a phenomenological approach[J]. Australian Journal of Plant Physiology, 1999,26:17-27.
[42]	Noe S M, Giersch C. A simple dynamic model of photosynjournal in oak leaves:coupling leaf conductance and photosynthetic carbon fixation by a variable intracellular CO₂ pool[J]. Functional Plant Biology, 2004,31:1196-1204.
[43]	叶子飘, 于强. 植物气孔导度的机理模型[J]. 植物生态学报, 2009,33(4):772-782.
[44]	Leuning R. A critical appraisal of a combined stomatal-photosynjournal model forC₃plants[J]. Plant,Cell & Environment, 1995,18:339-355.
[45]	周莉, 周广胜, 贾庆宇, 等. 2006. 盘锦湿地芦苇叶片气孔导度的模拟[J]. 气象与环境学报, 22(4):42-46.