應用
Y(II)或ΔF/FM’ 或 (FM’ – FS )/FM’) 是經受時間考驗的光適應測量參數(shù)���,比FV/FM對更多類型的植物脅迫更加敏感��。已有的大量證據表明FV/FM對許多種植物脅迫和健康植物的光系統(tǒng)II的測量十分出色�,而Y(II)或光量子產額則可測量實際光照下光適應環(huán)境和生理狀況的光系統(tǒng)II的效率。
原理
采用調制飽和脈沖原理�����,測量植物的葉綠素熒光����,通過相關文獻的研究成果�,計算植物的光量子產額及相對電子傳遞速率,同時可測量PAR�、葉溫、相對濕度等環(huán)境參數(shù)�����。
特點
葉片吸收測量:提供葉片吸收測量及隨環(huán)境變化導致的葉片吸收變化�。根據Eichelman (2004) 葉片吸收在健康植物的變化范圍在0.7~0.9 之間。因此�,為獲得準確的ETR或“J”,Y(II)測量儀提供了一個可靠的測量方法���,
FV/FM測量單元:可額外選配FV/FM測量儀����,用于暗適應測量。
具有暗適應葉夾
陽光下屏幕可見
圖形顯示FV/FM曲線
2GB存儲空間
USB通訊
數(shù)據Excel查看
先進的PAR葉夾:采用底部葉夾打開裝置�,防止測量時誤操作打開葉夾。對傳感器進行余弦校正�����,確保葉片相對測量光的角度不變��。
FM’校正:對于具有高光照強度歷史的植物���,完全關閉光反應中心是一個問題��,Y(II)測量儀使用Loriaux &Genty 2013的方法進行FM’校正��,確保誤差*小���。
測量植物葉片的吸收:能夠直接測量植物葉片的吸收,而不是使用平均值0.84計算ETR�。
自動調制光設定:快速準確自動的調整合適的調制光強,避免人工操作的誤差���。
先進算法避免飽和脈沖NPQ:采用25ms內8點的平均值確定FM’�����,消除飽和脈沖NPQ的影響�。
更精確的葉溫測量:采用非接觸式紅外測量,測量精度可達±0.5℃���。
直接測量相對濕度:含有測量氣體交換使用的固態(tài)傳感器��,可測量相對濕度。
降低葉片遮擋的設計:傾斜的角度減少對葉片的遮擋�����,可以測量擬南芥等小葉�����。
系統(tǒng)組成
標配:
Y(II)光量子產額測量儀����、充電器、USB電纜����、便攜箱、2個吸收測量單元��、U盤(包含說明書)。
可選:
FV/FM測量儀及10個暗適應葉夾���、三腳架��。
技術指標
測量參數(shù):
Y(II)或ΔF/Fm‘�����、ETR���、PAR、T�、FMS或FM’、Fs�、α(葉片吸收&葉片透射)。
監(jiān)測模式:可使用電腦��,長時間監(jiān)測Y(II)�、ETR、葉片吸收�����、PAR�����、葉溫、相對濕度����、及NPQ。
相對濕度:5%~95%��,±2%���。
可使用AC或USB供電,可配三腳架��。
技術參數(shù):
光源
飽和脈沖:白色LED具有PAR時7000μmols
調制光:紅色LED 660nm�,具有690nm短波過濾。
光化光源:僅可使用外部光源
檢測方法:調制脈沖法
檢測器&過濾器:具有700~750nm帶通過濾的PIN光電二極管
取樣速率:1~10000點/秒自動切換����。
測量時間:3s或長期監(jiān)測
存儲空間:2GB
輸出:USB
尺寸:便攜箱尺寸為14”x 11”x 6”,儀器為9’’長
質量:Y(II) 測量儀0.45 kg
FV/FM測量儀0.36 kg.
總重1.95 kg.
產地:美國
文獻
Adams & Demming-Adams 2004 – Chlorophyll Fluorescence as a tool to Monitor Plant Response to the Environment. William W. Adams III and Barbara Demmig-Adams��, From Chapter 22�����, “Chlorophyll a Fluorescence a Signature of Photosynthesis”, edited by George Papaqeorgiou and Govindjee���, published by Springer 2004�, PO Box 17���, 3300 AA Dordrecht����, The Netherlands����, pages 598 -599
Adams WW III, Demmig-Adams B. (1994) Carotenoid composition and down regulation of Photosystem II in three conifer species during the winter. Physiol Plant 92: 451-458
Ball MC. (1994) The role of photoinhibition during seedling establishment at low temperatures. In: Baker NR. And Bowyer JR. (eds) Photoinhibition of Photosynthesis. From Molecular Mechanisms to the Field�����, pp365-3376 Bios Scientific Publishers�, Oxford
Ball MC., Butterworth JA.��, Roden JS.����, Christian R.��, Egerton JJG.��, (1995) Applications of chlorophyll fluorescence to forest ecology. Aust. J. Plant Physiology 22: 311-319
Baker N.R��, Rosenquist E. (2004) Applications of chlorophyll fluorescence can improve crop production strategies: an examination of future possibilities�, Bukhov & Carpentier 2004 – Effects of Water Stress on the Photosynthetic Efficiency of Plants��, Bukhov NG.����, & Robert Carpentier, From Chapter 24�����, “Chlorophyll a Fluorescence a Signature of Photosynthesis”�����, edited by George
Papaqeorgiou and Govindjee�, published by Springer 2004�����, PO Box 17, 3300 AA Dordrecht����, The Netherlands, page 627-628 Burke J. (2007) Evaluation of Source Leaf Responses to Water-Deficit Stresses in Cotton Using a Novel Stress Bioassay����, Plant Physiology, Jan. 2007�����, Vol 143��, pp108-121
Burke J.����, Franks C.D. Burow G., Xin Z. (2010) Selection system for the Stay-Green Drought Tolerance Trait in Sorghum Germplasm�, Agronomy Journal 102:1118-1122 May 2010
Cavender-Bares J. & Fakhri A. Bazzaz 2004 – “From Leaves to Ecosystem: Using Chlorophyll Fluorescence to Assess Photosynthesis and Plant Function in Ecological Studies”. Jeannine Cavender Bares, Fakhri A. Bazzaz���, From Chapter 29�����, “Chlorophyll a Fluorescence a Signature of Photosynthesis”��, edited by George Papaqeorgiou and Govindjee����, published by Springer 2004, PO Box 17���, 3300 AA Dordrecht����, The Netherlands��, page 746-747 ETR Drought stress and npq
Cazzaniga S��, Osto L.D.��, Kong S-G.����, Wada M.�����, Bassi R., (2013) “Interaction between avoidance of photon absorption����, excess energy dissipation and zeaxanthin synthesis against photo oxidative stress in Arabidopsis”, The Plant Journal����, Volume 76, Issue 4�, pages568–579, November 2013 DOI: 10.1111/tpj.12314
Cheng L.����, Fuchigami L., Breen P.����, (2001) “The relationship between photosystem II efficiency and quantum yield for CO2 assimilation is not affected by nitrogen content in apple leaves.”
Adams WW III, Demmig-Adams B.��, Vernhoeven AS.���, and Barker DH.�����, (1995) Photoinhibition during winter stress – Involvement of sustained xanthophyll cycle-dependent energy-dissipation. Aust J. Plant Physiol 22: 261-276 Journal of Experimental Botany�����, 55(403):1607-1621
Journal of Experimental Botany���, 52(362):1865-1872Crafts-Brandner S. J.�����, Law R.D. (2000) Effects of heat stress on the inhibition and recovery of ribulase-1�����, 5- biphsphate carboxylase/ oxygenase activation state. Planta (2000) 212: 67-74
da Silva J. A. & Arrabaca M.C. (2008).Physiologia Plantarum Volume 121 Issue 3�, Pages 409 – 420 2008
Eichelman H.��, Oja V.�, Rasulov B., Padu E.�, Bichele I., Pettai H.����, Niinemets O., Laisk A. (2004) Development of Leaf Photosynthetic Parameters in Betual pendula Roth Leaves: Correlation with Photosystem I Density�, Plant Biology 6 (2004):307-318
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