1.Enhanced thermal energy dissipation depending on xanthophyll cycle and D1protein turnover in iron-deficient maize leaves exposed to high light,Photosynthetica,2001,39(2)
2.Responses of the antioxidant systems and xanthophyll cycle inPhaseolus vulgaristo the combined stress of high irradiance and high temperature.Photosynthetica,2000,38(2)
3.Characteristics of photosynthetic apparatus in Mn-starved leaves,Photosynthetica,2002,40(2)
4.Changes in donor and accept side in photosystem 2 complex in attached soybean and maize leaves caused by iron deficiency,Photosynthetica,2003,41(2): 267-271
5.Effects of streptomycin treatment on the chlorophyll fluorescence parameters and the level of the xanthophyll de-epoxidation in maize leaves,Journal of plant physiology and molecular biology,2003 , 29:(3)
6.Characterization of PSII Photochemistry and Thermostability in Salt-treated Rumex Leaves,Journal of plant physiology,2004,161(3)257-264
7.Changes in activity of energy dissipating mechanisms in wheat flag leaves during senescence,Plant biology,2004,6(2): 171-177
8.Dissipation of excess energy in Mehler-peroxidase reaction inRumexleaves during salt shock,Photosynthetica,2004,42(1) : 117-122
9.Inhibition of photosynthesis by shift in the balance of excitation energy distribution between photosystems in dithiothreitol treated soybean leaves,Photosynthetica,2004,42(3)409-415
10.Mitigation of photoinhibition by enhanced Mehler-Peroxidase reaction in salt-stressedRumexleaves.,Acta botanica sinica,2004,46(7): 811-818
11.Enhanced photoprotection at the early stages of leaf expansion in field-grown soybean plants.Plant science,2005,168: 911-919
12.Leaf orientation, photorespiration and xanthophyll cycle protect young soybean leaves against high irradiance in field,Environmental and experimental botany,
13.Development of photosystems 2 and 1 during leaf growth in grapevine seedlings probed by chlorophyllafluorescence transient and 820 nm transmissionin vivo,Photosynthetica,2006,44(3): 454-463
14.Alleviation of photoinhibition by calcium supplement in salt-treatedRumexleaves,Physiologia Plantrum,2007 129:386-396
15.The higher resistance to chilling stress in adaxial side of Rumex K-1 leaves is accompanied with higher photochemical and non-photochemical quenching,Photosynthetica,2007,45 (4): 496-502
16.Effects of Iron Deficiency on Photosynthesis and Photosystem II Function in Soybean Leaf.,Journal of plant physiology and molecular biology,2007,33(1) : 53-60
17.Partitioning of excitation energy in two wheat cultivars with different grain protein contents grown under three nitrogen applications in the field.,Physiologia Plantarum,2007,129:822-829
18.CO2assimilation and chlorophyll fluorescence in greenversusredBerberis thunbergiileaves measured with different quality irradiation.,Photosynthetica,2009,47 (1): 11-18
19.Heterogeneous behavior of PSII in soybean (Glycinemax) leaves with identical PSII photochemistry efficiency underd ifferent high temperature treatments,Journal of Plant Physiology,2009 166,1607—1615
20.Different enhancement of senescence induced by metabolic products ofAlternaria alternatain tobacco leaves of different ages,Physiologia Plantarum,2010 138: 164–175.
21.Characterization of the programmed cell death induced by metabolic products of Alternaria alternata in tobacco BY-2 cells,Physiologia Plantarum,2011,141: 117–129.
22.Systemic regulation of leaf anatomical structtue, photosynthetic performance and high-light tolerance in sorghum seedlings,Plant Physiology,2011,155:. 1416–1424,
23.Characterization of PSⅠrecovery after chilling photoinhibition in cucumber (Cucumis sativusL.),Planta,2011 (in press)
山東農業大學教授高輝遠