about
Evolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO2Increasing CO2 threatens human nutritionGenomic basis for stimulated respiration by plants growing under elevated carbon dioxideGlobal food insecurity. treatment of major food crops with elevated carbon dioxide or ozone under large-scale fully open-air conditions suggests recent models may have overestimated future yieldsClimate modifies response of non-native and native species richness to nutrient enrichment.Future carbon dioxide concentration decreases canopy evapotranspiration and soil water depletion by field-grown maize.Impacts of elevated CO2 concentration on the productivity and surface energy budget of the soybean and maize agroecosystem in the Midwest USA.Transcriptional reprogramming and stimulation of leaf respiration by elevated CO2 concentration is diminished, but not eliminated, under limiting nitrogen supply.Developmental stage specificity of transcriptional, biochemical and CO2 efflux responses of leaf dark respiration to growth of Arabidopsis thaliana at elevated [CO2].A physiological and biophysical model of coppice willow (Salix spp.) production yields for the contiguous USA in current and future climate scenarios.Photosynthesis, productivity, and yield of maize are not affected by open-air elevation of CO2 concentration in the absence of drought.Food for thought: lower-than-expected crop yield stimulation with rising CO2 concentrations.Impairment of C(4) photosynthesis by drought is exacerbated by limiting nitrogen and ameliorated by elevated [CO(2)] in maize.A multi-biome gap in understanding of crop and ecosystem responses to elevated CO2.Predicting invasion in grassland ecosystems: is exotic dominance the real embarrassment of richness?Physiological and ecological significance of sunflecks for dipterocarp seedlings.High C3 photosynthetic capacity and high intrinsic water use efficiency underlies the high productivity of the bioenergy grass Arundo donaxTargets for crop biotechnology in a future high-CO2 and high-O3 world.Elevated CO2 effects on plant carbon, nitrogen, and water relations: six important lessons from FACE.Will elevated carbon dioxide concentration amplify the benefits of nitrogen fixation in legumes?The origins of C4 grasslands: integrating evolutionary and ecosystem science.Heat waves imposed during early pod development in soybean (Glycine max) cause significant yield loss despite a rapid recovery from oxidative stress.Intensifying drought eliminates the expected benefits of elevated carbon dioxide for soybean.Growth of soybean at future tropospheric ozone concentrations decreases canopy evapotranspiration and soil water depletion.Altered physiological function, not structure, drives increased radiation-use efficiency of soybean grown at elevated CO2.Elevated ozone reduces photosynthetic carbon gain by accelerating leaf senescence of inbred and hybrid maize in a genotype-specific manner.Inconsistency of mesophyll conductance estimate causes the inconsistency for the estimates of maximum rate of Rubisco carboxylation among the linear, rectangular and non-rectangular hyperbola biochemical models of leaf photosynthesis--a case study oArabidopsis transcript and metabolite profiles: ecotype-specific responses to open-air elevated [CO2].Functional genomics and ecology--a tale of two scales.Urgent need for a common metric to make precipitation manipulation experiments comparableRising atmospheric carbon dioxide concentration and the future of C4 crops for food and fuelFACE-ing the facts: inconsistencies and interdependence among field, chamber and modeling studies of elevated [CO2] impacts on crop yield and food supplyDoes greater leaf-level photosynthesis explain the larger solar energy conversion efficiency of Miscanthus relative to switchgrass?Long-term growth of soybean at elevated [CO2] does not cause acclimation of stomatal conductance under fully open-air conditionsPhotosynthesis and the environmentElevated CO2 and O3 modify N turnover rates, but not N2O emissions in a soybean agroecosystemGreater antioxidant and respiratory metabolism in field-grown soybean exposed to elevated O3 under both ambient and elevated CO2Increased protein carbonylation in leaves of Arabidopsis and soybean in response to elevated [CO2]Does elevated atmospheric [CO2] alter diurnal C uptake and the balance of C and N metabolites in growing and fully expanded soybean leaves?Patterns of dynamic irradiance affect the photosynthetic capacity and growth of dipterocarp tree seedlings
P50
Q27003923-07668231-C954-458F-8BDC-9C5F7E9189EFQ28601792-0C99225C-6EAB-4C4E-B751-2CEC8E5728E4Q28755508-C09ED3D5-4F46-4F81-872C-297E9AB6F9ADQ28767587-CCE7ED74-F2DA-40F1-9163-703FDAE97F46Q30315218-549E5336-CE2B-4C10-A264-6692F3C323EDQ30602202-32652B10-D976-485B-9FF4-6C3FED90FE41Q30635040-C04BED6C-6C9B-44A4-80C9-3E3CEDF711C7Q30674606-64DC5A5C-6FBC-4B82-910B-F271468C9661Q30779324-05874991-D598-473D-BF3F-BA672615E604Q30949496-17894810-20D2-49AC-BB43-D171267FDE6CQ31029544-95780172-102B-44B8-826C-3FCFC89D63CBQ31047577-CC1AB4FC-09A9-4024-A22F-2CB1B162417CQ33844509-992E680A-D156-41D0-84BA-195061379664Q34143468-5347DB05-E6EA-4AB4-BEAB-8A7353B66C82Q34987821-58EA2B0E-A050-487E-B896-6BC3919E50EAQ35982472-642E0BC6-F820-4A2A-9F61-E1A7CA838B46Q36565016-9D72202A-8E0C-4447-8830-2A3F2CE458D9Q37149686-7CBE3D25-5562-4B57-A78C-CE01A0C5471DQ37463566-5F858DE0-E5F5-451A-8A78-38D956052416Q37597767-53A22A45-FD6B-4017-B776-006659BD1B6CQ37739711-CAC8B171-B9FC-4C22-8130-032DC21BEE1DQ39021257-DA9C4382-43E1-4DF8-899D-4AD7D32D87C2Q39031715-264E369D-5F92-42B2-894D-A41804C5FF13Q39762350-1F1975AF-36BE-4D9D-8186-732200547EC0Q44919003-D929DA68-A762-40AB-AC25-0D82D0EFF6DDQ47769907-C5DB5F49-D6D4-48F2-A4E5-0EEBD66012F5Q50642330-91FC4476-15B9-4471-853A-CC82C1D38268Q50779502-E4DD9E1E-4C9B-4272-876C-6628C6711CCAQ51184701-BBF4AF32-70F3-4BB2-B683-58F0183CB18BQ56959177-0B578F68-DEFC-4C06-A9B1-42961154A4C3Q57126934-EB79A81E-629A-4FB4-81FB-72F5077DD7A9Q57132875-78EECA98-1D8B-48FD-B247-8A425BD2EF89Q57202302-F6F163A2-405A-4140-9392-D056AD590AB8Q57202327-4E03832A-F442-4C87-B1C3-FA9D06FE2CF8Q57202352-55D3C94F-447C-4F67-AE1C-D967F6B9B9B3Q57202359-AFFDB6A0-F1FA-4FB0-8E57-2ADFB31CD70BQ57202361-18447CC4-43EA-4FF4-93E2-2F8773FA5387Q57202368-4F202DE9-77C0-4B99-8896-EC796E7CBB19Q57202371-B15BFACB-DD01-4492-9D57-78E4316966F5Q57202379-FEC0BED6-C265-44FE-828F-11BF55021943
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Andrew Leakey
@ast
Andrew Leakey
@en
Andrew Leakey
@es
Andrew Leakey
@nl
type
label
Andrew Leakey
@ast
Andrew Leakey
@en
Andrew Leakey
@es
Andrew Leakey
@nl
altLabel
Leakey AD
@en
prefLabel
Andrew Leakey
@ast
Andrew Leakey
@en
Andrew Leakey
@es
Andrew Leakey
@nl
P1053
Q-9889-2016
P106
P21
P31
P3829
P496
0000-0001-6251-024X