Search details
1.
Contrasting leaf-scale photosynthetic low-light response and its temperature dependency are key to differences in crop-scale radiation use efficiency.
New Phytol
; 241(6): 2435-2447, 2024 Mar.
Article
in English
| MEDLINE | ID: mdl-38214462
2.
APSIM-based modeling approach to understand sorghum production environments in Mali.
Agron Sustain Dev
; 44(3): 25, 2024.
Article
in English
| MEDLINE | ID: mdl-38660316
3.
A cross-scale analysis to understand and quantify the effects of photosynthetic enhancement on crop growth and yield across environments.
Plant Cell Environ
; 46(1): 23-44, 2023 01.
Article
in English
| MEDLINE | ID: mdl-36200623
4.
Differences in temperature responses among phenological processes in diverse Ethiopian sorghum germplasm can affect their specific adaptation to environmental conditions.
Ann Bot
; 131(4): 601-611, 2023 04 28.
Article
in English
| MEDLINE | ID: mdl-36661105
5.
Modeling adaptation of sorghum in Ethiopia with APSIM-opportunities with G×E×M.
Agron Sustain Dev
; 43(1): 15, 2023.
Article
in English
| MEDLINE | ID: mdl-36714044
6.
Manipulating assimilate availability provides insight into the genes controlling grain size in sorghum.
Plant J
; 108(1): 231-243, 2021 10.
Article
in English
| MEDLINE | ID: mdl-34309934
7.
Radiation use efficiency increased over a century of maize (Zea mays L.) breeding in the US corn belt.
J Exp Bot
; 73(16): 5503-5513, 2022 09 12.
Article
in English
| MEDLINE | ID: mdl-35640591
8.
Genetic modification of PIN genes induces causal mechanisms of stay-green drought adaptation phenotype.
J Exp Bot
; 73(19): 6711-6726, 2022 11 02.
Article
in English
| MEDLINE | ID: mdl-35961690
9.
Genetic basis of sorghum leaf width and its potential as a surrogate for transpiration efficiency.
Theor Appl Genet
; 135(9): 3057-3071, 2022 Sep.
Article
in English
| MEDLINE | ID: mdl-35933636
10.
Large-scale GWAS in sorghum reveals common genetic control of grain size among cereals.
Plant Biotechnol J
; 18(4): 1093-1105, 2020 04.
Article
in English
| MEDLINE | ID: mdl-31659829
11.
Soil water capture trends over 50 years of single-cross maize (Zea mays L.) breeding in the US corn-belt.
J Exp Bot
; 66(22): 7339-46, 2015 Dec.
Article
in English
| MEDLINE | ID: mdl-26428065
12.
Stay-green alleles individually enhance grain yield in sorghum under drought by modifying canopy development and water uptake patterns.
New Phytol
; 203(3): 817-30, 2014 Aug.
Article
in English
| MEDLINE | ID: mdl-24898064
13.
A physiological framework to explain genetic and environmental regulation of tillering in sorghum.
New Phytol
; 203(1): 155-67, 2014 Jul.
Article
in English
| MEDLINE | ID: mdl-24665928
14.
Drought adaptation of stay-green sorghum is associated with canopy development, leaf anatomy, root growth, and water uptake.
J Exp Bot
; 65(21): 6251-63, 2014 Nov.
Article
in English
| MEDLINE | ID: mdl-25381433
15.
Integrating stay-green and PIN-FORMED genes: PIN-FORMED genes as potential targets for designing climate-resilient cereal ideotypes.
AoB Plants
; 15(4): plad040, 2023 Jul.
Article
in English
| MEDLINE | ID: mdl-37448862
16.
Adapting APSIM to model the physiology and genetics of complex adaptive traits in field crops.
J Exp Bot
; 61(8): 2185-202, 2010 May.
Article
in English
| MEDLINE | ID: mdl-20400531
17.
Regulation of tillering in sorghum: genotypic effects.
Ann Bot
; 106(1): 69-78, 2010 Jul.
Article
in English
| MEDLINE | ID: mdl-20430784
18.
Regulation of tillering in sorghum: environmental effects.
Ann Bot
; 106(1): 57-67, 2010 Jul.
Article
in English
| MEDLINE | ID: mdl-20421230
19.
Pre-anthesis ovary development determines genotypic differences in potential kernel weight in sorghum.
J Exp Bot
; 60(4): 1399-408, 2009.
Article
in English
| MEDLINE | ID: mdl-19228817
20.
Genotypic variation in whole-plant transpiration efficiency in sorghum only partly aligns with variation in stomatal conductance.
Funct Plant Biol
; 46(12): 1072-1089, 2019 11.
Article
in English
| MEDLINE | ID: mdl-31615621