| Passive origins of stomatal control in vascular plants TJ Brodribb, SAM McAdam Science 331 (6017), 582-585, 2011 | 498 | 2011 |
| Conifer species adapt to low-rainfall climates by following one of two divergent pathways TJ Brodribb, SAM McAdam, GJ Jordan, SCV Martins Proceedings of the National Academy of Sciences 111 (40), 14489-14493, 2014 | 362 | 2014 |
| The evolution of mechanisms driving the stomatal response to vapor pressure deficit SAM McAdam, TJ Brodribb Plant Physiology 167 (3), 833-843, 2015 | 289 | 2015 |
| Visual quantification of embolism reveals leaf vulnerability to hydraulic failure TJ Brodribb, RP Skelton, SAM McAdam, D Bienaimé, CJ Lucani, ... New Phytologist 209 (4), 1403-1409, 2016 | 287 | 2016 |
| Evolution of stomatal responsiveness to CO2 and optimization of water‐use efficiency among land plants TJ Brodribb, SAM McAdam, GJ Jordan, TS Feild New Phytologist 183 (3), 839-847, 2009 | 274 | 2009 |
| Shoot‐derived abscisic acid promotes root growth SAM McAdam, TJ Brodribb, JJ Ross Plant, cell & environment 39 (3), 652-659, 2016 | 241 | 2016 |
| Linking turgor with ABA biosynthesis: implications for stomatal responses to vapor pressure deficit across land plants SAM McAdam, TJ Brodribb Plant Physiology 171 (3), 2008-2016, 2016 | 219 | 2016 |
| Abscisic acid mediates a divergence in the drought response of two conifers TJ Brodribb, SAM McAdam Plant physiology 162 (3), 1370-1377, 2013 | 210 | 2013 |
| Stomatal responses to vapour pressure deficit are regulated by high speed gene expression in angiosperms SAM McAdam, FC Sussmilch, TJ Brodribb Plant, cell & environment 39 (3), 485-491, 2016 | 190 | 2016 |
| Evolution of the stomatal regulation of plant water content TJ Brodribb, SAM McAdam Plant physiology 174 (2), 639-649, 2017 | 188 | 2017 |
| Stomatal innovation and the rise of seed plants SAM McAdam, TJ Brodribb Ecology Letters 15 (1), 1-8, 2012 | 182 | 2012 |
| Separating active and passive influences on stomatal control of transpiration SAM McAdam, TJ Brodribb Plant Physiology 164 (4), 1578-1586, 2014 | 168 | 2014 |
| Fern and lycophyte guard cells do not respond to endogenous abscisic acid SAM McAdam, TJ Brodribb The Plant Cell 24 (4), 1510-1521, 2012 | 164 | 2012 |
| Gas exchange recovery following natural drought is rapid unless limited by loss of leaf hydraulic conductance: evidence from an evergreen woodland RP Skelton, TJ Brodribb, SAM McAdam, PJ Mitchell New Phytologist 215 (4), 1399-1412, 2017 | 146 | 2017 |
| Xylem and stomata, coordinated through time and space TJ Brodribb, SAM McAdam, MR Carins Murphy Plant, Cell & Environment 40 (6), 872-880, 2017 | 145 | 2017 |
| Mesophyll cells are the main site of abscisic acid biosynthesis in water-stressed leaves SAM McAdam, TJ Brodribb Plant Physiology 177 (3), 911-917, 2018 | 120 | 2018 |
| Up-regulation of NCED3 and ABA biosynthesis occur within minutes of a decrease in leaf turgor but AHK1 is not required FC Sussmilch, TJ Brodribb, SAM McAdam Journal of experimental botany 68 (11), 2913-2918, 2017 | 119 | 2017 |
| Leaf water potential measurements using the pressure chamber: synthetic testing of assumptions towards best practices for precision and accuracy CM Rodriguez-Dominguez, A Forner, S Martorell, B Choat, R Lopez, ... Plant, cell & environment, 2022 | 112 | 2022 |
| Leaves, not roots or floral tissue, are the main site of rapid, external pressure-induced ABA biosynthesis in angiosperms FP Zhang, F Sussmilch, DS Nichols, AA Cardoso, TJ Brodribb, ... Journal of experimental botany 69 (5), 1261-1267, 2018 | 112 | 2018 |
| Linking xylem network failure with leaf tissue death T Brodribb, CR Brodersen, M Carriqui, V Tonet, C Rodriguez Dominguez, ... New Phytologist 232 (1), 68-79, 2021 | 104 | 2021 |
tim brodribbUniversity of TasmaniaПотвърден имейл адрес: utas.edu.au
