A non‐targeted metabolomics approach to quantifying differences in root storage between fast‐and slow‐growing plants
RRL Atkinson, MM Burrell, CP Osborne… - New …, 2012 - Wiley Online Library
Life history theory posits that slower‐growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast‐growing species …
resources to storage, structural (eg stems) or defence traits than fast‐growing species …
A non‐targeted metabolomics approach to quantifying differences in root storage between fast‐and slow‐growing plants
RRL Atkinson, MM Burrell, CP Osborne, KE Rose… - New Phytologist, 2012 - infona.pl
Life history theory posits that slower‐growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast‐growing species …
resources to storage, structural (eg stems) or defence traits than fast‐growing species …
A non-targeted metabolomics approach to quantifying differences in root storage between fast-and slow-growing plants
RRL Atkinson, MM Burrell, CP Osborne… - The New …, 2012 - pubmed.ncbi.nlm.nih.gov
Life history theory posits that slower-growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast-growing species …
resources to storage, structural (eg stems) or defence traits than fast-growing species …
A non-targeted metabolomics approach to quantifying differences in root storage between fast-and slow-growing plants.
RRL Atkinson, MM Burrell, CP Osborne… - New …, 2012 - search.ebscohost.com
Life history theory posits that slower-growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast-growing species …
resources to storage, structural (eg stems) or defence traits than fast-growing species …
A non-targeted metabolomics approach to quantifying differences in root storage between fast-and slow-growing plants
M Rees - New Phytologist, 2012 - JSTOR
Life history theory posits that slower-growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast-growing species …
resources to storage, structural (eg stems) or defence traits than fast-growing species …
A non-targeted metabolomics approach to quantifying differences in root storage between fast-and slow-growing plants.
RRL Atkinson, MM Burrell, CP Osborne, KE Rose… - 2012 - cabidigitallibrary.org
Life history theory posits that slower-growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast-growing species …
resources to storage, structural (eg stems) or defence traits than fast-growing species …
A non-targeted metabolomics approach to quantifying differences in root storage between fast-and slow-growing plants.
RRL Atkinson, MM Burrell, CP Osborne… - The New …, 2012 - europepmc.org
Life history theory posits that slower-growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast-growing species …
resources to storage, structural (eg stems) or defence traits than fast-growing species …
A non-targeted metabolomics approach to quantifying differences in root storage between fast-and slow-growing plants
RRL Atkinson, MM Burrell, CP Osborne, KE Rose… - New Phytologist, 2012 - JSTOR
Life history theory posits that slower-growing species should invest proportionally more
resources to storage, structural (eg stems) or defence traits than fast-growing species …
resources to storage, structural (eg stems) or defence traits than fast-growing species …