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The prospects for constraining productivity through time with the whole‐plant physiology of fossils
Author(s) -
Boyce C. Kevin,
Zwieniecki Maciej A.
Publication year - 2019
Publication title -
new phytologist
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.742
H-Index - 244
eISSN - 1469-8137
pISSN - 0028-646X
DOI - 10.1111/nph.15446
Subject(s) - transpiration , resistance (ecology) , biosphere , component (thermodynamics) , carboniferous , ecology , plant evolution , environmental science , footprint , hydraulics , biology , biochemical engineering , geology , paleontology , photosynthesis , botany , structural basin , physics , engineering , biochemistry , genome , gene , thermodynamics
Summary Anatomically preserved fossils allow estimation of hydraulic parameters, potentially providing constraints on interpreting whole‐plant physiology. However, different organ systems have typically been considered in isolation – a problem given common mismatches of high and low conductance components coupled in the hydraulic path of the same plant. A recent paper addressed the issue of how to handle resistance mismatches in fossil plant hydraulics, focusing on Carboniferous medullosan seed plants and arborescent lycopsids. Among other problems, however, a fundamental error was made: the transpiration stream consists of resistances in series (where resistances are additive and the component with the largest resistance can dominate the behavior of the system), but emphasis was instead placed on the lowest resistance, effectively treating the system as resistances in parallel (where the component with the smallest resistance will dominate the behavior). Instead of possessing high assimilation capacities to match high specific stem conductances, it is argued here that individual high conductance components in these Paleozoic plants are nonetheless associated with low whole‐plant productivity, just as can be commonly seen in living plants. Resolution of how to handle these issues may have broad implications for the Earth system including geobiological feedbacks to rock weathering, atmospheric composition, and climate.