- Koçillari, Loren;
- Olson, Mark E;
- Suweis, Samir;
- Rocha, Rodrigo P;
- Lovison, Alberto;
- Cardin, Franco;
- Dawson, Todd E;
- Echeverría, Alberto;
- Fajardo, Alex;
- Lechthaler, Silvia;
- Martínez-Pérez, Cecilia;
- Marcati, Carmen Regina;
- Chung, Kuo-Fang;
- Rosell, Julieta A;
- Segovia-Rivas, Alí;
- Williams, Cameron B;
- Petrone-Mendoza, Emilio;
- Rinaldo, Andrea;
- Anfodillo, Tommaso;
- Banavar, Jayanth R;
- Maritan, Amos
Shaping global water and carbon cycles, plants lift water from roots to leaves through xylem conduits. The importance of xylem water conduction makes it crucial to understand how natural selection deploys conduit diameters within and across plants. Wider conduits transport more water but are likely more vulnerable to conduction-blocking gas embolisms and cost more for a plant to build, a tension necessarily shaping xylem conduit diameters along plant stems. We build on this expectation to present the Widened Pipe Model (WPM) of plant hydraulic evolution, testing it against a global dataset. The WPM predicts that xylem conduits should be narrowest at the stem tips, widening quickly before plateauing toward the stem base. This universal profile emerges from Pareto modeling of a trade-off between just two competing vectors of natural selection: one favoring rapid widening of conduits tip to base, minimizing hydraulic resistance, and another favoring slow widening of conduits, minimizing carbon cost and embolism risk. Our data spanning terrestrial plant orders, life forms, habitats, and sizes conform closely to WPM predictions. The WPM highlights carbon economy as a powerful vector of natural selection shaping plant function. It further implies that factors that cause resistance in plant conductive systems, such as conduit pit membrane resistance, should scale in exact harmony with tip-to-base conduit widening. Furthermore, the WPM implies that alterations in the environments of individual plants should lead to changes in plant height, for example, shedding terminal branches and resprouting at lower height under drier climates, thus achieving narrower and potentially more embolism-resistant conduits.