Osmotically driven pipe flows and their relation to sugar transport in plants

TL;DR

This study combines experiments and theory to analyze osmotically driven sugar transport in plant-like pipes, confirming the pressure-flow hypothesis and providing exact solutions for the flow equations.

Contribution

The paper presents a novel experimental setup and theoretical analysis that accurately models transient osmotically driven flows, extending previous work and confirming key aspects of plant sugar transport mechanisms.

Findings

Good agreement between experiment and theory on sugar front decay

Exact solutions for flow equations in low resistance conditions

Numerical solutions for more general conditions

Abstract

In plants, osmotically driven flows are believed to be responsible for translocation of sugar in the pipe-like phloem cell network, spanning the entire length of the plant. In this paper, we present an experimental and theoretical study of transient osmotically driven flows through pipes with semipermeable walls. We extend the experimental work of Eschrich, Evert and Young \cite[]{Eschrich:1972} by providing a more accurate version of their experiment allowing for better comparison with theory. In the experiments we measure the dynamics and structure of a "sugar front", i.e. the transport and decay of a sudden loading of sugar in a pipe which is closed in both ends. We include measurements of pressure inside the membrane tube allowing us to compare the experiments directly with theory and, in particular, to confirm quantitatively the exponential decay of the front in a closed tube.In a novel setup we are able to measure the entire concentration profile as the sugar front moves. In contrast to previous studies we find very good agreement between experiment and theory. In the limit of low axial resistance (valid in our experiments as well as in many cases in plants) we show that the equations can be solved exactly by the method of characteristics yielding, in general, an implicit solution. Further we show that under more general conditions the equations of motion can be rewritten as a single integro-differential equation, which can be readily solved numerically. The applicability of our results to plants is discussed and it is shown that it is probable that the pressure-flow hypothesis can account for short distance transport of sugar in plants.