Possible causes for embolism repair in xylem

Wood sections of eight species of angiosperm and gymnosperm were made and observed under microscope. When a dehydrated section was rewet, the air inside its conduits contracted under the force of surface tension for several seconds to form elongated or spherical bubbles. The elongated bubbles in smaller conduits shortened till vanished. In addition, we also discorved that bubbles in larger conduits extended at first, then collapsed and disappeared; the bubbles outside conduits appeared gradualy or popped up in the field of view one after another; for some samples, they originated mainly from the cross sections of the wood rays. The smaller ones also collapsed and the larger ones grew up gradually. We suspected that air might transfer from the bubbles with short radii to those with large radii, both inside and outside conduits. The calculation of the amount of gas in all bubbles in a field of view supported our hypothesis. There are two possible mechanisms to explain the phenomena. First, based on the capillay equation, air can move from a smaller bubble to a larger one. Another reason is that the dissolving air from smaller bubbles can enter into the adjacent bubbles with larger curvature radii. Gas movement should obey the same rules in living plants. Therefore, we suggest that after cavitation events, instead of air moving from xylem into ambient atmosphere, two mechanisms could induce air to transfer from smaller conduits into larger conduits or the regions with lower pressures, leading the embolized conduits in the smaller conduits to repair. Furthermore, the differnce of values of contact angles in conduits might promote the refilling of embolism at lower xylem pressure.