CIRCULATION AND FORMATION OF WOOD IN PLANTS. 583 



Anotherside of the general question may now be considered. We 

 have seen how, by intermittent pressures on capillary vessels and 

 ducts and inosculating canals, there must be produced a draught of 

 sap towards the point of compression to replace the sap squeezed out. 

 But we have still to inquire what will be the effect on the distribu 

 tion of sap throughout the plant as a whole. It was concluded that 

 out of the compressed vessels the greater part of the liquid would 

 escape longitudinally the longitudinal resistance to movement 

 being least. In every case the probabilities are infinity to one against 

 the resistances being equal upwards and downwards. Always, then, 

 more sap will be expelled in one direction than in the other. But in 

 whichever direction least sap is expelled, from that same direction 

 most sap will return when the vessels are relieved from pressure the 

 force which is powerful in arresting the back current in that direction 

 being the same force which is powerful in producing a forward cur 

 rent. Ordinarily, the more abundant supply of liquid being from be 

 low, there will result an upward current. At each bend a portion of 

 the contents will be squeezed out through the sides of the vessels a 

 portion will be squeezed downwards, reversing the current ascending 

 from the roots, but soon stopped by its resistance ; while a larger por 

 tion will be squeezed upwards towards the extremities of the vessels, 

 where consumption and loss are most rapid. At each recoil the ves 

 sels will be replenished, chiefly by the repressed upward current ; and 

 at the next bend more of it will be thrust onwards than backwards. 

 Hence we have everywhere in action a kind of rude force-pump, 

 worked by the wind ; and we see how sap may thus be raised to a 

 height far beyond that to which it could be raised by capillary ac 

 tion, aided by osmose and evaporation. 



Thus far, however, the argument proceeds on the assumption that 

 there is liquid enough to replenish every time the vessels subject 

 to this process. But suppose the supply fails suppose the roots 

 have exhausted the surrounding stock of moisture. Evidently the 

 vessels thus repeatedly having their contents squeezed out into the 

 surrounding tissue, cannot go on refilling themselves from other 

 vessels without tending to empty the vascular system. On the one 

 hand, evaporation from the leaves causing a draught on the capillary 

 tubes that end in them, continually generates a capillary tension up 

 wards ; while, on the other hand, the vessels beTow, expanding after 

 their sap has been squeezed out, produce a tension both upwards 

 and downwards towards the point of loss. Were the limiting mem 

 branes of the vessels impermeable, the movement of sap would, under 

 these conditions, soon be arrested. But these membranes are perme 

 able ; and the surrounding tissues readily permit the passage of air. 

 This state of tension, then, will cause an entrance of air into the tubes; 

 the columns of liquid they contain will be interrupted by bubbles. 

 It seems, indeed, not improbable that this entrance of air may take 



