/iS ABSORPTION OF FOOD-.SALT.S J!Y WATEH-I'I.ANTS. 



complicated adaptations are iiecessaiy for the extraction of food-salts from the 

 earth. In particular, the portions which are exposed to the air above ground exhibit 

 a number of special structures connected with this extraction. These structures 

 (cuticle, stomata, &c.) are superfluous in the case of aquatic plants, for there is with 

 them no necessity for raising and conducting food-salts into the parts where they 

 can be used up. Moreover the absorption of nutritious matter is much simpler, 

 inasmuch as it is not necessary for the absorbent parts to search for a perpetual 

 source of the requisite substances. The roots of land-plants have often to range 

 over a wide area in order to find sufiicient nourishment in the earth, and frequently 

 they have then to liberate it, i.e. bring it into a state of solution. This is not the 

 case with water-plants. They are completely surrounded by a medium which 

 is itself to a large extent a solution of food-salts, and no sooner are suljstances 

 withdrawn by the absorbent cells from the layers of water inunediately bounding 

 them than those substances are again supplied from the more remote environ- 

 ment. Constant compensating currents occur in water, and there is, therefore, 

 scarcely an aquatic plant towards which there is not a perpetual flow of the food- 

 salts it requires in a form suitable for absorption. In connection with this kind of 

 food-absorption there is also the fact that the parts by which hydrophytes attach 

 themselves to a support are relatively small in area. Fucoids, as large as hazel 

 trees in height and girth, are fixed to submerged rocks by groujis of cells perhaps 

 only 1 cm. in diameter. 



The quantity of food-salts absorbed by hydrophytes is very considerable com- 

 pared with the amounts absorbed by other plants. As has lieen mentioned before, 

 soda and iodine play a very important part in the thousands of difl'erent \-arieties 

 which live in the sea. If Florideee are transferred from the sea into pure distilled 

 water, common salt and other saline compounds difi"use out of the interior of tlie 

 cells through the cell-membranes into the fresh water around. The red colouring 

 matter of these Floridece also passes through the cell-walls into the water, proving 

 that the molecular structure of the membrane is adapted to the agency of salt 

 water in the osmotic processes of food-absorption. 



Plants living in fresh, or in brackish water, likewi.se absorb relati\-el3' large 

 quantities of food-salts; and this accounts for the fact that water which is very 

 poorly provided with nutriment of the kind contains only very few vegetable 

 species. 



One would expect that exceedingly abundant vegetation would be evolved in 

 running water, provided the latter contained food-salts in solution, however small 

 they might l:>e in (juantity. For, in such a situation, it is not necessary to wait for 

 the salts withdrawn by the plants from their immediate environment to be restored 

 by the slow processes of mixture and e()uilibration ; the water which has been drained 

 of nutriment is replaced the next moment by other water bearing fresh food-salts. 

 Experience shows, however, that flowing water is not so favourable to the develop- 

 ment of hydrophytes as is the still water of pools, ponds, and lakes. This may 

 partly depend on the fact that running water is always poorer in food-salts, and 



