/2 NOTRIUXT SALTS. 



must iit all events come into contact with aa great a mass of nutrient soil as 

 possible, and this is eti'ected by means of a widely-ramifying system of I'oots; 

 and, in addition, they must assist in making available desii-able matter in the 

 soil by the elimination from themselves of certain substances. 



In order to explain the remarkable power that plants possess of exercising 

 a choice in the absorjjtiun of certain food-stuffs from am<;ngst the whole number 

 presented to them, we must in the first place assume a special structure to exist 

 in the cells which are in immediate contact with the nutrient medium. To 

 reach the interior of a cell, the salts must pass through the cell-membrane and 

 the so-called ectoplasm. We may look ujDon these walls, that are to be pene- 

 trated, as filters, or, to abide by our previous simile, as sieves, which allow only 

 certain kinds of molecules to pass and arrest others. Moreover, just as the 

 structure of a sieve, especially the size and shape of its pores, has its effect in the 

 separation of the particles of the matter sifted, so also may the structure of a 

 cell-wall have a discriminating influence in the absorption of food-salts. It may 

 be supposed that the cell-wall in one species of plant acts as a sieve capable of 

 letting through molecules of potash but none of alumina, whilst the cell-wall in 

 a second species allows molecules of alumina to pass as well, but is impervious to 

 those of chloride of sodium. This hypothesis would also explain why the absorp- 

 tion of food-stufts by plants generally takes place through cell-walls, and why 

 absorption into the organs concerned by means of ojaen tubes, which would lie 

 at all events a much simpler method, is not preferred. It is, however, necessary 

 to investigate first the nature of the force which causes molecules of the various 

 salts to move from the soil to the cell-membranes, which we suppose to be like 

 sieves, and through them into the interior of a plant. A force acting in this 

 sense from without is inconceivable, and we must therefore look for the motive 

 stimulus in the plant itself. 



As has been already stated in connection with the absorption of carbonic acid, 

 it is believed that the cause of this movement is the disturbance of the molecular 

 equilibrium in the growing vegetable organiam. If at one spot in the protoplasm 

 of a cell a particular substance is altered, and, let us say, converted into an 

 insoluble compound, the previous grouping of molecules appears to be altered, or 

 in other words, the molecular equilibrium is disturbed. To restore equilibrium, 

 there must be a re-introduction of molecules of the material that has been removed; 

 and the attraction of them from the quarter where they occur in a fluid, that is 

 to say in a mobile condition, is the more energetic. Supposing, for instance, 

 gypsum (i.e. sulphate of lime) is being decomposed within a cell, and the lime 

 combines with the oxalic acid (set free in the same cell) to form insoluble oxalate 

 of lime, whilst the sulphur combines with ether elements to form insoluble 

 albuminoids, this use of the gypsum occasions a violent attraction of that sub- 

 stance from the environment, or, to put it another way, it causes a movement of 

 gypsum towards the place of consumption. If this latter place is a cell in innne- 

 diate contact with the nutrient substratum, the absorption of the substance 



