12 



BULLETIN" 100, U. S. DEPARTMENT OF AGRICULTURE. 



of water requirement on the basis of the phint as a wliole may afford 

 a more reliable index of successful growth in relation to drought than 

 taking into account only the aerial portion of the plant. Most of 

 the work on water requirement has been done in connection with 

 cultivated plants, the root systems of which are small as compared 

 with certain native species which may be classed as conservative users 

 of water. The more dissimilar the root systems of species compared 

 the less reliable the water requirement data will be unless the roots 

 as well as the tops are taken into account. 



The appreciably greater amount of water used by the plants grown 

 in the fertile soil over those grown in the infertile soil is accounted 

 for by the fact that the plants grew much more luxuriantly in the 

 richer soil ; hence the transpiration was much greater, and at the end 

 of the season much more dry matter had been produced on the fertile 

 than on the infertile soil. Exact data as to the vegetative develop- 

 ment and the total water requirements of the species grown in the two 

 soils are r-hown in Table 3. 



Table 3. — Summary of vegetative grotcth and vmter requirements of peas, hrome 



grass, and wheat. 



Data determined. 



Peas. 



Infertile 

 soil. 



Fertile 

 soil. 



Native brome grass. 



Infertile 

 soil. 



Fertile 

 soil. 



Wh&aX. 



Infertile 

 soil. 



FertUe 

 soil. 



Number of leaves 



Leaf length (mm.) 



Dry weight (grams) 



Water used per plant (grams) 



Water reqmrement per unit dry matter 

 (grams) 



42 



791 



0.79 



667 



841 



112 



2,634 



6.55 



3,051 



467 



35 



2,902 



0.41 



553 



1,367 



5,218 

 0.85 

 944 



1,110 



22 

 4,474 

 5.52 

 2,516 



472 



47 



10, oso 



12.09 



3,820 



343 



The graphical representation (fig. 4) of Table 3 shows remarkable 

 contrast in the vegetative growth and total water requirement of the 

 plants developed in the two soils. The number of leaves produced 

 by field peas, for example, in the infertile soil as compared with that 

 of the fertile soil is as 1 to 2.7; the leaf length, 1 to 3.3^ the total dry 

 weight produced, 1 to 8.3; and the water used per plant, 1 to 4.6. 

 Similar contrasts are shown in the case of the other two species. 

 The ratio in the water requirement per unit of dry matter, on the 

 other hand, is reversed in the case of each species, as has previously 

 been showm. 



The above data show clearly the importance of exercising the 

 greatest care in the selection and subsequent treatment of soils for 

 the study of comparative growth of standard plants as a means of 

 integrating climate. While soils obtained within a limited space 

 and at the same depth, and having uniform appearance in color, 

 texture, and other essentials, may be similar in many respects, they 



