33 of nitrogen and potash remain unchanged for all plots. Graph 2 shows that the rate of in- crease of phosphorus uptake is similar for all experimental sites, whereas the total uptake at any particular level of phosphorus application varied markedly. At the Sámsstadir experiment station, for instance, grass on peat soil (Sámsst. (70 N)) took up far greater phosphorus than on silt loam soil (Sámsst. (120 N)), in spite of the fact that the latter plots received about 70 per cent more nitrogen. The peat soil gave larger yields and also grass with somewhat higher phosphorus content (see Tables 11 and 12). Tables 5, 6 and 7 and graph 3 show that the „apparent phosphorus balance" of the soil dropped rapidly with increased phosphorus fertilization, in particular for low rates of appli- cation. This means that in relation to the amount applied, the quantity taken up by the grass was by far greatest when the phosphorus applications were low. Thus in three of the present trials, at the annual application of 13,1 kg P per hectare, the total quantity taken up by the grass was 15 to 45 per cent greater than that applied to the soil (the „apparent phosphorus balance“ is 115 to 145 per cent). When the phosphorus application was doubled, to 26,2 kg P/ha, the „apparent phosphorus balance" dropped to about 70 to 80 per cent. This efficient utilization of low rates of phosphorus applications was somewhat unexpected, yet a pleasant surprise. The relatively low requirements and efficient utilization of phosphorus was unex- pected for soils which when plowed and harrowed in a virgin condition are usually so totally deficient in phosphorus that no plant will thrive without a phosphorus application. Two questions relative to phosphorus are of primary interest to the farmer: (1) What is the minimal quantity of phosphorus required to avoid yield reduction due to phosphorus defi- ciency? (2) Is the supply of available phosphorus in the soil enough to ensure grass or fodder with sufficient phosphorus content from a nutritional standpoint? These questions are treated in another paper (Jóhannesson, 1959), and graph 4 is from that paper. This graph indicates that a small annual applicatiion, or about 30 kg P2O5 per hectare, was sufficient for the re- spective fields, and other evidence presented in the mentioned paper indicated that approxi- mately 40 to 45 kg P2O5 sufficed along with 120 kg N or less pr. hectare. Analytical data listed in the paper also indicated that grass from plots which receive annually 13,1 kg P (30 kg P2O5) pr. hectare is sufficiently rich in phosphorus from a nutritional point of view. It is obvious that more soil phosphorus accumulates as the annual applications increase. Table 13 lists some analytical data on the amount of extracted soil phosphorus, and shows an in- creased quantity of „available“ phosphorus with increased rates of phosphorus fertilization. These data, however, are not absolute measures of the quantity of soil phosphorus that may become available to the grass, and therefore they cannot be used as a basis for any quantative calculations. Experimental results of the agronomic experiment stations (Arni Jónsson, 1947— 1958) and some scattered fertilizer trials (Jóhannesson, 1956), however, have shown that very appreciable residual effects from phosphorus fertilizer (triple superphosphate) are observed in permanent grass fields. Yet, available evidence strongly indicates that for permanent grass fields it is more profitable to top-dress with relatively small quantities of phosphorus fertiliizer annually than with larger quantities at greater intervals. Comments relating to Tables 8 and 9. These Tables are included because they throw some further light on the orders of magni- tude of phosphorus content in grass and of the „apparent phosphorus balance“ of the soil or phosphorus utilization. Table 13 lists some characteristics of the respective soils. It is difficult to make comparisons between the four experiment stations as regards yields and chemical composition, since climatic or growing conditions usually are significantly different in any one as well as in different seasons. The present information is insufficient to state in quantitave terms the climatic influence or to eliminate its varying effects. Thus climatic

Qupperneq 1
Qupperneq 2
Qupperneq 3
Qupperneq 4
Qupperneq 5
Qupperneq 6
Qupperneq 7
Qupperneq 8
Qupperneq 9
Qupperneq 10
Qupperneq 11
Qupperneq 12
Qupperneq 13
Qupperneq 14
Qupperneq 15
Qupperneq 16
Qupperneq 17
Qupperneq 18
Qupperneq 19
Qupperneq 20
Qupperneq 21
Qupperneq 22
Qupperneq 23
Qupperneq 24
Qupperneq 25
Qupperneq 26
Qupperneq 27
Qupperneq 28
Qupperneq 29
Qupperneq 30
Qupperneq 31
Qupperneq 32
Qupperneq 33
Qupperneq 34
Qupperneq 35
Qupperneq 36
Qupperneq 37
Qupperneq 38
Qupperneq 39
Qupperneq 40
Qupperneq 41
Qupperneq 42
Qupperneq 43
Qupperneq 44
Qupperneq 45
Qupperneq 46
Qupperneq 47
Qupperneq 48
Qupperneq 49
Qupperneq 50
Qupperneq 51
Qupperneq 52
Qupperneq 53
Qupperneq 54
Qupperneq 55
Qupperneq 56