Table 3.
Gaussian models for the two gypsovags occurring in gypsum and calcareous soils at both sites. The P-value of the corresponding analysis of deviance and the mean value of each variable in each class are indicated
| Variable | Salvia lavandulifolia |
Rosmarinus officinalis |
||||
|---|---|---|---|---|---|---|
| Gy/Caa | Siteb | Interaction termc | Gy/Caa | Siteb | Interaction termc | |
| Ash | 0·037 | ns | ns | 0·007 | ns | ns |
| Ca = 6·36; Gy = 7·23 | Ca = 5·43; Gy = 6·04 | |||||
| Ca | 0·001 | ns | ns | 0·019 | ns | 0·020 |
| Ca = 1·50; Gy = 1·94 | Ca = 1·20; Gy = 1·43 | Z-Ca = 1·17; Z-Gy = 1·64; M-Ca = 1·22; M-Gy = 1·22 | ||||
| C | 0·001 | 0·001 | ns | 0·032 | ns | 0·011 |
| Ca = 56·37; Gy = 54·94 | Z = 54·7; M = 56·6 | Ca = 56·35; Gy = 55·96 | Z-Ca = 56·21; Z-Gy = 56·30; M-Ca = 56·49; M-Gy = 55·62 | |||
| C/N | 0·0001 | ns | ns | ns | ns | ns |
| Ca = 37·53; Gy = 31·31 | ||||||
| Mg | 0·003 | 0·003 | 0·003 | 0·001 | ns | ns |
| Ca = 3·03; Gy = 3·28 | Z = 2·34; M = 3·97 | Z-Ca = 3·04; Z-Gy = 1·64; M-Ca = 3·01; M-Gy = 4·92 | Ca = 1·69; Gy = 2·77 | |||
| N | 0·0001 | ns | ns | ns | ns | ns |
| Ca = 15·08; Gy = 17·64 | ||||||
| Na | ns | 0·0001 | ns | ns | ns | ns |
| Z = 0·52; M = 0·35 | ||||||
| P | 0·006 | 0·003 | 0·003 | 0·004 | ns | ns |
| Ca = 0·85; Gy = 1·03 | Z = 1·03; M = 0·85 | Z-Ca = 0·85; Z-Gy = 1·21; M-Ca = 0·85; M-Gy = 0·84 | Ca = 0·85; Gy = 0·68 | |||
| K | ns | 0·005 | ns | 0·017 | ns | ns |
| Z = 6·80; M = 4·22 | Ca = 10·04; Gy = 8·05 | |||||
| S | 0·001 | ns | ns | ns | ns | ns |
| Ca = 0·05; Gy = 0·11 | ||||||
aCa = calcareous soil, Gy = gypsum soil.
bM = Madrid (central Spain, Middle Tajo Basin); Z = Zaragoza (north-east Spain, Middle Ebro Basin).
cZ-Ca = calcareous soils in Zaragoza; Z-Gy = gypsum soils in Zaragoza; Ca-M = calcareous soils in Madrid; Gy-M = gypsum soils in Madrid.
ns indicates that predictors do not explain a significant fraction of deviance. See text for details on statistics. n = 5.