3.2. The Fresh Matter Yield of Maize Grown for Silage
During the field experiment, an effect of differentiated mineral fertilizer combinations and a long-term effect of the organomineral fertilizer based on lignite waste on the production of silage maize were investigated. The fresh matter yield of maize grown for silage (
Table 4) recorded in the experiment significantly varied in subsequent years, depending on fertilizer treatment varieties in the first year of research and on the interaction of the experimental factors.
The highest average yields of fresh matter were obtained on the plots with NPKMgS + N1 in 2014 (72.4 Mg·ha
−1) and in 2016 (116.2 Mg·ha
−1) and with NPKMgS + N2 in 2015 (118.3 Mg·ha
−1). To those plots, 1 Mg·ha
−1 and 5 Mg·ha
−1 of organomineral fertilizer based on lignite waste were applied to the preceding crop, respectively. The above yields were 2.2, 1.7 and 1.7 times higher, respectively, than the yield of control plants. Of the varieties, the medium late type in 2014 and the medium early type in 2015 and 2016 yielded the best results. This may indicate their high yield potential, also reported by other authors [
40,
41], mainly related to their longer growing season. Some studies [
29,
42] indicated a high impact of soil evaporation and plant transpiration on the maize yield, and Li et al. [
43] recorded the highest yields when access to water and nitrogen was optimal. In the present experiment the highest yield was noted in 2015 (102.5 Mg·ha
−1). As indicated by the results presented in Diagram 1, the highest yield of fresh matter (101.3 Mg·ha
−1) was on the plot with NPKMgS + N1, on which 1 Mg·ha
−1 of the organomineral fertilizer and 60 kg·N·ha
−1 were applied to the preceding crop.
3.3. Nitrogen, Phosphorus, Potassium, Magnesium and Sulphur Content in Maize Biomass
The chemical composition of silage maize is the result of treatment, soil and weather conditions and growing methods and varieties [
44]. In the present experiment maize average total nitrogen content was significantly differentiated by fertilizer treatment, varieties and the years of research (
Table 5). Treatment combinations resulted in a significant reduction in maize nitrogen content compared to control. According to Skowrońska and Filipek [
14] an increase in the maize yield decreased nitrogen concentration in plants. In the present research, according to statistical analysis, the highest average nitrogen concentration (14 g∙kg
−1 DM) across treatment combinations and years was in maize from the plot with NPKMgS + N2 and in control plants. The medium late variety (PR 38A79) accumulated the largest amounts of nitrogen. A significant effect of varieties on the level of nitrogen and protein in maize biomass was confirmed by other research [
45]. In the present studies the largest amounts of nitrogen were recorded as a response to all treatment combinations in 2015. Of all nutrients, nitrogen increases crop yields to the greatest extent [
46], which was also confirmed by the present research.
The bioavailability of phosphorus largely depends on soil pH [
47], plant species and fertilizer treatment [
48]. The concentration of phosphates in the soil solution is very low, and low temperatures after plant emergence additionally inhibit the uptake of phosphorus [
49,
50]. In a statistically significant way, its largest amounts were found in silage maize harvested from control, and fertilizer treatment resulted in a significant reduction in phosphorus content (
Table 5). That was a result of the dilution of this chemical element in higher yields of maize, which was confirmed by other research [
14]. The lowest phosphorus content was recorded in plants treated with NPKMgS + N3, with a high yield of maize harvested from that plot (
Table 4). The content of this chemical element remained similar across varieties but it varied across years. The highest was for plants harvested in 2015 (2.21 g∙kg
−1DM), and the lowest in 2016 (1.95 g∙kg
−1DM).
The linear regression equation and the correlation coefficient (YFM= 209.9971 − 58.4861Pp r = −0.9223) indicate a significant negative relationship between phosphorus content in maize dry matter and its yield (
Figure 2a). At the same time, the linear regression equation and the correlation coefficient (Kp = 3.7344 + 2.8697Pp r = 0.9766) indicate a significant positive relationship between phosphorus and potassium content in maize DM (
Figure 2b).
The highest potassium content (11.16 g·kg
−1DM) was found in control plants, while the lowest (8.93 g·kg
−1DM) in plants treated with NPKMgS + N3 (
Table 5). Like in the case of phosphorus, that was caused by the dilution of this chemical element in a large yield. In their study, Bruns and Ebelhar [
51] pointed to the relationship between an increase in soil potassium content and the concentration of this element in maize. Obtaining high yields of fodder plants is associated with reducing the content of ingredients in the yield of biomass as a result of dilution of ingredients in high yields. The concept of “component dilution” has been introduced [
14,
43]. Across varieties, the highest potassium content was found in the early Silien one (9.89 g·kg
−1DM) in 2014. It was significantly higher (by 15.75%) than the content of the medium late PR 38A79 variety. Across subsequent years of research, no significant differences in potassium content were noted. According to other publications, potassium content of silage maize is at an optimal level [
30] for forage plants [
51].
Mineral treatment combinations significantly reduced magnesium content in maize (
Table 5). The lowest was in plants collected from plots treated with NPKMgS+ N1, with high yields harvested there. The magnesium content of maize dry matter was negatively significantly correlated with potassium content and the fresh matter yield (
Figure 3).
The highest phosphorus content was in 2014 (1.06 g·kg−1DM), with significantly lower amounts in 2015 and 2016 (0.75 g·kg−1DM).
Sulphur deficiency may be one of the main causes of a decrease in the quantity and quality of crops [
52,
53]. The applied mineral treatment and varieties did not have a significant impact on maize sulphur content, which ranged from 0.45 to 0.51 g∙kg
−1DM (
Table 5). In 2015 and 2016, there was a significant (by 13.3%) increase in sulphur content compared to the first year of research (2014). The main contributor to the lower content of sulphur in maize harvested in 2014 could have been unfavorable meteorological conditions during the vegetation period. This relationship was confirmed by other authors [
54,
55].
3.4. Uptake of Nitrogen, Phosphorus, Potassium, Magnesium and Sulphur
The amounts of nitrogen, phosphorus, potassium, magnesium and sulphur in maize biomass result from their concentration and the yield (
Table 6). According to statistical analysis, treatment combinations, varieties and years of research affected those amounts in a statistically significant way. The highest statistically significant nitrogen uptake in relation to control was recorded in plants treated with NPKMgS + N2 applied in subsequent years of research. On those plots, 5 Mg·ha
−1 of the organomineral fertilizer based on lignite waste, pre-sowing and 60 kg·N·ha
−1 as a top dressing were applied to the preceding crop. According to Skowrońska [
10], for typical grain maize varieties, the amount of nitrogen taken up by plants reached 450 kg·N·ha
−1, and the negative gross nitrogen balance was −180 kg·N·ha
−1 (i.e., it was nitrogen taken up from the soil).
The uptake of phosphorus by maize grown for silage was significantly affected by the experimental factors. Thus, the highest uptake of phosphorus (74.2 kg·ha−1) was recorded for plants treated with NPKMgS + N1. Across varieties it was the highest for the medium early P8000 type and for the medium late PR38A79 type. In 2015, plants took up the largest amounts of phosphorus. Similar amounts of phosphorus taken up by maize (65 kg·P·ha−1) were presented in other studies.
Statistical analysis showed a significant impact of treatment and years on the potassium uptake. Thus, the highest potassium uptake by maize (353.2 kg·ha
−1) was recorded on plots with NPKMgS + N2. Large differences in the potassium uptake in subsequent years of research were due to weather conditions (
Table 1 and
Table 2). Statistical analysis showed a significant impact of treatment, varieties and years of research on the magnesium uptake by maize grown for silage (
Table 6. Its highest value across years of research (30.9 kg·ha
−1) was recorded in plants treated with NPKMgS + N2. On those plots, 5 Mg·ha
−1 of the organomineral fertilizer based on lignite waste pre-sowing and a top dressing of 60 kg·N·ha
−1 were applied. Maize grown for silage in 2015 took up significantly larger amounts of magnesium (29.8 kg·ha
−1) than in 2014.
Statistical analysis showed a significant effect of treatment and years of research on the sulphur uptake by maize grown for silage. Thus, the highest average sulphur uptake (18.3 kg·ha−1) was recorded for plants treated with NPKMgS + N2. In 2015, maize took up significantly larger amounts of sulphur (20.1 kg·ha−1) than in 2014. A significantly lower uptake of sulphur in 2014 was mainly a result of low yields.
3.5. Agronomic and Physiological Efficiency of Nitrogen, Phosphorus, Potassium, Magnesium and Sulphur Treatment
The values of agronomic efficiency (AE) of nitrogen in mineral fertilizers (polyfoska
® M-MAKS NPKMgS and urea) are presented in
Table 7. The highest (133 kg·Kg
−1N) was recorded for maize treated with NPKMgS + N1. On this plot, 1 Mg·ha
−1 of the organomineral fertilizer based on lignite waste was applied pre-sowing to the preceding crop (maize). Some studies [
56] reported a decrease in AE to 76 kg·Kg
−1N after the application of YaraRega, a compound fertilizer, applied to the soil surface and by fertigation. Studies carried out in South Africa [
57] have confirmed a reduction in agronomic efficiency in response to increasing doses of mineral nitrogen. In the present experiment, the highest AE of nitrogen among varieties was recorded for early and medium early ones (Silien and P800). Across experimental years, its highest value was noted in 2015 (129 kg·Kg
−1N).
The AE of phosphorus in polyfoska
® M-MAKS NPKMgS is presented in
Table 7. Statistical analysis indicated a significant impact of phosphorus treatment, varieties and years of research on its AE. The high AE of phosphorus resulted not only from its dosage but also from nitrogen, potassium, magnesium and sulphur treatment, as well as from the treatment applied to the preceding crop. The highest AE of phosphorus (476 kg·Kg
−1P) was noted for maize treated with NPKMgS + N2. On this plot, 5 Mg·ha
−1 of the organo-mineral fertilizer based on lignite waste was applied pre-sowing to the preceding crop, which was maize. In a statistically significant way, the lowest AE of phosphorus was for the PR 38A79 variety. For maize grown in 2015, the highest AE of phosphorus (477 kg·Kg
−1P) was recorded.
Statistical analysis indicated a significant impact of treatment, varieties and years of research and the interaction of the factors on the AE of potassium. The highest average AE of this chemical element (133 kg·Kg−1K) was noted for maize treated with NPKMgS + N2. On that plot, 5 Mg·ha−1 of the organomineral fertilizer based on lignite waste (100-35-125 kg·NPK ha−1) pre-sowing, and 60 kg·N·ha−1 as a top dressing were applied to the preceding crop. In the second year of research (2015), the highest AE of potassium (133 kg·Kg−1 K) was observed.
The AE of magnesium in M-MAKS NPKMgS polyfoska
® is presented in
Table 7. Its highest value (1386 kg·Kg
−1Mg) was obtained for maize treated with NPKMgS + N2. It was similar for the Silien and P8000 varieties (1272 and 1271 kg·Kg
−1Mg, respectively). In the second year, the highest AE of magnesium (1391 kg·Kg
−1Mg) was recorded. Nitrogen treatment applied pre-sowing increased the AE of magnesium.
The treatment of maize with polifoska®, M-MAKS NPKMgS and urea (100-35-125-12-14 kg·ha−1 + 40 kg·N·ha−1 as a top dressing) made it possible to achieve the highest value of sulphur agronomic efficiency (1188 kg·Kg−1S). Across varieties, the highest statistically significant AE of sulphur was for Silien and P8000. In the second year of research (2015), the highest AE of sulphur treatment was recorded (1193 kg·Kg−1S).
The physiological efficiency (PE) of macronutrients in mineral fertilizers (polyfoska
®, M-MAKS NPKMgS and urea) taken up by maize grown for silage is presented in
Table 8. For nitrogen, its statistically significant highest value (153 kg·Kg
−1N) was recorded in maize treated with polyfoska
®, M-MAKS and NPKMgS (100-35-125-12-14 kg·ha
−1). Doses of mineral nitrogen (N1, N2 and N3) applied in a top dressing significantly reduced the PE of nitrogen. The decrease in PE was the result of a significantly higher nitrogen uptake with the yield of maize fertilized with NPKMgS + N1, NPKMgS + N2 and NPKMgS in relation to the control. For varieties, the highest statistically significant value was noted for the early Silien variety (105 kg·Kg
−1N) with 100 kg·Kg
−1N for the medium early P8000 variety. Studies on spring wheat [
52] indicated that PE of nitrogen and sulphur was higher than their AE obtained under the influence of nitrogen treatment. For silage maize grown in 2016, the highest PE was observed (107 kg·Kg
−1N).
The main cause of the reduction in the PE of phosphorus was a higher uptake of that mineral by maize on plots where a nitrogen top dressing was used in doses of 20 and 40 kg·N·ha
−1. This relationship confirms the stimulating effect of balanced nitrogen treatment on the phosphorus uptake during plant vegetation [
58]. The high PE of phosphorus resulted not only from its dose but also from nitrogen, potassium, magnesium and sulphur treatment, as well as from treatment applied to the preceding crop. The highest PE phosphorus (1144 kg·Kg
−1P) was obtained for maize treated with NPKMgS. On that plot, 100-35-125 kg·NPK·ha
−1 (mineral fertilizers, manure at a dose of 30 Mg·ha
−1) and a top dressing of 60 kg·N·ha
−1 were applied to the preceding crop. For subsequent years of research, significantly increasing the values of PE of phosphorus (929 < 961 < 1009 kg·Kg
−1P) were noted.
The highest PE of potassium (155 kg·Kg−1K) was obtained for maize treated with NPKMgS + N3. On that plot, 100-35-125 kg·NPK ha−1 (mineral fertilizers, manure at a dose of 30 Mg·ha−1) and a top dressing of 60 kg·N·ha−1 were applied. In the third year (2016) the highest potassium PE was recorded (158 kg·Kg−1K).
The highest PE of magnesium (1545 kg·Kg−1Mg) was obtained for maize treated with NPKMgS + N1. On this plot, 1 Mg·ha−1 of organomineral fertilizer based on lignite waste (100-35-125 kg·NPK·ha−1) was applied pre-sowing to the preceding crop, i.e., maize, with 60 kg·N·ha−1 as a top dressing. Nitrogen treatment applied as a top dressing increased the agronomic efficiency of magnesium. Its highest value was for the early Silien variety (1546 kg·Kg−1Mg). In the first year of research (2014), the highest PE of magnesium treatment was recorded (1485 kg·Kg−1Mg).
Nitrogen treatment (N1, N2 and N3) applied as a top dressing significantly reduced the PE of sulphur in the first and second years of research and insignificantly in the third year of research (
Table 8). The treatment of maize with NPKMgS (100-35-125-12-14 kg·ha
−1) resulted in the highest value of the PE of sulphur (3137 kg·Kg
−1S). Among the varieties, it was the highest for P8000, a medium early one (2837 kg·Kg
−1S). In the third year, the highest PE of sulphur was noted (2707 kg·Kg
−1S).
The AE of nitrogen was significantly negatively correlated with the PE of phosphorus (
Table 9). Significant relationships occurred between the AE of phosphorus and the AE of potassium, magnesium and sulphur and between the PE of nitrogen and sulphur. The AE of potassium was correlated with the AE of magnesium and sulphur and with the PE of nitrogen and sulphur. Significant relationships were also noted between the AE of magnesium and the PE of nitrogen and sulphur. The PE of nitrogen was significantly positively correlated with the PE of sulphur (
Table 8). From the agronomic point of view, positive correlations between the agronomic efficiency of N, P, K, Mg and S and the physiological efficiency of N, P, K, Mg and S are the most favorable. Under natural field conditions, this is impossible to achieve because of the biochemical processes in plants.