3.1. Characteristics of the Soil
Physical and chemical soil properties of the examined vineyards for the soil layers 0–30 cm, 30–60 cm and profile horizons (<200 cm) are given in
Table 3. Soil pH value was highly acid to alkaline in topsoil and subsoil, according to classification for vineyard soils [
44]. The topsoil layer (0–30 cm) has an acidic pH value for the most part (72% of the region’s surface area). In the soil profile horizons, the pH value of most soils increased with depth. The most suitable soil pH in terms of vine cultivation is neutral [
45]. According to White [
46] the optimum pH range for vine growth is 5.5–8. Slightly acidic and neutral vineyard soils generally have better nutrient balance for plant growth. Soil pH value is most often a natural property of the soil and comes from the pH reaction of the parent substrate in which the soil was formed.
Samples of topsoil and subsoil belong to the noncalcareous to highly calcareous soil category [
44]. The content of CaCO
3 in completely carbonate-free soils is completely uniform in terms of profile depth or a small part of carbonates appears at the lower layer. In other soils, the carbonate content generally increases in depth of the profile. The content of free CaCO
3 largely depends on the parent substrate, i.e., the type of soil.
Bulk density (BD) of the soils varied between 1.24 and 1.70 g cm
−3 (
Figure 5). The BD of most of the examined soil profiles increases with depth, as a consequence of the long-term pressure of the upper soil layers on the lower layers. Most of the examined horizons have BD of more compact arable soils, according to the classification of Kačinski [
47,
48] which is unfavorable from the aspect of water, air and temperature regime of these soils. According to Leake [
45] the BD values in the vineyard soils should be less than 1.4 g cm
−3. In the study of Doğan and Gülser [
49], BD of vineyards soils varied between 1.07 and 1.75 g cm
−3.
The soil texture examined for the Tri Morave wine growing region is characterized by increased clay content (
Figure 6). Clay content of vineyard fields varies between 13.96% and 50.48%. Most of the samples are concentrated in the classes of light clay and heavy clay. This texture is unfavorable for most cultivated plant species. According to Gücüyen, loamy soils include high organic matter, low-water-holding capacity and well-drained characteristics that are generally suitable for good quality grape production [
50].
3.2. Soil Organic Carbon Stock
The soil organic carbon stock in the organic layer (0–30 cm) of the observed vineyard soils ranged between 17.72 and 87.04 t ha
−1, with mean value 46.19 t ha
−1 (
Figure 7). In subsoil (30–60 cm), SOC stock ranged between 14.54 and 91.16 t ha
−1, with mean value 40.26 t ha
−1. These results are lower than the average value for SOC stock of agricultural land in Serbia. The previous analysis of organic carbon content in agricultural land of Serbia showed that in the 0–30 cm layer, values of SOC stock ranged from 3.72 to 328.23 t ha
−1 with mean value 68.99 t ha
−1 [
51].
Similar results were obtained by other authors. According to the assessment of the mean SOC stock of the different cropland uses in Italy, SOC stock in the top 30 cm of mineral soil for the vineyards was 41.9 ± 15.9 t ha
−1 [
31]. In his study, SOC stock for the whole cropland category was 52.1 ± 17.4 t C ha
−1, which is in the range of those reported for other European countries. Smith et al. [
52] suggest a mean value of 53 t C ha
−1 as an average value for all European cropland soils. SOC stocks in peninsular Spain showed a high heterogeneity, with the lowest values in arid regions. The average value in topsoil (0–30 cm) was 44 ± 26 and 57 ± 35 t C ha
−1 in subsoil (30–50 cm) [
11]. SOC stock in vineyards of peninsular Spain was reported by Murillo [
33] at 42.5 ± 28.9 t C ha
−1. For France, the SOC stock in the agricultural soils was estimated at 15 to 40 t ha
−1 in mid-France and 40–50 t ha
−1 in the north and southwest [
53]. Results for SOC stocks in the vineyards of France were reported by Martin et al. [
32] at 39.4 ± 26.5 t ha
−1.
Besides the specific soil properties in vineyards, the reduction of SOC is possibly a consequence of the intensification of agricultural practices [
54,
55]. In the observed area, the management is based on the reduced use of organic fertilizers, which are applied mainly only when establishing vineyards, as well as on conventional land cultivation in intensive production. Intensive viticulture could lead to the soil degradation, with loss of soil fertility, acceleration of soil erosion and SOM mineralization, and CO
2 emission increase [
26,
27,
56]. Soil tillage affects soil respiration, temperature, water content, pH, oxidation–reduction potential and the soil ecology [
57,
58]. In particular, it enhances the microbial biomass turnover and, in turn, the short-term CO
2 evolution by improving soil aeration, increasing the contact between soil and crop residues and by exposing organic matter to microbial attack [
59].
Experiments conducted in the United States [
60] show a reduction of more than 30% in the SOM content in soils that have been cultivated for many years. In the undisturbed state, SOM contents are the result of a balance between mineralization losses and organic matter inputs. Disturbances change this equilibrium very quickly, leading to a higher level of decomposition of SOM, especially the labile forms (sugars, amino acids) that play a major role in stabilizing the physical structures of the soil [
51]. The remaining forms of SOM are less effective in stabilizing the soil structure. Such a system is in a state of degradation, which can be prevented by compensating for the loss of SOM by increasing organic matter input.
The results of our study confirmed that different soil types exhibited typical ranges topsoil carbon storage. Lepotsols (53.53 t ha
−1) yielded the highest SOC in topsoil. A similar value was observed in Cambisol (51.69 t ha
−1). The comparison between SOC stocks of Fluvisols (30.11 t ha
−1) and Vertisols (36.69 t ha
−1) revealed no significant differences. A previous assessment of organic carbon stocks in the agricultural soils of the Republic of Serbia [
51] observed the following mean values for the reference soil groups: Leptosols (151.33 t ha
−1), Cambisols (89.81 t ha
−1), Vertisols (71.09 t ha
−1) and Fluvisols (70.80 t ha
−1). In this study, the mean values of SOC for observed soil type were higher than our results, but of the same order. In soils of the Vojvodina region, the largest SOC stocks were observed in Vertisols (74 t ha
−1) and the lowest Fluvisol (46 t ha
−1) [
61]. Murillo [
33] reported mean values of SOC stocks for peninsular Spain: 71.4 ± 57.8 t C ha
−1 for Cambisols; 75.8 ± 58.9 t C ha
−1 for Fluvisol; 98.8 ± 56.4 t C ha
−1 for Leptosol and 68.9 ± 37.8 t C ha
−1 for Vertisol. It may be concluded that SOC stocks in all of the observed soil types for vineyards were lower than the average for agricultural land in Serbia.
The highest SOC in subsoil were for Cambisols (43.43 t C ha
−1). Fluvisols (42.23 t C ha
−1) and Lepotsols (42.83 t C ha
−1) revealed similar SOC stocks in the soil horizon. The subsoil of Vertisols yielded the lowest amount of SOC (33.79 t ha
−1). The differences in SOC stocks of all soil groups in subsoils were not significant. Fluvisol contain much higher SOC stocks in subsoils than in topsoil. Schöning et al. [
62] highlighted the importance of subsoil carbon balance on a plot scale. Grüneberg [
63] showed that this is also true for the regional scale.
Differences of SOC stocks can be partly explained by soil texture, which is a result of different parent materials on which the soils developed. Cambisols are characterized by adequate profile depth, good texture and water–air properties. Fluvisols are formed due to the constant deposition of fresh suspensions and do not have a developed humus horizon. The humus content is low, about 2%, and often below 1%, and it is not distributed uniformly in depth. These characteristics can explain our results. The high concentration of SOC in Leptosols is a consequence of the humus layer in humus–carbonate and humus–silicate soils. Lower regions under natural vegetation contain 5–10% of humus, while higher ones can contain up to 20% [
64]. Vertisols have low production value due to the high clay content and specificity of descending material from upper to lower layers due to the formation of cracks during the dry part of the year.
3.3. Organic Carbon Concentrations in Observed Soil Types
The mean SOC concentrations in the topsoil and subsoil of the observed soil types of the Tri Morave vineyard region are given in
Table 4. The highest mean concentration of SOC in topsoil was found in Leptosols and Cambisols, and the lowest in Fluvisols. As for the SOC stocks, the organic carbon concentration in the agricultural soils was also lower in our results than in the previous assessment for the reference soil groups [
51], in which the content ranged from 0.08% to 21.72%, with a mean value of 2.07% for the top 30 cm. In this study, Vertisols (1.76%) and Fluvisols (1.74%) were characterized as soils of low SOC concentration, while Leptosols (3.96%) and Cambisols (2.16%) belonged to the class with medium SOC contents.
In the examination of SOC concentration of European soils, for all soil categories (arable, forest, grass and others) the following values were obtained: Cambisols 2.4%, Fluvisols 1.6% and Vertisols 1.5% [
16]. In the experiment of Novara et al. [
25], which was carried out on a flat vineyard area in the west of Sicily, Italy, on calcic–gleyic vertisol, SOC content was 0.95 ± 0.07%, similar to our results.
The overall mean SOC concentration of the samples in topsoil (0–30 cm), 1.02 ± 0.32%, was higher than the SOC concentrations in subsoil (30–60 cm), 0.85 ± 0.32%.
In the deeper layers, the SOC concentration was fairly uniform. The highest SOC content was also recorded in Cambisols, while the lowest was found in Vertisols.
Numerous studies reported a dominant effect of soil type on SOC stocks both in topsoil and subsoil [
22,
24,
65]. Soil type is strongly associated with SOC storage at multiple scales and under different climatic conditions [
66]. Soil type is not an independent control factor but integrates climate, parent material and topography related properties, which affect the potential of soils to store C, particularly through moisture regime and texture [
66].
3.4. Distribution of Organic Carbon in the Soil Profile
The SOC content in soil profile horizons ranged from 0.09% to 1.79% (
Figure 8). The highest SOC content was observed in the topsoil layer, as expected. This is a consequence of the accumulation of organic matter originating from plant residues, as well as higher activity of microorganisms, which participate in the decomposition of fresh organic matter. Significant factors in these processes are soil temperature and humidity.
The average value of SOC decreased rapidly with increasing depth, which is in agreement with the results of other research [
67,
68,
69]. Regression analysis revealed a statistically significant change in SOC content with soil depth (
Figure 9). The average SOC content decreased by 0.62% in the 0–100 cm layer with increasing depth. The declining trend of SOC content decreases in the deeper layer, 100–200 cm, with the average SOC value falling by 0.17%.
In the study by Yu et al. [
67], the mean value of SOC in the 0–100 cm soil layer decreased rapidly with increasing soil depth, ranging from 3.37 ± 1.43 g kg
−1 in the topsoil layer (0–20 cm) to 1.66 ± 0.98 g kg
−1 in the 80–100 cm layer.
Correlation analysis showed a more significant correlation between SOC and soil depth in the upper layer (r = 0.99) compared to the deeper soil layer (r = 0.91).
3.5. Effect of Fertilization Strategies on SOC Concentration
Fertilizer management is important for increasing crop productivity and soil quality, while limiting the environmental contamination. In intensive vineyard production of Serbia, fertilization is mostly based on inorganic fertilizers. Some winegrowers avoid using organic amendments, because they fear negative effects on the quality of the grapes (extended period of grape ripening, low sugar and high acid content). However, several studies confirmed that the combined application of mineral and organic fertilizers give the best results in terms of grape yield (4.7 kg vine
−1) and the physical and chemical characteristics of bunches and berries (14.72% sugar) [
70,
71]. Only individual application of organic fertilizers led to the lower yield (3.6 kg vine
−1) [
70,
72] and lower content of sugar in berries (14.29%) [
70,
73], as well as to the increase in berry acidity (4.32 g L
−1) [
70]. The overall polyphenol concentration is higher in organic grapes, resulting in a higher protection from oxidation [
72]. The fertilization practice, based on exclusively inorganic fertilizers, could jeopardize soil quality and content of SOC.
Table 5 shows the SOC concentration in vineyards with different fertilization strategies. Combining ameliorative fertilization and application of farmyard manure initially with continuous application of NPK inorganic fertilizers has led to the highest SOC. In relation to the plots where no fertilizer was applied, the SOC content was increased by 0.37%, while in relation to the application of foliar fertilizer only, it was increased by 0.27%. These differences were statistically significant, while there were no statistically significant differences compared to the other variants. Similar results were obtained by other authors. Yang et al. [
74] indicated that the SOC content could be maintained at a relatively stable level under sufficient chemical fertilizer application without return of manure and crop residue conditions, and SOC content was increased with the combination of chemical fertilizer and manure application.
Application of AF + NPK led to the SOC concentration that was statistically significantly higher than in the variant without fertilization, by 0.34%. Similar results were obtained by application of FM + GM, where SOC was increased by 0.29%, compared to the NF. There were no statistically significant differences compared to other variants.
The lowest SOC content was recorded on plots that had not been fertilized at all, as well as those that had been fertilized with only foliar fertilizer. Similar results were observed by Liu et al. [
75]. Hao et al. [
76] stated that the effects of manure application, tillage, crop rotation, fertilizer rate, and soil and water conservation farming have positive influence on the SOC pool. They found that SOC at the 0–15 cm soil layer was 6.2%, 7.7% and 9.3% higher with manure, chemical fertilizers and manure plus fertilizers, respectively, than with no fertilizer application.
Between the vineyard establishment and 2015, the mean SOC concentration decreased in both depths of unfertilized vineyards (
Table 6). In fertilized vineyards, SOC decreased only in topsoil. In this, the shallow layer, tillage significantly affects soil respiration, temperature, water content and other soil properties. The contact between soil and crop residues increases and organic matter is more exposed to microbial attack. This leads to a decrease in the content of SOC.
The reduction of SOC was rapid in the earlier stage of cultivation. Similar results were obtained by other authors. Liu et al. [
75] showed a significant decline of total SOC that occurred in the first five years of cultivation where the average SOC loss per year was about 2.3 t ha
−1 for the 0–17 cm horizon. The average annual SOC loss between 5- and 14-year cultivation was 0.95 t ha
−1 and between 14- and 50-year cultivation it was 0.29 t ha
−1. Compared with the uncultivated soil, Liu et al. also indicated that SOC loss (the sum of three horizons) was 17%, 28% and 55% in the 5-, 14- and 50-year cultivation periods, respectively. Biddoccu et al. [
77] found that average soil loss in a mountain vineyard, Aosta valley (NW Italy), was 15.7 t ha
−1 y
−1. The loss of the SOC could be reduced by taking into account some of the different mitigation options, such as manuring and fertilizing, conservation tillage, management of crop residues and cover cropping [
54,
78,
79].
The reduction of SOC in topsoil of fertilized vineyards, in the first five years, was higher compared to the unfertilized plots. The reason is initially higher concentration of SOC in fertilized vineyards. Similar results were obtained Garcia-Diaz et al. [
80]. They stated that the decrease in SOC content after tillage was greater in the treatment that presented higher SOC content.
The SOC content increased in subsoil of vineyards that had been fertilized initially with sufficient amounts of inorganic fertilizer during the cultivation and farmyard manure. The deep tillage (60–80 cm) has led to deep placement of organic amendments and equalization of SOC content between the mixed layers. On average, even 35 years after deep tillage event, the subsoil still contained 13.49 t ha
−1 more SOC than before this measure. It can be concluded that deep tillage can preserve SOC in the deeper soil layer and prevent carbon loss from the surface layer. Subsoil holds a large potential to store additional soil organic carbon (SOC) because of the large number of unsaturated mineral surfaces and environmental conditions that impede SOC decomposition, e.g., more constant moisture and temperature regime or oxygen limitation [
81]. Similar results were obtained by other authors. According to Liu et al. [
75], deep tillage (subsoiling) increased SOC and N relative to conventional tillage. Cervantes et al. [
81] stated that after the deep plowing event, the layer of the deeply plowed fields accumulated on average 0.4 ± 0.1 Mg SOC ha
−1 yr
−1.
Similar results were stated by Liu et al. [
75] with the rotary plowing and conventional tillage, where the SOC contents at 16–30 cm were higher than in the depth between 0 and 15 cm, indicating that more root residues were incorporated into this layer. This result was consistent with mixing of organic matter by plowing, but opposite to results with no-tillage practice or conservation tillage [
82,
83,
84]. According to Campbell et al. [
85], SOC gains under no-till were about 250 kg ha
−1 yr
−1 greater than for tilled systems, regardless of cropping frequency. Within the surface 7.5 cm, the no-till system possessed significantly more SOC (by 7.28 t ha
−1) relative to the conventional tillage [
86].
3.6. Correlation of SOC with Soil Properties
The dependence of SOC content and other physical and chemical properties of soil was examined by correlation analysis and shown in
Figure 10. A statistically significant correlation was found only in the lower undisturbed soil layers. In the upper layer, there was a significant decrease in the SOC content and disturbance of the ratio of SOC and other soil properties due to the strong anthropogenic impact. A significant positive correlation of SOC with clay content was found. The positive relationship between clay content and SOC confirmed the global relation between them [
87,
88,
89]. The fine fraction of soil serves as a measure for SOC storage [
66]. Smaller particle size has better water retention, fertilizer retention capacity and higher nutrient content [
67]. The stability of SOC is determined by the chemical nature of SOM, absorption in the mineral part of the soil and its participation in the formation of structural microaggregates [
90]. With an increased content of clay particles, the content of SOC tends to increase. The reason for this is the bond between the surface of the clay particles and OM, which slows down the decomposition process. Soils with higher clay content increase the potential for aggregate formation [
51]. Macroaggregates physically protect organic molecules from further mineralization caused by microorganisms [
91]. In similar climatic conditions, the SOM content in fine-textured (clay) soils is two to four times higher than in coarse-textured (sandy) soils [
92]. The low clay content of the soil tends to be poor in soil aggregation stability and water holding, due to low cohesion forces between elementary particles that affect the porosity [
6].
Sand content was significantly negatively correlated with SOC content, which agrees with the results of Li et al. [
93]. They concluded that increasing desertification would reduce the accumulation of SOC. Sandy soils usually contain less SOM than soils with a finer texture, such as loam or clay. Lower moisture content and higher aeration in sandy soils results in faster SOM oxidation compared to heavier soils. In general, poorly drained soils have a higher moisture content and poorer aeration. This results in a higher organic matter (OM) content in these soils than in their better-drained equivalents [
51].
SOC content decreased with increasing pH and CaCO
3 content. Negative correlation between pH value and SOC was found in the study of Islam et al. [
94], especially in the presence of high sand percentage and high concentrations of Na
+. Similar results were obtained by Ayaz et al. [
95]. In their examination, the soil organic carbon stock negatively correlated with soil pH (r = −0.38,
p ≤ 0.05) and calcium carbonate (r = −0.45,
p ≤ 0.01). Increase of the calcium carbonate concentration and soil pH significantly affect soil microbial activity and reduces the SOC quantity by the enhancement in the rate of mineralization.