Winter Wheat Resilience Under Different Pre-Crop Conditions in Albeluvisol Soils
Department of Food and Agrotechnology, Faculty of Informatics, Engineering and Technologies, Kauno Kolegija Higher Education Institution, Pramonės pr. 20, LT-50468 Kaunas, Lithuania
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Author to whom correspondence should be addressed.
Sustainability 2025, 17(1), 216; https://doi.org/10.3390/su17010216
Submission received: 7 November 2024
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Revised: 20 December 2024
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Accepted: 26 December 2024
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Published: 31 December 2024
Abstract
:One of the most popular varieties in crop farming is wheat. In Lithuania, more than 460 winter wheat varieties are registered in the State Register of Plant Varieties. One of the most popular and time-tested varieties is ‘Skagen’, which is highly valued for its winter hardiness. The aim of the research is to determine the influence of different pre-crops on the winter survival of the wheat variety ‘Skagen’ in Albeluvisol soils. For the experiment, fields of the winter wheat (Triticum aestivum) variety ‘Skagen’ from farms in the Lazdijai district were chosen. The experiment was conducted from 2017 to 2018. Plant count, chlorophyll index, and weed count were evaluated. After evaluating the differences in plant density after winter, it was found that a significantly greater reduction in plant density, 98.06%, occurred after winter wheat and 97.62% after spring wheat pre-crops compared to perennial grass pre-crops. The highest chlorophyll index was in winter wheat crops, where the pre-crops were peas, winter rape, and perennial grasses, respectively, ranging from 17.78% to 19.57%. Properly selected pre-crops reduce the risk of overwintering and form a strong crop from the beginning of vegetation.
1. Introduction
Wheat is one of the main cereal crops worldwide [1,2]. Additionally, wheat is the most-grown cereal crop, with over 220 million hectares planted annually [3]. The main variety of grain cultivated is T. aestivum, occupying 90% of all wheat areas. The remaining 10% is composed of T. durum and T. spelta [4]. Winter wheat (Triticum aestivum L., 2n = 6x = 42, AABBBD) is a naturally formed allohexaploid species., having seven homoeologous chromosome groups [5]. Since wheat farming is relatively easy and suitable for mechanization, farmers often choose to cultivate these crops. A significant factor in increasing wheat productivity is the variety [6]. The replacement of old varieties with new, more productive, competitive ones, characterized by wide agro-ecological adaptability and enhanced traits for adapting to adverse environmental conditions, better suited to specific soil and climate conditions, and higher levels of agricultural technology, is one of the best ways to obtain large quantities of high-quality grain [7]. With the change of the global climate, the risk of freeze damage to wheat cultivation has increased. In recent years, with the comprehensive research on the freeze resistance of wheat, especially the development of genetic engineering technologies, the research on the freeze resistance of wheat has made great progress [8]. Wang et al. (2024) found that the chlorophyll, soluble sugar, soluble protein, and free proline contents of various winter wheat varieties were positively correlated with cold resistance, while the malondialdehyde content was negatively correlated with cold. Five physiological parameters can be used as physiological indicators for breeding cold-resistant varieties [9]. Currently, there are more than 460 winter wheat varieties registered in the State Register of Plant Varieties [10].
‘Skagen’ is the most popular variety in the Baltic region. It was registered in Lithuania 12 years ago. The ‘Skagen’ variety is characterized by high and stable yields, excellent spring emergence, and good resistance to many foliar diseases [11,12].
According to Šuliauskas [13], winter wheat is best sown after peas, beans, winter rape, and spring rape. It also thrives when sown after spring wheat, whose pre-crop is winter rape. According to Romaneckas [14], winter wheat is considered a soil-depleting agricultural crop, and if sown after spring wheat, it may become susceptible to root diseases. Therefore, from a crop rotation perspective, the most suitable pre-crops for wheat are soil-improving plants such as legumes and perennial grasses. According to data from the Lithuanian Institute of Agriculture, spring barley is a better pre-crop for reducing weediness in winter wheat than peas, winter rape, and winter wheat. The number of plants that did not overwinter was determined.
Temperature and precipitation are the major weather characteristics that contribute to crop growth in the North in general and the overwintering capacity of rye and wheat when grown in northern European conditions [15,16]. It is projected that the climate will continue to become warmer and the growing season longer, but the increases in temperatures will occur mostly outside the growing season, during autumn and winter [17,18,19] Wheat freezing occurs when the temperature drops below 0 °C [20], along with various freeze injuries, including sudden temperature drops at the beginning of winter, prolonged cold in winter, drought and freezing, freezing, and warming up in early spring [21]. Freezing damage can disrupt plant physiological and metabolic processes, such as water metabolism, mineral nutrition, photosynthesis, respiration, and general metabolism [22]. Freezing damage causes water to freeze inside and outside the cell, and these ice crystals penetrate the cell walls, causing cell dehydration and death.
Osmotic stress has been shown to be a dominant factor affecting the ability of winter wheat varieties to survive winter [23,24].
Low temperature stress can pose a serious threat to plants throughout their life cycle and seriously affect crop yield and quality. Therefore, it is urgent to identify effective, sustainable, and environmentally friendly practices that can reduce the negative effects of low temperature on plants and improve crop performance [25].
Accumulation of reactive oxygen and abiotic free radicals occurs in frozen damaged plants, which damage the internal environment and membrane system of cells, even causing leaf withering and necrosis/death [26]. Due to all these factors, wheat does not survive smoothly. Freezing damage is an agricultural meteorological disaster that can occur in winter and early spring, causing plant tissues to dry out and freeze, thus losing physiological activity. This ultimately can lead to plant damage or even death [20]. Several freezing damage studies have been conducted [27,28]. Meng et al. [29] determined the freezing damage indices of winter wheat overwintering in northern China using the principal component method.
The aim of the study is to determine the influence of different pre-sowing treatments on the survival of the winter wheat variety ‘Skagen’ in Albeluvisol soils as winters warm and precipitation increases in autumn and winter. The main objectives are to determine weediness after the application of different pre-sowing treatments to winter wheat and to assess crop viability after plant vegetation renewal.
2. Materials and Methods
2.1. Experimental Design and Agricultural Practices
During the study, three different locations in Lithuania with different pre-crops were selected (Figure 1). The experimental sites were chosen so that they were not far from each other due to climatic conditions and soil type. Fields of the winter wheat (Triticum aestivum) variety ‘Skagen’ from farms in the Lazdijai district were chosen for the experiment. The experiment was conducted from 2017 to 2018.
The farms are intensive production ones, employing crop rotation: winter wheat (Triticum aestivum), winter rape (Brassica napus), and peas (Pisum sativum) (Table 1).
The soil tillage in all treatments was uniform—deep plowing (20–25 cm), soil cultivation, fertilization, and sowing (Table 2). The preparation of winter wheat for wintering was conducted in all farms on November 25th. The seed rate and sowing depth were chosen by determining the economic value of seeds is as follows [30]:
Agricultural value of seeds,% = (Germination,% × Cleanliness,%)/100
To determine the economic value, it is necessary to know the germination and cleanliness of the seeds. For example, the germination rate of the available seeds is 87 percent, and the purity is 99.5 percent. We calculate [31]:
(87 × 99.5)/100 = 86.6%
Next, we calculate the seed rate by physical weight, in kilograms [31]:
(Weight of 1000 seeds,g × Seed rate,mln.ha × 100)/(Economic value of seeds) = Seed rate,kg/ha
For example, we are calculating the sowing rate for spring wheat, and the planned sowing rate is 5 million sprouted seeds per hectare. The mass of 1000 seeds is 45.4 g [31].
(45.5 × 5.0 × 100)/86.6 = 262.70 kg/ha
For successful germination, crops must be sown to a depth within the physiological tolerance of the seed (Table 3). For wheat, it is generally considered to be 30–50 mm; for lupins, it is 25 mm, and for field peas, it is 30–50 mm [32].
The plant condition was assessed at 10-day intervals. The soil type was Albeluvisol. The assessment of winter plant conditions in both farms was conducted on April 15th.
During the study, the selected variants were conducted in three replications, with the size of the experimental plot being 30 m2 (10 m in length and 3 m in width). Soil samples were taken using an agrochemical soil sampling auger (Ø 20 mm) at linear EPV spacing. Samples were taken from a depth of 0–25 cm. This depth was chosen due to the main freeze risk and main nutrients in this soil layer (Figure 2). This sampling depth was chosen because it is the main layer that contains nutrients for plant roots, which are just beginning to grow. Another main reason freeze is damaging to roots in this soil layer is the risk of uprooting or damaging the plants’ water vessels.
The trajectory line was formed by the letters X and W. In each replication of the variant, 15 soil samples were taken, forming a total of 250 g of soil sample. Soil chemical properties were determined (Table 4).
During the study, at the beginning of plant vegetation, when the growth stage BBCH 29–30 was reached, the variation of chlorophyll content in leaves was assessed. The measurement was made on the two leaves from the top of the main stem of the plant. Soil temperature was measured using an electronic thermometer IQ 150 in the plant root growth zone. Measurements were taken at 10-day intervals on April 1st, 10th, and 20th.
An electronic chlorophyll meter CM 1000 was used to determine chlorophyll content. Measurements were taken at 10-day intervals on April 1st, 10th, and 20th.
The density of winter wheat crops was evaluated. In permanent accounting plots with an area of 30 m2 on April 15th, all surviving plants were counted in all variants.
2.2. Meteorological Conditions
Meteorological conditions are one of the main factors influencing the winter hardiness of plants. Plants that manage to grow 3–4 tillers before winter are the best suited for wintering. Prolonged severe frosts and temperature fluctuations can hurt crops. After freezing weather, water in the plants can freeze, leading to vitrification. This process occurs when the temperature suddenly drops to −20 °C. Sudden warming can be devastating for plants [34].
In September 2017, the average air temperature ranged from 12.5 to 14.7 °C (0.5–1.5 °C higher than the standard climate norm for the period of 1981–2010 (hereinafter referred to as SCN). The highest air temperature at the beginning of the month rose to 21–25 °C. The lowest air temperature in late September dropped in many places to 1–4 °C (Table 5). During September, precipitation in most parts of Lithuania ranged from 90 to 190 mm (1.5 to 2.5 times the SCN).
In October 2017, the average air temperature ranged from 6.1 to 9.9 °C (close to the SCN in many regions). The highest air temperature in the middle of the month rose to 14–20 °C. The lowest air temperature in many places dropped to 0–4 °C. The weather was very rainy. In October, precipitation in most parts of Lithuania ranged from 80 to 125 mm (1.5 to 2 times the SCN).
In November 2017, the average air temperature ranged from 2.5 to 5.8 °C (1.7–2.4 °C higher than the SCN in many areas). The highest air temperature rose to 9–11 °C. The lowest air temperature dropped in many areas to −1 to −3 °C. In December 2017, the average air temperature ranged from 0.0 °C in the eastern regions of the country. The highest air temperature reached 7–10 °C. The lowest air temperature dropped to −1 to −6 °C. In December, precipitation in most parts of Lithuania ranged from 61 to 95 mm (1.3–1.5 times the SCN). A thin (1–10 cm) snow cover was formed almost everywhere in the country on the first day of the month, but by the end of the first month, snow had melted in many areas. In February 2018, the average air temperature ranged from −4.3 to −7.4 °C (2–3.5 °C lower than the SCN). The highest air temperature rose to 1–4 °C. The lowest air temperature dropped in many areas to −19 to −25 °C. In February, precipitation in most parts of Lithuania ranged from 21 to 40 mm (55–90% of the SCN). There was no frost in the Lazdijai region. In March 2018, the average air temperature ranged from −1.0 to −2.8 °C (2.2–2.8 °C lower than the standard climate norm). The highest air temperature rose to 8–11 °C. The lowest air temperature dropped in many areas to −15 to −20 °C (Table 5). In April 2018, the average air temperature ranged from 8.1 to 11.1 °C (positive anomaly of 2–3.6 °C). The highest air temperature reached 22–27 °C this month. The lowest air temperature dropped in many areas to −1 to −4 °C, with frost observed on several nights towards the end of the month—the temperature on the soil surface dropped to −1 to −7 °C. In most parts of the country, precipitation ranged from 40 to 70 mm (1.2–2.3 times the SCN). The soil remained frozen longer than usual, but thawed intermittently—sometimes frozen, sometimes thawed. Frost persisted at the beginning of the month, but by April 10th, the soils had thawed everywhere. In May 2018, the average air temperature ranged from 15.1 to 17.5 °C (positive anomaly of 2.4–4.8 °C). It was the hottest May since 1961: The previous highest average air temperature in Lithuania was 15.4 °C (in 1993 and 2013), but this year, it was 1 degree higher (16.4 °C). New heat records for May 3rd and 29th were set in Lithuania, and on the 30th, the record for the entire month of May reached 32.7 °C. Precipitation in May was lower than usual: In almost all of southern Lithuania and parts of the northern and western regions, it ranged from 7 to 25 mm (up to 0.5 times the SCN) (Table 5).
In September and October, the precipitation amount was more than twice as high compared to the long-term average of precipitation. Such a high amount of precipitation must have made it difficult for plants to start growing due to a possible lack of oxygen in the vascular system (Table 6).
November precipitation (50.0 mm) was in line with the long-term average, while December precipitation was 36.1 mm more than the usual in December. February precipitation was 19.1 mm less than the long-term average. In the spring period from March to May, precipitation was 71 mm, which was 50.64% less than the long-term average in the spring period.
2.3. Statistical Analysis
During the study, the data for the years were processed using a one-factor analysis of variance (ANOVA) method, using the computer program ANOVA from the SYSTAT 12 software package. The probability level of differences among all the treatments was determined using the LSD test [35].
3. Results
3.1. The Density Assessment of Winter Wheat Crops During the Autumn and Spring Periods
Research data were collected from three farms at the beginning of plant vegetation during the autumn period and at the onset of vegetation renewal at the beginning of spring (Figure 3).
After evaluating the different plant emergence rates, it was found that significantly more plants, ranging from 37.86% to 57.59%, were present after pre-crops of winter rape, winter wheat, and spring wheat compared to perennial grasses, and from 21.10% to 46.15% compared to peas (Table 7).
After evaluating the differences in plant density after winter, it was found that a significantly greater reduction in plant density, 98.06%, occurred after winter wheat and 97.62% after spring wheat pre-crops compared to perennial grass pre-crops.
Meteorological conditions, which are a crucial factor for plant winter hardiness, were not favorable during the study. This primarily influences the quality of grains. Meteorological conditions during the growth period can impact grain quality more than its variety [36].
3.2. Study of Winter Wheat Photosynthetic Activity
Photosynthesis is one of the main physiological processes determining the productivity of plant organisms. Effective photosynthetic activity is ensured by the appropriate content and ratio of chlorophylls [37]. According to Romaneckas [14], in young plants, the chlorophyll content begins to decrease in the absence of nutrients and increases under favorable conditions. Spectrometric methods are used to determine the chlorophyll content index under field conditions without damaging the leaf structure.
After evaluating the chlorophyll content in leaves from the renewal of plant vegetation, it was found that the highest chlorophyll index was in winter wheat crops where the pre-crops were peas, winter rape, and perennial grasses, respectively, ranging from 17.78% to 19.57% (Figure 4). When assessing the fluctuations in chlorophyll content, the potentially highest winter wheat yield should be after the following pre-crops: peas and winter rape.
The highest chlorophyll index was recorded after both 10 and 20 days in the same crops where the pre-crops were peas or winter rape. The lowest chlorophyll index was found in the treatment where winter wheat was resown. The most suitable pre-crops for wheat and perhaps the best solution for environmental purposes are soil-improving plants such as legumes and perennial grasses [38].
After evaluating the effect of different pre-crops on winter wheat weediness before wintering, it was found that significantly more weeds were present in all treatments compared to the treatment where perennial grasses were grown before sowing winter wheat (Table 8). The highest weed infestation was found in the treatment where winter wheat was followed by winter wheat again. Crop rotation can reduce environmental stress, weed proliferation, plant diseases, and the risk of insect pests specific to certain crops [39].
After analyzing the research data, it was noticed that the fewest weeds were found in the ‘Skagen’ variety of winter wheat fields where the pre-crop crop was perennial grassland. The highest weed count was observed where winter wheat was followed by winter barley—up to 78 units m2. Overall, it can be concluded that weed infestation is highest in winter wheat after-crops. By applying proper crop rotation, weed infestation in fields can be reduced, leading to savings on herbicides.
In winter wheat, yield and grain quality are more influenced by the pre-crop than by tillage practices. The best pre-crop for high yields with favorable grain quality characteristics was winter rape, and the worst was maize grown for grain. However, reducing tillage to only stubble disking negatively affected yield and yield components. In the situation after winter wheat, especially after winter rape, tillage can be limited by stubble disking without negative effects on grain yield, its bulk density, or protein content [40].
Sowing time is one of the most important factors in cultivation technology for the formation of productive and higher winter hardiness crops. According to Šuliauskas [13], from an agronomic point of view, the optimal sowing date for winter wheat in Lithuania is 10–25 September. According to statistics, only 5% of winter wheat is sown in Lithuania before 10 September, and 20–25% after 25 September. According to Romaneckas [14], the timing of sowing winter wheat depends mainly on the autumn weather conditions. The longer the warm autumn, the later the sowing can be. It is usual to sow winter wheat from the end of August to mid-September.
4. Discussion
Pre-sowing crops have had a positive effect on wheat yields. The lowest cereal yields were observed under conditions without pre-crops and no planting of beech. The brassica family plants grown in these experiments showed a positive effect on grain yield, harvest index, number of seeds per spike, and number of spines per spike. Therefore, it can be concluded that using brassica family plants can improve the physical conditions of the soil, increase the organic matter content, and have a positive effect on subsequent yield [41].
Plant development depends on ambient and soil temperature, soil moisture content, and fertility. Temperature and humidity are the factors that most determine the intensity of soil gas and water vapor flux. They interact to alter the rate of decomposition of organic matter and other biological and biochemical processes in the soil [35,36]. Peltonen-Sainio et al. [42] conducted a study related to the overwintering of cereals and the amount of precipitation in autumn. The research team stated that the severity of overwintering damage varies greatly from year to year, and the study failed to determine the dependence on the wheat variety and overwintering. However, it was observed that overwintering damage may increase due to climate change, which is currently increased by the large amount of autumn precipitation. In particular, fluctuating conditions for wheat prevent wintering in the current growing regions, and this is unlikely to change in the future, but climate change may worsen the situation even more. Žekonienė et al. [43] found that the overwintering of winter wheat is greatly affected by the time of early spring, when the frost has not yet completely gone, spring frosts begin, and, as a result, the upper soil layer begins to move, weak wheat roots are broken, and their seedlings are uprooted. Then many plants die. At the same time, it depends on the type of soil and how much organic matter it contains. I. Pranckietienė [44] states that the overwintering of plants largely depends on the applied fertilization in the autumn period. Overwintering is related to the distribution of proteins, carbohydrates, organic compounds, and the enzyme superoxide dismutase in plants. The growth of winter crops is prolonged during the growing season. According to Šuliauskas [13], winter wheat has different air temperature requirements as it grows and develops. For example, seeds germinate at 2–3 °C and germinate at 5–8 °C. The optimum germination temperature is 16–20 °C. The above-ground part of the plant starts to grow at temperatures of at least 4–6 °C. The optimum air temperature for initial growth is 14–16 °C. The stem and inflorescences start to form internally at a temperature of 6–10 °C. The flowering and fruiting of wheat is possible at 12–14 °C. The optimum temperature for grain maturation is 18–22 °C.
5. Conclusions
- The evaluation of the number of plants that did not overwinter after the different pre-crops showed that there was a significantly higher reduction of plants after the winter and spring wheat pre-crop compared to the perennial grass pre-crop.
- The chlorophyll index from the beginning of the growing season was found to be significantly higher in winter wheat after peas and winter rape throughout the most active period of the growing season. The lowest chlorophyll index was found in winter wheat that was resown.
- The fewest weeds were found in the winter wheat crop ‘Skagen’ with the pre-crop of perennial grassland. The highest number of weeds was found where winter wheat was resown after winter wheat—78 units m2. It can be stated that winter wheat that is resown has the highest weed density. With the right crop rotation, it is possible to reduce the weediness of the crop.
- The best pre-crops for winter wheat for overwintering are the perennial grasses and winter rape, because the lowest number of dead plants were in these treatments. When evaluating the treatments, the deadest winter wheat plants after overwintering were winter wheat as pre-crops and spring wheat, as well.
Author Contributions
Conceptualization, D.Š., L.S. and D.K.; methodology, D.Š., L.S. and D.K.; software, D.Š., L.S. and D.K.; validation, D.Š., L.S. and D.K.; formal analysis, D.Š., L.S. and D.K.; investigation, D.Š., L.S. and D.K.; resources, D.Š., L.S. and D.K.; data curation, D.Š., L.S. and D.K.; writing—original draft preparation, D.Š., L.S. and D.K.; writing—review and editing, D.Š., L.S. and D.K.; visualization, D.Š., L.S. and D.K.; supervision, D.Š., L.S. and D.K.; project administration, D.Š., L.S. and D.K.; funding acquisition, D.Š., L.S. and D.K. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
The original contributions presented in the study are included in the article; further inquiries can be directed to the corresponding authors.
Conflicts of Interest
The authors declare no conflicts of interest.
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Figure 1.
Experimental locations.
Figure 2.
The trajectory of soil sampling.
Figure 3.
Density assessment of winter wheat crops during the autumn and spring periods, 2017–2018, units m−2. Notes. a–d Different letters indicate significant differences between the treatments (p < 0.05).
Figure 3.
Density assessment of winter wheat crops during the autumn and spring periods, 2017–2018, units m−2. Notes. a–d Different letters indicate significant differences between the treatments (p < 0.05).
Figure 4.
Changes in chlorophyll content in winter wheat leaves after different pre-crops, 2018. Notes. a,b Different letters indicate significant differences between the treatments (p < 0.05).
Figure 4.
Changes in chlorophyll content in winter wheat leaves after different pre-crops, 2018. Notes. a,b Different letters indicate significant differences between the treatments (p < 0.05).
Table 1.
Experimental treatments.
| Treatment | Pre-Crop |
|---|---|
| PG | Perennial grasses (Trifolium pratense L. + Phleum pratense L.) |
| P | Peas (Pisum sativum L.) |
| WR | Winter rape (Brassica napus L.) |
| WW | Winter wheat (Triticum aestivum L.) |
| SW | Spring wheat (Triticum aestivum L.) |
Note: PG—perennial grasses; P—peas; WR—winter rape; WW—winter wheat; SW—spring wheat.
Table 2.
Agrotechnical measures of the experiment.
| Treatments | Treatment A | Treatment B | Treatment C |
|---|---|---|---|
| Variety | Skagen | Skagen | Skagen |
| Sowing date | 09–25 | 09–26 | 09–24 |
| Seed rate kg/ha | 230 kg/ha | 230 kg/ha | 230 kg/ha |
| Sowing depth | 3 cm | 3 cm | 3 cm |
| Type of sowing | Interspersed—12 cm | Interspersed—12 cm | Interspersed—12 cm |
Table 3.
Agrotechnical measures for growing winter wheat and their implementation time.
| Agrotechnical Tools | Norms | Time of Completion of Works |
|---|---|---|
| Fertilizer spread N8P20K30 | 300 kg/ha | 20 September 2021 |
| Sprayed‚ Legascy pro’ | 1.8 L ha−1 | 8 October 2021 |
| Ammonium nitrate | 150 kg ha−1 | 11 March 2022 |
| Ammonium nitrate | 200 kg ha−1 | 22 April 2022 |
| Sprayed‚ Cycocel 750 SL’ | 1.2 L ha−1 | 29 April 2022 |
| Ammonium nitrate | 100 kg ha−1 | 17 May 2022 |
| Tempo+ | 0.3 L ha−1 | 19 May 2022 |
| Flexit | 0.25 L ha−1 | 19 May 2022 |
Table 4.
Pre-crops of the experiments and soil chemical properties.
| Variant A of the experiment: | ||||||
| Position No. | Pre-crop | Variety | pHKCl | Humus content, % | mg kg−1 of the soil | |
| P2O5 | K2O | |||||
| 1. | Perennial grasses | Skagen | 6.76 | 2.01 | 130 | 159 |
| Potentiometric method KCL LST ISO 1039:2005 [33] | Titrimetric method (SVP-4) | Spectrometric Egnerio-Rimo-Domingo method (A-L) (SVP 2-1: SVP 2-2) | ||||
| Variant B of the experiment: | ||||||
| Position No. | Pre-crop | Variety | pHKCl | Humus content, % | mg kg−1 of the soil | |
| P2O5 | K2O | |||||
| 2. | Winter rape | Skagen | 7.48 | 1.04 | 57 | 85 |
| Potentiometric method KCL LST ISO 1039:2005 | Titrimetric method (SVP-4) | Spectrometric Egnerio-Rimo-Domingo method (A-L) (SVP 2-1: SVP 2-2) | ||||
| Variant C of the experiment: | ||||||
| Position No. | Pre-crop | Variety | pHKCl | Humus content, % | mg kg−1 of the soil | |
| P2O5 | K2O | |||||
| 3. | Winter wheat | Skagen | 7.62 | 1.33 | 48 | 95 |
| Potentiometric method KCL LST ISO 1039:2005 | Titrimetric method (SVP-4) | Spectrometric Egnerio-Rimo-Domingo method (A-L) (SVP 2-1: SVP 2-2) | ||||
Note: P2O5—mobile phosphorus; K2O—mobile potassium; KCl—potassium chloride.
Table 5.
Average temperature (°C) and the sum of the active temperatures (SAT) during the winter wheat growing season (September–May) in 2017–2018.
Table 5.
Average temperature (°C) and the sum of the active temperatures (SAT) during the winter wheat growing season (September–May) in 2017–2018.
| Year/Month | 09 | 10 | 11 | 12 | 01 | 02 | 03 | 04 | 05 | SAT |
|---|---|---|---|---|---|---|---|---|---|---|
| 2017–2018 | 13.6 | 8.0 | 4.2 | 1.8 | −5.9 | −5.9 | −1.9 | 9.6 | 16.3 | 2331.5 |
| Long-term average 1974–2018 | 12.6 | 6.8 | 2.8 | −2.8 | −3.7 | −4.7 | 0.3 | 6.9 | 13.2 | - |
Table 6.
Precipitation (mm) during the winter wheat growing season (September–May) in 2017–2018.
| Year/Month | 09 | 10 | 11 | 12 | 01 | 02 | 03 | 04 | 05 | Sum |
|---|---|---|---|---|---|---|---|---|---|---|
| 2017–2018 | 140.0 | 102.5 | 50.0 | 78.0 | 30.5 | 16.0 | - | 55.0 | 16.0 | 488.0 |
| Long-term average 1974–2018 | 60.0 | 51.0 | 51.0 | 41.9 | 38.1 | 35.1 | 37.2 | 41.3 | 61.7 | 417.3 |
(http://www.meteo.lt/lt/oro-temperatūra accessed on 18 June 2022).
Table 7.
Number of plants that did not overwinter after different pre-crops, units m−2.
| Treatment | Pre-Crop | Dead Plants (Units m−2) |
|---|---|---|
| PG | Perennial grasses | 2 a |
| P | Peas | 28 ab |
| WR | Winter rape | 9 a |
| WW | Winter wheat | 103 d |
| SW | Spring wheat | 84 c |
Notes. a–d Different letters indicate significant differences between the treatments (p < 0.05). PG—perennial grasses; P—peas; WR—winter rape; WW—winter wheat; SW—spring wheat.
Table 8.
Evaluation of total weed infestation in winter wheat ‘Skagen’ during the autumn period after different pre-crops, 27 November 2018.
Table 8.
Evaluation of total weed infestation in winter wheat ‘Skagen’ during the autumn period after different pre-crops, 27 November 2018.
| Treatment | Pre-Crop | Number of Weeds (Units m−2) |
|---|---|---|
| PG | Perennial grasses | 2 a |
| P | Peas | 19 b |
| WR | Winter rape | 10 b |
| WW | Winter wheat | 78 c |
| SW | Spring wheat | 14 b |
Notes. a–c Different letters indicate significant differences between the treatments (p < 0.05). PG—perennial grasses; P—peas; WR—winter rape; WW—winter wheat; SW—spring wheat.
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Šumskienė, D.; Skinulienė, L.; Klimavičius, D. Winter Wheat Resilience Under Different Pre-Crop Conditions in Albeluvisol Soils. Sustainability 2025, 17, 216. https://doi.org/10.3390/su17010216
AMA Style
Šumskienė D, Skinulienė L, Klimavičius D. Winter Wheat Resilience Under Different Pre-Crop Conditions in Albeluvisol Soils. Sustainability. 2025; 17(1):216. https://doi.org/10.3390/su17010216
Chicago/Turabian StyleŠumskienė, Dalė, Lina Skinulienė, and Donatas Klimavičius. 2025. "Winter Wheat Resilience Under Different Pre-Crop Conditions in Albeluvisol Soils" Sustainability 17, no. 1: 216. https://doi.org/10.3390/su17010216
APA StyleŠumskienė, D., Skinulienė, L., & Klimavičius, D. (2025). Winter Wheat Resilience Under Different Pre-Crop Conditions in Albeluvisol Soils. Sustainability, 17(1), 216. https://doi.org/10.3390/su17010216
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