Background and aims <p>Sheep wool (SW) is mostly underutilized and is treated as waste. This study investigates its ability to retain water in the soil.</p> Methods <p>After determining the chemical composition of SW, it was mixed with soil at ratios of 97.5:2.5 and 95:5-(soil:SW) in the first experiment, and 99:1, 98:2, and 97:3 in the second experiment. Silage maize plants were then grown in these soil-SW mixtures.</p> Results <p>Thermal camera imaging showed that SW treatments reduced canopy temperatures, indicating lower water and heat stress. Chlorophyll content increased with SW addition, peaking in the SW1 treatment (97.5:2.5 w/w) in the first experiment and in the SW2 treatment (98:2 w/w) in the second experiment. Stomatal resistance was generally higher in the first experiment but decreased with increasing SW levels in the second. Stomatal density increased across all SW treatments in both experiments. Pot weight confirmed that SW-treated pots retained more water. In the first experiment, maize dry weight increased with the SW1 treatment, while the highest dry weight was observed in SW2 treatment during the second experiment. Nutrient analysis showed significant increases in N and P concentrations with SW treatments. Potassium levels increased in the first experiment, while Ca and Mg showed variable responses across experiments. Manganese, Zn and Cu concentrations also increased with SW treatments.</p> Conclusions <p>This study highlights the potential of SW as a soil conditioner for improving water retention, nutrient uptake, and plant growth. Further research is recommended to optimize SW application rates across crop species and environmental conditions.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Reduced irrigation demand in maize cultivation through soil amendment with sheep wool: a natural water retention strategy

  • Ozge Sahin,
  • Selver Kan,
  • Fatma Gokmen Yılmaz,
  • Gamze Cakirer Seyrek,
  • Mohd Kamran Khan,
  • Sait Gezgin,
  • Aydin Gunes

摘要

Background and aims

Sheep wool (SW) is mostly underutilized and is treated as waste. This study investigates its ability to retain water in the soil.

Methods

After determining the chemical composition of SW, it was mixed with soil at ratios of 97.5:2.5 and 95:5-(soil:SW) in the first experiment, and 99:1, 98:2, and 97:3 in the second experiment. Silage maize plants were then grown in these soil-SW mixtures.

Results

Thermal camera imaging showed that SW treatments reduced canopy temperatures, indicating lower water and heat stress. Chlorophyll content increased with SW addition, peaking in the SW1 treatment (97.5:2.5 w/w) in the first experiment and in the SW2 treatment (98:2 w/w) in the second experiment. Stomatal resistance was generally higher in the first experiment but decreased with increasing SW levels in the second. Stomatal density increased across all SW treatments in both experiments. Pot weight confirmed that SW-treated pots retained more water. In the first experiment, maize dry weight increased with the SW1 treatment, while the highest dry weight was observed in SW2 treatment during the second experiment. Nutrient analysis showed significant increases in N and P concentrations with SW treatments. Potassium levels increased in the first experiment, while Ca and Mg showed variable responses across experiments. Manganese, Zn and Cu concentrations also increased with SW treatments.

Conclusions

This study highlights the potential of SW as a soil conditioner for improving water retention, nutrient uptake, and plant growth. Further research is recommended to optimize SW application rates across crop species and environmental conditions.