Determination of the physiological response of lettuce to different irrigation water salinities (NaCl) and leaching fractions

Yıl 2024, Cilt: 29 Sayı: 2, 552 - 568

Berkant Ödemiş Derya Kazgöz Candemir Cihan Karaca

https://doi.org/10.37908/mkutbd.1466659

Öz

The Amik Plain, where the experiment was conducted, is increasingly salinised owing to improper irrigation methods, excessive irrigation, drainage and groundwater use. This situation indicates that soil salinity will increase even more in the future. The study was conducted using a factorial experimental design in potted conditions inside the greenhouse to investigate the impacts of three distinct levels of irrigation water salinity (ECi) (ECi-0= 0.5 dS m-1 (control), ECi-2= 2 dS m-1and ECi-4= 4 dS m-1) and four different leaching fraction (LF) (LF0=0%, LF10=10%, LF20=20%, LF30=30%) on stomatal conductance (gs), leaf surface temperature (LSt), chlorophyll content (SPAD), chlorophyll concentrations (Chl-a, Chl-b, and Chl-tot) and yield parameters in 'Cospirina' lettuce plants. As a result of the study, soil salinity (ECe) increased from 0.82 dS m-1 to 2.09 dS m-1 with increasing ECi. As ECi increased, plant water consumption (PWC) decreased from 8.92 to 5.71 L pot-1, yield decreased from 276 g pot-1 to 198 g pot-1, gs decreased from 266 mmol m-2 s-1 to 215 mmol m-2 s-1. LSt increased by 2.17% in ECi-2 and 6.4% in ECi-4 compared to the control. As ECe increased, yield decreased by 10% in ECi-2 and 28% in ECi-4 compared to the control treatment. Chl-tot and Chl-a were significantly affected by the increase in ECe (r2=0.96*, r2=0.99**, respectively), while Chl-b was not affected. In contrast to soil salinity, leaching fraction had a positive effect on plant physiology.

Anahtar Kelimeler

Chlorophyll concentrations, Chlorophyll content, Greenhouse, Lactuca sativa L., Soil salinity, Stomatal conductance, Washing rate

Marulun farklı sulama suyu tuzluluklarına ve yıkama fraksiyonlarına karşı fizyolojik tepkisinin belirlenmesi

Öz

Denemenin yürütüldüğü Amik Ovası yanlış sulama yöntemleri, aşırı sulama, drenaj ve yeraltı su kullanımı nedeniyle hızla tuzlanmaktadır. Bu durum, toprak tuzluluğunun gelecekte daha da artacağını göstermektedir. Araştırma, ‘Cospirina’ çeşidi marul bitkisinde 3 farklı sulama suyu tuzluluğu (ECi) (ECi-0= 0.5 dS m-1 (kontrol), ECi-2= 2 dS m-1and ECi-4= 4 dS m-1) ve 4 farklı yıkama oranlarının (LF) (LF0=0%, LF10=10%, LF20=20%, LF30=30%) stoma iletkenliği (gs), yaprak yüzey sıcaklığı (LSt), klorofil içeriği (SPAD) ve klorofil konsantrasyonları (Chl-a, Chl-b ve Chl-tot) ve verim parametrelerine etkilerini belirlemek amacıyla seradaki saksı koşullarında faktöriyel deneme deseninde yürütülmüştür. Araştırma sonucunda, ECi arttıkça, toprak tuzluluğu (ECe) 0.82 dS m -1 den, 2.09 dS m-1’ye artmıştır. ECi’nin artmasıyla bitki su tüketimi (PWC) 8.92’den 5.71 L pot-1’ye, verim 276 g pot-1’dan 198 g pot-1’a, gs, 266 mmol m-2 s-1’dan 215 mmol m-2 s-1’a azalmıştır. LSt, ECi-0’a göre ECi-2’de %2.17, ECi-4’de %6.4 artmıştır. ECe arttığında verim tanık konuya göre, ECi-2’de %10 ve ECi-4’de %28 azalmıştır. Chl-tot ve Chl-a, ECe’deki artıştan önemli ölçüde etkilenirken (sırasıyla r2=0.96*, r2=0.99**), Chl-b etkilenmemiştir. Toprak tuzluluğunun aksine yıkama oranları bitki fizyolojisini olumlu etkilemiştir.

Anahtar Kelimeler

Klorofil konsantrasyonu, Klorofil içeriği, Lactuca sativa L., Sera, Toprak tuzluluğu, Stoma iletkenliği, Yıkama oranı

Kaynakça

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