Reclamation of Highly Calcareous Saline Sodic Soil Using<i>Atriplex Halimus</i>and by-Product Gypsum

Gharaibeh, Mamoun A.; Eltaif, N. I.; Albalasmeh, Ammar

doi:10.1080/15226514.2011.573821

Cited by 66 publications

(30 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These results suggest that application of organic amendments can facilitate efficient replacement of Na + on the exchange sites by adding significant amounts of divalent cations and may further prevent the entry of Na + onto the exchange phase, when low SAR water is used as a leaching solution. Similar results of enhanced Na + leaching were observed in other studies when saline-sodic soils were treated with various amendments (Ahmad et al, 2006;Ghafoor et al, 2012;Gharaibeh et al, 2011;Jalali and Ranjbar, 2009). It should be noted that the cumulative amounts of cations given in mmolc column −1 (Figs.…”

Section: Leachate Ecsupporting

confidence: 77%

“…All treatments were effective in reducing the soil ESP to <15 after leaching with 7 pore volumes of reclaimed water including the control. Koo et al (1990) and Gharaibeh et al (2011) reported similar results with saline-sodic soil being reclaimed with irrigation water and attributed this effect to 'valence dilution' (Reeve and Doering, 1966), where adsorption of divalent cations is preferred at the expense of monovalent cations when soil solution is diluted by added water. ESP reductions were still significantly greater (P < 0.01) in soils amended with organic amendments than in the control soils (Fig.…”

Section: Soil Espsupporting

confidence: 61%

See 1 more Smart Citation

Leaching and reclamation of a biochar and compost amended saline–sodic soil with moderate SAR reclaimed water

Chaganti

Crohn

Šimůnek

2015

Agricultural Water Management

175

View full text Add to dashboard Cite

a b s t r a c tRemediating saline-sodic soils with organic amendments is increasingly seen as a cheaper and sustainable alternative to inorganic materials. The reclamation potential of biochar, biosolids and greenwaste composts applied to a saline-sodic soil was evaluated in a laboratory leaching experiment using moderate SAR reclaimed water. Treatments included biochar, biosolids co-compost, greenwaste compost (all applied at a 75 t ha −1 rate), gypsum (50% soil gypsum requirement), biochar + gypsum, biosolids + gypsum, greenwaste + gypsum and a non-amended control. All treatments were subjected to a one month incubation after which, soils were filled in columns and leached using reclaimed water until 7 PV of water had passed. Cumulative leachate losses of Na + , Ca 2+ , and Mg 2+ were evaluated in addition to soil properties after leaching. Results show that leaching with moderate SAR water was effective in reducing the soil salinity and sodicity of all soils, irrespective of amendment application. However, incorporating biochar and composts significantly enhanced this effect. Salt leaching was higher in soils treated with organic amendments. Cumulative leachate losses of cations were significantly higher from biochar and compost treated soils compared to gypsum and unamended controls. Improvements in soil aggregate stability and saturated hydraulic conductivity were prominent in compost treated soils. After leaching, soil analyses indicated that organic amendments lowered significantly more soil EC e , ESP and SAR than that of the control soils and saturated the exchange complex with Ca 2+ . Soil pH was significantly reduced and CEC was significantly increased in only compost treated soils. Although individual organic amendment applications proved to be significant enough to remediate a saline-sodic soil, combined applications of gypsum and organic amendments were more effective in improving soil properties directly related to sodium removal including sodium leaching, hydraulic conductivity, ESP, and SAR, and therefore could have a supplementary benefit of accelerating the reclamation process.

show abstract

Section: Leachate Ecsupporting

confidence: 77%

Section: Soil Espsupporting

confidence: 61%

Leaching and reclamation of a biochar and compost amended saline–sodic soil with moderate SAR reclaimed water

Chaganti

Crohn

Šimůnek

2015

Agricultural Water Management

175

View full text Add to dashboard Cite

show abstract

“…5), and nearly 30 species of landscape plants, including some salinity-sensitive species, were proposed with survival up to 90% after one or two years. Meanwhile, the approach is applicable to the field condition, which is very different from the traditional reclamation methods mainly used in soil columns, lysimeter experiments, laboratory experiments or greenhouse conditions (Ammari et al, 2013;Gharaibeh et al, 2011Gharaibeh et al, , 2009Hanay et al, 2004;Mahmoodabadi et al, 2013;Miranda et al, 2011;Nayak et al, 2008;Oster et al, 1999;Qadir et al, 1996;Sidhu et al, 2004;Siyal et al, 2010;Somani, 1981).…”

Section: Landscape Re-vegetationmentioning

confidence: 99%

“…Phytoremediation is a technology that can improve plantnutrient availability, extend the depth of the ameliorated zone, and may promote stability of soil aggregates and soil hydraulic properties (Gharaibeh et al, 2011;Qadir and Schubert, 2002). However, biological methods for utilization or vegetative bioremediation of salt-affected soils are limited by the growth environment and salinity tolerance of plants, and are usually combined with chemical amendments and/or leaching methods in reclamation of highly saline-sodic soils.…”

Section: Introductionmentioning

confidence: 99%

First and second-year assessments of the rapid reconstruction and re-vegetation method for reclaiming two saline–sodic, coastal soils with drip-irrigation

Kang

Wan

et al. 2015

Ecological Engineering

View full text Add to dashboard Cite

a b s t r a c tSoil salinity, sodicity and saline groundwater are major constraints to the cultivation of landscape plants along oceanic coasts. A sustainable approach for reclaiming saline-sodic soils in coastal environments is evaluated. Soil tillage, phased saline water management based on soil matric potential under dripirrigation, and the installation of a gravel-sand layer were used. Field trials using the method showed that the proposed approach had the advantages of considerable water conservation, more effective salt leaching and successful re-vegetation with desired species. Severely saline soils became non-saline within the 0-40 cm soil profile after one year and non-saline to moderately saline within the 0-120 cm depth after two years. The approach can rather quickly create an attractive landscape and maintain good plant growth. Plants representing nearly 30 landscape species, including some sensitive to salinity were proposed. Plantings showed survival up to 90% after one and two years. This approach demands less water, improves the ecological environments, and will inspire development of coastal areas.

show abstract

“…Yet, in many arid environments, highquality water is not available to support the establishment of plants for revegetation projects. The removal of sodium salts from saline soils by tolerant plants, as an alternative for costly chemical amendments, has emerged as an efficient low-cost technology [9].…”

Section: Introductionmentioning

confidence: 99%

Effect of Salinity and Temperature on Germination of Lygeum spartum

Nedjimi

2013

Agric Res

View full text Add to dashboard Cite

Lygeum spartum L. (Poaceae) is one of the most important perennial grass species in arid steppes of Algeria. Its germination responses to environmental stresses are poorly understood. Therefore, experiments were conducted to determine the effect of salinity and temperature on the germination of seeds. Seeds were germinated at three alternating temperatures (10-20, 15-25, and 20-30°C), with four NaCl concentrations (0, 50, 100, and 150 mM) and 12-h photoperiod. Results indicate that seeds can germinate at high salt concentrations (150 mM NaCl). However, highest germination was obtained in distilled water. Lower thermoperiods promoted germination, while high temperatures significantly inhibited the germination of seeds at all NaCl concentrations tested. Rate of germination decreased with increases in salinity. Seeds recovered after being transferred to distilled water, and recovery was higher from higher salinity concentrations and lower thermoperiods. L. spartum is moderately salt tolerant at germination stage, and tolerance is affected by the interaction of temperature and NaCl concentration.

show abstract

Reclamation of Highly Calcareous Saline Sodic Soil UsingAtriplex Halimusand by-Product Gypsum

Cited by 66 publications

References 31 publications

Leaching and reclamation of a biochar and compost amended saline–sodic soil with moderate SAR reclaimed water

Leaching and reclamation of a biochar and compost amended saline–sodic soil with moderate SAR reclaimed water

First and second-year assessments of the rapid reconstruction and re-vegetation method for reclaiming two saline–sodic, coastal soils with drip-irrigation

Effect of Salinity and Temperature on Germination of Lygeum spartum

Contact Info

Product

Resources

About