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Crop tolerance to seawater

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Crop tolerance to seawater is the ability of an agricultural crop to withstand the high salinity induced by irrigation with seawater, or a mixture of fresh water and seawater. There are crops that can grow on seawater and demonstration farms have shown the feasibility.[1] The government of the Netherlands reports a breakthrough in food security as specific varieties of potatoes, carrots, red onions, white cabbage and broccoli appear to thrive if they are irrigated with salt water.[2]

Salt Farm Texel

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The Salt Farm Texel, a farm on the island of Texel, The Netherlands, is testing the salt tolerance of crops under controlled field conditions. There are 56 experimental plots of 160 m2 each that are treated in eight replicas with seven different salt concentrations. These concentrations are obtained with intensive daily drip irrigations of 10 or more mm (i.e. more than 10 liter per m2 per day) with water having a salt concentration expressed in electric conductivity (EC) of 2, 4, 8, 12, 16, 20 and 35 dS/m.[3] The range of EC values is obtained by mixing fresh water with the appropriate amount of seawater having a salinity corresponding to an EC value of about 50 dS/m. After planting, crops were allowed to germinate under fresh water conditions before the salt treatment started.

Soil salinity

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The soil salinity is expressed in the electric conductivity of the extract of a saturated soil paste (ECe in dS/m).[4]

Author Schleiff presented a classification of salt tolerance of crops based on ECe in dS/m [5] that may be summarized as follows:

Salt tolerance
ECe (dS/m) ^)
Tolerance classification
    < 2 very sensitive
    2 – 4 sensitive
    4 – 6 slightly sensitive
    6 – 8 moderately tolerant
    8 – 10 tolerant
    > 10 very tolerant

^) The crop performs well (no yield reduction) up to the soil salinity level listed in the table. Beyond that level, the yield goes down.

The main difference with the classification published by Richards in the USDA Agriculture Handbook No. 60, 1954 [4] is that the classes are narrower with steps of 2 dS/m instead of 4.

Maas–Hoffman model fitted to a data set.
In this example the crop has a salt tolerance (threshold) of ECe=7 dS/m beyond which the yield declines.
Data from Salt Farm Brochure. Boundaries (yellow) and error ranges (light brown) have been added. The scatter is quite high. It is not known whether the yield percentages were computed year by year (A), or for all years combined (B). In case B the error ranges are still larger due to annual yield differences. No analysis of variance (Anova) was done to prove that the Maas-Hoffman model really is a statistically significant improvement over a simple, straightforward, downward sloping linear regression model.
The Salt Farm Texel also published a graph of the yield-salinity relation of white cabbage. Boundary lines were added separately in red color. The boundaries suggest that the slope of the ellipse encompassing the confidence area of the breakpoint should be upward to the right instead of to the left. However the Texel document does not give an explanation of the construction of the ellipse.

Modeling

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The Salt Farm Texel uses the Maas–Hoffman model for crop response to soil salinity.[6] The model uses a response function starting with a horizontal line connected further on to a downward sloping line. The connection point is also called threshold or tolerance. Up to the threshold the crop is not affected by soil salinity while beyond it the yield starts declining. The model is fitted to the data by piecewise linear regression.[7]

Results

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Crop Variety   ^) Threshold *)
(ECe in dS/m)
Class
Potato   x) Mignonne      #) 4.1 slightly sensitive
Achilles 2.9 sensitive
Foc 2.1 sensitive
Met 1.9 very sensitive
"927" 3.4 sensitive
Carrot Cas 4.5 slightly sensitive
Ner 3.6 sensitive
Nat < 1 very sensitive
Ben < 1 very sensitive
"101" 3.0 sensitive
"102" 5.0 slightly sensitive
Pri 2.1 sensitive
Onion Alo 2.4 sensitive
Red 5.9 slightly sensitive
San 3.2 sensitive
Hyb 3.4 sensitive
Lettuce Batavia H < 1 very sensitive
Batavia S 2.3 sensitive
Butterhead L 1.8 very sensitive
Cabbage   White cabbage   #)   4.6 slightly sensitive
Broccoli 5.6 slightly sensitive
Barley Que 2014 3.3 sensitive           +)
Que 2015 1.7 very sensitive   +)

^) Many variety names are uncommon as they consist of 3 letters only
*) It is not known what the results would have been if the planting was not done under fresh water conditions but in saline conditions.
#) Graphs with scatter plots are shown in the report for these two varieties only. They show considerable variation both in Y (Yield) and X (ECe) direction.
x) For potato only one comparable value is known in literature, namely for the very sensitive variety white rose having a threshold of 1.7 dS/m [8]
+) For barley, in contrast, the U.S. Salinity Laboratory mentions a threshold value of ECe = 8 dS/m, which makes it a tolerant crop [9]

Summary

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The highest tolerance is found for the onion variety "Red" which classifies as slightly sensitive. All crops classify in the range from very sensitive over sensitive to slightly sensitive. There is no crop classified as tolerant, not even moderately tolerant.

S-curve model

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In the Texel report, also the Van Genuchten-Gupta model (giving an S-curve) was used to find the soil salinity at the 90% yield point. The rationale for this was not given.

Lentils

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Lentils

The Mediterranean Agronomic Institute, Valenzano, Bari, Italy South coast grew 5 cultivars of lentil irrigated with sea water of different salinity levels. Saline water was prepared by mixing fresh water (EC = 0.9 dS/m) with sea water (EC = 48 dS/m) to achieve salinity levels of 3.0, 6.0, 9.0 and 12.0 dS/m.[citation needed] Some of the results are shown in the following table:

Salinity
(dS/m)
Relative seedling length in % (control = 100%)
by cultivar
ILL4400 ILL5582 ILL5845 ILL5883 ILL8006
      3     98     83     82     98     96
      6     70     43     78     90     83
      9     57     48     63     52     62
    12     36     40     38     30     43

Halophytes

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Turtleweed

Halophytes, or salt-loving plants, can be irrigated with pure seawater with the aim to grow fodder crops. A trial was made by Glenn et al. to use halophytes for feeding of sheep and it was concluded that the animals thrived well.[10]

Setting the yield of an alfalfa (lucerne) fodder crop irrigated with fresh water (2 kg/m2) at 100%, the following results were obtained for the yield of halophytic crops irrigated with seawater:

Crop Relative yield (%)
Atriplex lentiformis, quailbush 90
Pickleweed, turtleweed 89
Suaeda sp., sea blite 88
Dwarf glasswort, Salicornia bigelovii 87
Sesuvium portulacastrum, sea purslane 85
Distichlis palmeri, Palmers grass 65
Atriplex cinerea, coast salt bush 45
Barley (Hordeum vulgare)

Barley

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After selecting the most salt tolerant cultivar, the University of California at Davis has grown barley irrigated with pure seawater and obtained half the normal yield per acre, i.e. half of the average yield per acre at national level.[11] The experiment was conducted at Bodega Bay, North of San Francisco, in a laboratory on the Pacific Ocean.

Rice

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Liu Shiping's team at Yangzhou University created rice varieties that can be grown in salt water, and achieve yields of 6.5 to 9.3 tons per hectare.[12][13] As of 2021, seawater rice had been planted on 400,000 ha (990,000 acres) in soils with up to 4 grams of salt per kilogram, with yields averaging 8.8 tons per hectare, according to Qingdao Saline-Alkali Tolerant Rice Research and Development Center.[14]

Lettuce, chard and chicory

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In a recent trial comparing three seawater and freshwater blends (i.e. 5%–10%–15% of seawater), some scientists found that lettuce productivity was negatively affected by 10% and 15% blends of seawater, whereas chard and chicory’s growth was not affected by any blend. Interestingly, water consumption dropped and WUE significantly increased in every tested crop accordingly with increased seawater concentrations. They concluded that certain amounts of seawater can be practically used in hydroponics, allowing freshwater savings and increasing concentrations of certain mineral nutrients.[15]

See also

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References

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  1. ^ Monica Nicks, 2014. Consider The Salt-Tolerant Potato. In: Modern Farmer. On line: [1]
  2. ^ Government of The Netherlands, 2017. Dutch saline agricultural knowledge brings breakthrough in food security. News item | 23-02-2017 | 12:13. On line: [2]
  3. ^ Salt Farm Texel, 2017. Crop salt tolerance brochure. On line
  4. ^ a b L. A. Richards, Editor, 1954, Diagnosis and Improvement of saline and alkali soil, Agriculture Handbook No. 60, USDA. [3]
  5. ^ Uwe Schleiff, Research for crop salt tolerance under brackish irrigation. On line: [4]
  6. ^ Maas EV, Hoffman GJ, 1977. Crop salt tolerance-current assessment. Journal of the Irrigation and Drainage Division, American Society of Civil Engineers 103: 115–134.
  7. ^ PennState Eberly College of Science. Piecewise Linear Regression Models. On line: [5]
  8. ^ Bernstein, L., Ayers, A.D. & Wadleigh, C.H. 1951. The salt tolerance of white rose potatoes. Am. Soc. Hort. Sci., 57: 231–236.
  9. ^ U.S. Salinity Laboratory, United States Department of Agriculture, Agricultural Research Service, Salt Tolerance of Fiber, Grain and Special Crops. On line: [6]
  10. ^ Edward P. Glenn, J. Jed Brown and James W. O’Leary, 1998, Irrigating Crops with Seawater. In: Scientific American, August 1998. On line: [7]
  11. ^ A. Rossiter, 1977. Scientists grow barley with seawater irrigation.. The Washington post. On line: [8]
  12. ^ Beach, Greg (October 25, 2017). "Chinese scientists created a type of rice that can grow in saltwater". inhabitat.com.
  13. ^ Kentish, Benjamin (October 24, 2017). "Chinese scientists may have just found a new way to feed 200 million people". The Independent.
  14. ^ Micu, Alexandru (2022-10-14). "A significant rice in productivity: China's output of GMO "seawater rice" doubled over the last 2 years". ZME Science. Retrieved 2022-10-31.
  15. ^ Atzori, G., Guidi Nissim W., Caparrotta S., Vignolini P., Masi E., Azzarello E.,Pandolfi C., Gonnelli C., Mancuso S. (2016). “Potential and constraints of different seawater and freshwater blends as growing media for three vegetable crops”, Agricultural Water Management, 176: 255-262 https://doi.org/10.1016/j.agwat.2016.06.016