Water Deficit Effects on Transpiration and Leaf Growth<sup>1</sup>

Rosenthal, W. D.; Arkin, G. F.; Shouse, P. J.; Jordan, W. R.

doi:10.2134/agronj1987.00021962007900060014x

Cited by 90 publications

(65 citation statements)

References 7 publications

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“…Further work is required to determine the dependence of a on pasture and soil types. If a can be successfully related to pasture species, this may provide a means to study the relative response of alternative pasture species to drought conditions (Parry et al 1992), as plant stress is closely related to ^£7 (McAneney et al 1982;McAneney & Judd 1983;Parfitt et al 1985aParfitt et al , 1985bRosenthal et al 1987;Barker et al 1989;Sadras & Milroy 1996). This would then allow a practical model of plant growth response to water stress to be formulated.…”

Section: Resultsmentioning

confidence: 99%

A practical model for predicting soil water deficit in New Zealand pastures

Woodward¹,

Barker

Zyskowski

2001

New Zealand Journal of Agricultural Research

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Soil water is the single most important resource for pasture and crop production in New Zealand farms. Because soil water is difficult to measure, however, the ability to predict soil water status from daily weather data is valuable, and has application for on-farm irrigation, stocking, and supplementation decisions. In this paper a practical water balance model is presented. The model uses daily rainfall and potential evapotranspiration (PET) estimates to predict changes in the water content in two overlapping soil zones: a rapidly recharged (and depleted) zone of unspecified depth, and the total plant rooting zone. The use of two zones improves predictions of actual evapotranspiration and plant stress compared with models that use only one zone. An important factor determining the success of soil water models is the ability to predict actual evapotranspiration, AET. In this model actual evapotranspiration, AET, is calculated as the lesser A00039 Received 4 August 2000; accepted II December 2000of potential evapotranspiration, PET, and total readily available water (RAW) per day. RAW is defined as all of the water in the rapidly recharged surface zone plus a proportion of the water in the remainder of the soil profile. By validation against 11 historical data sets, the model is shown to give accurate predictions of soil water deficit across a range of New Zealand flat-land pastoral soils. The model parameters can be easily estimated from commonly available soil properties (soil order classification, and available water holding capacity) without the need for additional site-specific calibration. This model provides an easily used, practical decision tool for the management of drought, allowing early prediction of decline in pasture growth and estimates of required irrigation.

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Section: Resultsmentioning

confidence: 99%

A practical model for predicting soil water deficit in New Zealand pastures

Woodward¹,

Barker

Zyskowski

2001

New Zealand Journal of Agricultural Research

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“…They showed that the relationship between SPI and NDVI can be explained with a linear relationship as long as the seasonality is taken into account, for example, by conducting correlation analyses individually for each month of the year. Because the relationship between precipitation and vegetation development differs between plant species (Rosenthal et al, 1987), the analyses were conducted separately for different land uses. First, the average SPEI, SPI and NDVI values of all pixels in each land use were determined for each month.…”

Section: Time Series Of Spei Spi and Ndvimentioning

confidence: 99%

Addressing drought conditions under current and future climates in the Jordan River region

Törnros

Menzel

2014

Hydrol. Earth Syst. Sci.

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Abstract. The Standardized Precipitation-Evaporation Index (SPEI) was applied in order to address the drought conditions under current and future climates in the Jordan River region located in the southeastern Mediterranean area. In the first step, the SPEI was derived from spatially interpolated monthly precipitation and temperature data at multiple timescales: accumulated precipitation and monthly mean temperature were considered over a number of timescalesfor example 1, 3, and 6 months. To investigate the performance of the drought index, correlation analyses were conducted with simulated soil moisture and the Normalized Difference Vegetation Index (NDVI) obtained from remote sensing. A comparison with the Standardized Precipitation Index (SPI), i.e., a drought index that does not incorporate temperature, was also conducted. The results show that the 6-month SPEI has the highest correlation with simulated soil moisture and best explains the interannual variation of the monthly NDVI. Hence, a timescale of 6 months is the most appropriate when addressing vegetation growth in the semiarid region. In the second step, the 6-month SPEI was derived from three climate projections based on the Intergovernmental Panel on Climate Change emission scenario A1B. When comparing the period 2031-2060 with 1961-1990, it is shown that the percentage of time with moderate, severe and extreme drought conditions is projected to increase strongly. To address the impact of drought on the agricultural sector, the irrigation water demand during certain drought years was thereafter simulated with a hydrological model on a spatial resolution of 1 km. A large increase in the demand for irrigation water was simulated, showing that the agricultural sector is expected to become even more vulnerable to drought in the future.

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“…Virtually all major processes contributing to crop yield including leaf gas exchange (Ritchie, Burnett & Henderson 1972;Ritchie 1973;Sinclair & Ludlow 1986;Kuppers, Kuppers & Schulze 1988), leaf growth (Sinclair 1986;Rosenthal et al . 1987;Lecoeur & Sinclair 1996;Muchow & Sinclair 1991) are inhibited late in stage I or in stage II of soil drying.…”

Section: Yield and Crop Water Usementioning

confidence: 99%

Osmolyte accumulation: can it really help increase crop yield under drought conditions?

Serraj

Sinclair

2002

Plant Cell & Environment

736

370

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Osmolyte accumulation (OA) is frequently cited as a key putative mechanism for increasing yields of crops subjected to drought conditions. The hypothesis is that OA results in a number of benefits that sustain cell and tissue activity under water-deficit conditions. It has been proposed as an effective tolerance mechanism for water deficits, which could be enhanced in crops by traditional plant breeding, marker-assisted selection or genetic engineering, to generate drought-tolerant crops. However, field studies examining the association between OA and crop yield have tended to show no consistent benefit. The few, often-cited, investigations with positive associations were obtained under severe water deficits with extremely low yields or conditions with special water-supply scenarios when much of the benefit is plant survival. Under conditions where water deficits threaten crop survival, yields are so low that even large fractional yield gains offer little practical benefit to growers. Indeed, the often-cited benefit of turgor maintenance in cells is likely to result in crop behaviour that is exactly opposite to what is beneficial to crops. The one clear mechanism identified in this review for beneficial yield responses to OA is in the maintenance of root development in order to reach water that may be available deeper in the soil profile.

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Water Deficit Effects on Transpiration and Leaf Growth¹

Cited by 90 publications

References 7 publications

A practical model for predicting soil water deficit in New Zealand pastures

A practical model for predicting soil water deficit in New Zealand pastures

Addressing drought conditions under current and future climates in the Jordan River region

Osmolyte accumulation: can it really help increase crop yield under drought conditions?

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Water Deficit Effects on Transpiration and Leaf Growth1

Cited by 90 publications

References 7 publications

A practical model for predicting soil water deficit in New Zealand pastures

A practical model for predicting soil water deficit in New Zealand pastures

Addressing drought conditions under current and future climates in the Jordan River region

Osmolyte accumulation: can it really help increase crop yield under drought conditions?

Contact Info

Product

Resources

About

Water Deficit Effects on Transpiration and Leaf Growth¹