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Items: 6

1.

Intermittency of water vapor fluxes from vineyards during light wind and convective conditions.

Los SA, Hipps LE, Alfieri JG, Kustas WP, Prueger JH.

Irrig Sci. 2019;1:1-15. doi: 10.1007/s00271-018-0617-5. Epub 2019 Jan 8.

PMID:
31031515
2.

Microwave implementation of two-source energy balance approach for estimating evapotranspiration.

Holmes TR, Hain C, Crow WT, Anderson MC, Kustas WP.

Hydrol Earth Syst Sci. 2018;22(2):1351-1369. doi: 10.5194/hess-22-1351-2018. Epub 2018 Feb 23.

3.

Assessment of different methods for shadow detection in high-resolution optical imagery and evaluation of shadow impact on calculation of NDVI, and evapotranspiration.

Aboutalebi M, Torres-Rua AF, Kustas WP, Nieto H, Coopmans C, McKee M.

Irrig Sci. 2018;1:1-23. doi: 10.1007/s00271-018-0613-9. Epub 2018 Dec 3.

PMID:
31031514
4.

Comparison of field-scale herbicide runoff and volatilization losses: an eight-year field investigation.

Gish TJ, Prueger JH, Daughtry CS, Kustas WP, McKee LG, Russ AL, Hatfield JL.

J Environ Qual. 2011 Sep-Oct;40(5):1432-42. doi: 10.2134/jeq2010.0092.

PMID:
21869505
5.

Soil moisture and metolachlor volatilization observations over three years.

Gish TJ, Prueger JH, Kustas WP, Daughtry CS, McKee LG, Russ A, Hatfield JL.

J Environ Qual. 2009 Jul 23;38(5):1785-95. doi: 10.2134/jeq2008.0276. Print 2009 Sep-Oct.

PMID:
19643743
6.

Solar radiation, relative humidity, and soil water effects on metolachlor volatilization.

Prueger JH, Gish TJ, McConnell LL, Mckee LG, Hatfield JL, Kustas WP.

Environ Sci Technol. 2005 Jul 15;39(14):5219-26.

PMID:
16082950

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