Enhancing water productivity in sugarcane cultivation by integrating basal crop coefficient with deficit irrigation

Issued Date

2026-08-01

Resource Type

Article

ISSN

03783774

eISSN

18732283

DOI

10.1016/j.agwat.2026.110529

Scopus ID

2-s2.0-105041314029

Journal Title

Agricultural Water Management

Volume

333

Rights Holder(s)

SCOPUS

Bibliographic Citation

Agricultural Water Management Vol.333 (2026)

Suggested Citation

Malee C., Phattaralerphong J., Kositsakulchai E., Rattanasakphakdee S., Luepromchai E., Kachenchart B. Enhancing water productivity in sugarcane cultivation by integrating basal crop coefficient with deficit irrigation. Agricultural Water Management Vol.333 (2026). doi:10.1016/j.agwat.2026.110529 Retrieved from: https://repository.li.mahidol.ac.th/handle/123456789/117363

Title

Enhancing water productivity in sugarcane cultivation by integrating basal crop coefficient with deficit irrigation

Author(s)

Malee C.
 Phattaralerphong J.
 Kositsakulchai E.
 Rattanasakphakdee S.
 Luepromchai E.
 Kachenchart B.

Author's Affiliation

Chulalongkorn University
 Kasetsart University, Kamphaeng Saen Campus
 Kasetsart University, Chalermphrakiat Sakon Nakhon Province Campus
 Faculty of Environment and Resource Studies, Mahidol University
 Kaset Thai International Sugar Corporation Public Company Limited (KTIS)

Corresponding Author(s)

Malee C.

Other Contributor(s)

Mahidol University

Abstract

Water productivity (WP) is a critical factor for sustainable agriculture, particularly in water-scarce regions. This study integrated locally calibrated, cultivar-specific basal crop coefficients (K<inf>cb</inf>) to apply deficit irrigation strategies for optimizing irrigation management and enhancing WP in sugarcane cultivation. Field experiments with a commercial sugarcane variety (Khon Kaen 3, KK3) were conducted in two weighing lysimeters to assess actual evapotranspiration (ET<inf>a</inf>), crop yield, and WP over two growing seasons in central Thailand. The first lysimeter cultivated sugarcane under full irrigation (FI), managed near field capacity to establish a standard non-stress condition, while the second lysimeter used a 50% management allowed depletion (50% MAD) deficit strategy. The SIMDualKc model used the field data to derive K<inf>cb</inf> values for the local KK3 cultivar, ensuring that the coefficients reflected cultivar-specific physiological traits and Central Thailand's Tropical Savanna (Aw) climate while aligned with the FAO-56 K<inf>cb</inf> framework. The calibrated K<inf>cb</inf> values reflected the crop's phenological water demands and were 0.15, 1.11 and 0.49 for initial growth, mid-season and late-season stages, respectively. The AquaCrop model was then configured with the calibrated K<inf>cb</inf> values, validated against lysimeter and secondary regional yield data, and employed to predict yields, crop evapotranspiration, WP, and irrigation frequencies under various irrigation scenarios. The simulated results revealed that the moderate deficit irrigation regimes (25% and 50% MAD) significantly reduced crop water use while maintaining competitive sugarcane yields. In contrast, the rainfed system demonstrated yield losses due to rainfall variability. The findings provide a sustainable framework for supporting adaptive irrigation practices.

Keyword(s)

Earth and Planetary Sciences
 Environmental Science
 Agricultural and Biological Sciences

Availability

URI

https://repository.li.mahidol.ac.th/handle/123456789/117363

Collections

Scopus 2026