Research article

The sustainability of the muang fai irrigation system of northern Thailand

  • Received: 22 November 2018 Accepted: 07 March 2019 Published: 19 March 2019
  • The research was designed to understand the factors that have sustained the use of a seven-hundred-year-old irrigation system (muang fai) in northern Thailand, despite the challenge of a new technology: pumping irrigation water from underground. There were two main objectives. The first was to assess whether the muang fai system is sustainable. The second was to determine the contribution of the muang fai to the groundwater sustainability in the study region. This second objective is related to the United Nationos Sustainable Development Goal 6 (SDG6), water security. The results show that membership of the muang fai is changing slowly and the system is inherently stable, even given various pressures that tend to work against it, such as the increasing average farm size. Also, although the muang fai conserves water relative to other forms of irrigation, there is adequate recharge in the majority of the region to render this contribution to sustainability of the watershed relatively small.

    Citation: Arriya Mungsunti, Kevin A. Parton. The sustainability of the muang fai irrigation system of northern Thailand[J]. AIMS Environmental Science, 2019, 6(2): 77-93. doi: 10.3934/environsci.2019.2.77

    Related Papers:

  • The research was designed to understand the factors that have sustained the use of a seven-hundred-year-old irrigation system (muang fai) in northern Thailand, despite the challenge of a new technology: pumping irrigation water from underground. There were two main objectives. The first was to assess whether the muang fai system is sustainable. The second was to determine the contribution of the muang fai to the groundwater sustainability in the study region. This second objective is related to the United Nationos Sustainable Development Goal 6 (SDG6), water security. The results show that membership of the muang fai is changing slowly and the system is inherently stable, even given various pressures that tend to work against it, such as the increasing average farm size. Also, although the muang fai conserves water relative to other forms of irrigation, there is adequate recharge in the majority of the region to render this contribution to sustainability of the watershed relatively small.


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    [1] Mungsunti A, Parton K (2017) Estimating the economic and environmental benefits of a traditional communal water irrigation system: The case of muang fai in Northern Thailand. Agric Water Manage 179: 366–377.
    [2] United Nations (UN) (2016) Sustainable Development Goal 6: Ensure availability and sustainable management of water and sanitation for all. Available from: https://sustainabledevelopment.un.org/sdg6#targets
    [3] Zhou S, Herzfeld T, Glauben T, et al. (2008) Factors Affecting Chinese Farmers' Decisions to Adopt a Water-Saving Technology. Can J Agric Econ 56: 51–61.
    [4] Ounvachit T (2011) Equal water sharing in scarcity conditions: the case of Chaisombat Muang Fai Irrigation System in Thailand. Paddy and Water Environment 9: 325–332.
    [5] Alley W, Leake S (2004) The Journey from Safe Yield to Sustainability. Groundwater 42: 12–16.
    [6] Gleeson T, Alley W, Allen D, et al. (2012) Towards Sustainable Groundwater Use: Setting Long-term Goals, Backcasting, and Managing Adaptively. Groundwater 50: 19–26.
    [7] Maimone M (2004) Defining and Managing Sustainable Yield. Groundwater 42: 809–814.
    [8] Zhou Y (2009) A Critical Review of Groundwater Budget Myth, Safe Yield and Sustainability. J. Hydrol. 370: 207–213.
    [9] Alley W, Reilly T, Franke O (1999) Sustainability of Ground-Water Resources. US Geological Survey Circular 1186. Denver. Available from: https://pubs.usgs.gov/circ/circ1186.
    [10] Ortigara, A R C, Kay, M, Uhlenbrook S (2018) A Review of the SDG6 Synthesis Report 2018 from an Education, Training, and Research Perspective. Water 10: 1353. Available from: https://www.mdpi.com/2073-4441/10/10/1353
    [11] World Commission on Environment and Development (1987) Our Common Future. New York: Oxford University Press.
    [12] Loucks D, Gladwell J (1999) Sustainability Criteria for Water Resource Systems. Cambridge: Cambridge University Press.
    [13] Ashraf B, AghaKouchak A, Alizadeh A, et al. (2017) Quantifying Anthropogenic Stress on Groundwater Resources. Sci Rep 7: 12910.
    [14] Surareks V (1986) Historical Development and Management of Irrigation System in Northern Thailand. Bangkok: Chareonwit Printing.
    [15] Wichienkiew A, Sattayawattana C, Panitchayakul P, et al. (2003) Water Resource Management: Muang Fai Tradition. In: Jammarik S, Sattayawattana C, editors. Local Community Right of Original Indegenous Lanna: Case Study of Lua, Lou, Pakakayor (Karen) Communities in Nan, Chiang Rai, and Chiang Mai Provinces. Bangkok: Nititham. pp. 120–130.
    [16] Ounvichit T, Wattayu S, Masayoshi S (2008) Participatory Management Structure of Large-Scale People's Irrigation System: The Case of the Soprong Muang Fai System, Northern Thailand. Southeast Asian Studies 46: 145–162.
    [17] Na-Tarang E (2001) Local Knowledge of Lanna. Bangkok: Ammarin Printing and Publishing.
    [18] Falvey L (2001) Sustainable Technologies in Thai Agriculture. ATSE Focus 115: 53.
    [19] Lertwicha P, Wichienchai A (2003) Village Community of Mae Karn River Basin. Bangkok: Tarn Punya Education.
    [20] Surareks V (2006) Muang Fai Communities in Northern Thailand: People's Experiences and Wisdom in Irrigation Management. J Dev Sustain Pract 1: 44–52.
    [21] Surareks V (1998) The Muang Fai Irrigation System of Northern Thailand: Historical Development and Management. Tai Culture 3: 37–48.
    [22] Margane A, Tatong T (1999) Aspects of Hydrogeology of the Chaing Mai-Lamphun Basin, Thailand that are important for Groundwater Management. Zeitschrift fuer Angevandte Geologie 45: 188–197.
    [23] RID (2003) Royal Irrigation Department Database. Chiang Mai: RID.
    [24] Chiang Mai Provincial Office (2010) Chiang Mai Provincial Population Report. Chiang Mai: Chiang Mai Provincial Office.
    [25] Leng G, Huang M, Tang Q, et al. (2014) Modeling the Effects of Groundwater-Fed Irrigation on Terrestrial Hydrology over the Conterminous United States. J Hydrometeorol 15: 957–972.
    [26] Koch M, Arlai P, Lukjan A (2012) Modeling Investigation on the future Permissible Yield in upper Chiang Rai Aquifers System. Procedia Eng 32: 69–76.
    [27] Department of Groundwater Resources (2009) Groundwater Resources Assessment in the Kok River Basin. Bangkok: Thai Government.
    [28] IEconomics.com (2017) Thailand–GDP from Agriculture. Available from: https://ieconomics.com/thailand-gdp-from-agriculture.
    [29] Win H (2017) Analysis of Tropical Fruits in Thailand. Available from: http://ap.fftc.agnet.org/ap_db.php?id=818.
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  • © 2019 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)
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