Community Based Adaptation To Climate Change And Social Economic In Xe Champhone Wetland, Champhone District, Savannakhet Province

Phoummixay siharath; Somchay Vilaychaleun; Khampasith Thammathevo; Keophousone Phonhalath; Soulyphan Kannitha; Chankhachone Sonemanivong; Keoduangchai Keokhamphui; Phaiphana Siharath

doi:10.58471/esaprom.v3i02.4408

Authors

Phoummixay siharath Faculty of Engineering, National University of Laos
Somchay Vilaychaleun Faculty of Engineering, National University of Laos
Khampasith Thammathevo Faculty of Engineering, National University of Laos
Keophousone Phonhalath Faculty of Engineering, National University of Laos
Soulyphan Kannitha Faculty of Engineering, National University of Laos
Chankhachone Sonemanivong Faculty of Engineering, National University of Laos
Keoduangchai Keokhamphui Faculty of Water Resources, National University of Laos
Phaiphana Siharath Faculty of Engineering, National University of Laos

DOI:

https://doi.org/10.58471/esaprom.v3i02.4408

Keywords:

adaptation, community, climate change, resilience, wetland

Abstract

Climate change is key significant factor that impacts on multi-dimensions, which is relevant to social economic development, livelihood and environment, hence, Community Based Adaptation (CBA) to climate change is a mechanism of adapting based on the existing practices, knowledge, policy and experiences of the rice farmers to sustain their lives on changing climate, the objective of the study is to assess the social economic and find the practice management of rice farmers to adapt during flood and drought seasons. Hence, according to the research finds that, majority of the rice farmers are experienced and learnt from the previous effect and adjust themselves by using knowledge skills, experiences to build the resilience for their rice and crop planting in order to prevent and avoid the damages from climate change within the wetland. Besides that, the local communities still utilize the existing potential natural based adaptation to be flexible sustainably their agricultural activities and livelihood during rainy and dry season

References

Baig, S. P. et al. (2016). Cost and benefits of ecosystem based adaptation: the case of the Philippines. 32.

Balehegn, M. et al. (2019). Ecosystem-based adaptation in Tigray, northern Ethiopia: a systematic review of interventions, impacts, and challenges. 1-45.

Berkes, F. J. C. b. (2004). Rethinking community‐based conservation. 18(3), 621-630.

Boutsamaly, S. et al. (2023). Spatial analysis of flash flood and Drought impact from Climate Change in Phongsaly District, Phogsaly Province, by using Geo-Informatics Technology and Modelling. doi:https://doi.org/10.56556/gssr.v2i3.515

Bronen, R. (2015). Climate-induced community relocations using integrated social-ecological assessments to foster adaptation and resilience. Ecology and Society, 20(3).

Cha, Y. et al. (2024). Place-Based Adaptation through Network Governance. 16(5), 2155.

Chen, H. et al. (2018). Climate change and anthropogenic impacts on wetland and agriculture in the Songnen and Sanjiang Plain, Northeast China. 10(3), 356.

Clarke, T. et al. (2019). Community-based adaptation to climate change: lessons from Tanna Island, Vanuatu. 14(1), 59-80.

Danraka, M. M. et al. (2024). COMMUNITY-BASED ADAPTATION TO FLOOD: A SYSTEMATIC LITERATURE REVIEW. 11(1), 251-278.

Desta, H. et al. (2012). Aspects of climate change and its associated impacts on wetland ecosystem functions: A review. 8(10), 582-596.

Donatti, C. I. et al. (2020). Indicators to measure the climate change adaptation outcomes of ecosystem-based adaptation. Climatic Change, 158(3), 413-433. doi:10.1007/s10584-019-02565-9

Dong, L.-Q. &Zhang, G.-X. J. A. i. W. S. (2011). Review of the impacts of climate change on wetland ecohydrology. 22(3), 429-436.

Grantham, H. S. et al. (2011). Ecosystem-based adaptation in marine ecosystems of tropical Oceania in response to climate change. 17(3), 241-258.

Hale, L. Z. et al. (2009). Ecosystem-based adaptation in marine and coastal ecosystems. 25(4), 21-28.

Johnson, W. C. et al. (2005). Vulnerability of northern prairie wetlands to climate change. 55(10), 863-872.

Keskitalo, E. C. H. &Kulyasova, A. A. J. P. R. (2009). The role of governance in community adaptation to climate change. 28(1), 60-70.

Krittasudthacheewa, C. et al. (2019). Development and Climate Change in the Mekong Region.

Lacombe, G. et al. (2017). Climate Change Adaptation in Wetlands Areas (CAWA).

Lebel, L. et al. (2023). COVID-19 and household water insecurities in vulnerable communities in the Mekong Region. Environment, Development and Sustainability, 25(4), 3503-3522. doi:https://doi.org/10.1007/s10668-022-02182-0

Leh, M. et al. (2020). Erosion Study of the Xe Champhone Wetlands.

Lloréns, J. L. P. J. W. s. (2008). Impacts of climate change on wetland ecosystems. 7(2.117), 8.

Mekaoussi, H. et al. (2023). Predicting biochemical oxygen demand in wastewater treatment plant using advance extreme learning machine optimized by Bat algorithm. 9(11).

Meynell, P.-J. J. T. w. b. (2017). Wetlands of the Mekong River basin, an overview. 1-22.

Nandy, P. &Ahammad, R. J. S. l. o. m. r. (2012). Navigating mangrove resilience through the ecosystem-based adaptation approach: lessons from Bangladesh. 1, 243-254.

Osuman, K. (2019). Assessment of level of Public Knowledge, attitudes and Perception towards Mangrove Forest conservation in Mesurado Wetland in Liberia. University of Nairobi,

Poudel, S. et al. (2021). Assessment of Factors Affecting Willingness To Pay/Accept: A Study From Begnas Watershed, Nepal. 10(2), 1-15.

Province, S. &Lao, P. (2011). Baseline Report.

Rajendran, M. &Thivyatharsan, R. (2013). Community Based Adaptation and Mitigation Strategies in Relation to Water and Crop Management in Batticaloa District.

Reid, H. (2011). Improving the evidence for ecosystem-based adaptation. United Kingdom: ; International Institute for Environment and Development (IIED), London (United Kingdom).

Rizvi, A. R. et al. (2015). Ecosystems based adaptation: knowledge gaps in making an economic case for investing in nature based solutions for climate change. 48.

Roberts, D. et al. (2012). Exploring ecosystem-based adaptation in Durban, South Africa:“learning-by-doing” at the local government coal face. 24(1), 167-195.

Shindell, D. T. et al. (2004). Impacts of climate change on methane emissions from wetlands. 31(21).

Siharath, P. et al. (2023). Lead and Zinc Groundwater Contaminant Transport Modelling Using MT3DMS in Xaysomboun Province, Lao PDR. 1(2), 208-228. doi:https://doi.org/10.58578/ajstea.v1i2.1934

Sonemanivong, C. et al. (2023). Reservoir Enlargement and Energy Production Comparison of Dry, Normal and Wet Year at Nam Sana1 Hydro Power Plant Kasy District, Vientiane Province. 2(2), 47-58. doi:https://doi.org/10.55927/ajns.v2i2.4039

Taillardat, P. et al. (2020). Climate change mitigation potential of wetlands and the cost-effectiveness of their restoration. 10(5), 20190129.

Wamsler, C. et al. (2016). Operationalizing ecosystem-based adaptation: harnessing ecosystem services to buffer communities against climate change. 21(1).

Wamsler, C. J. E. &society. (2015). Mainstreaming ecosystem-based adaptation: transformation toward sustainability in urban governance and planning. 20(2).

Woroniecki, S. et al. (2019). The promises and pitfalls of ecosystem-based adaptation to climate change as a vehicle for social empowerment. 24(2).

Xaiveeheuang, T. et al. (2023). An Assessment the Financial Performance of Muangkhay Water Supply System in Luang Prabang Capital, Luang Prabang Province. 5(1), 83-89. doi:https://doi.org/10.15864/jmscm.5105