PRACA ORYGINALNA
Land extension analysis for irrigated paddy fields using GIS-based multi-criteria and legacy land data: A case study of the West Sumatra, Indonesia
1
Faculty of Agriculture / Department of Soil Science and Land Resources, Universitas Andalas, Indonesia
2
Department of Plantation, State Polytechnic of Sriwijaya, Indonesia
3
Faculty of Agriculture / Department of Soil Science and Land Resources,, Universitas Andalas, Indonesia
Data nadesłania: 08-09-2022
Data ostatniej rewizji: 23-02-2025
Data akceptacji: 04-04-2025
Data publikacji online: 04-04-2025
Data publikacji: 04-04-2025
Autor do korespondencji
Zuldadan Naspendra
Faculty of Agriculture / Department of Soil Science and Land Resources, Universitas Andalas, Kampus Unand Limau Manis, 25163, Padang, Indonesia
Faculty of Agriculture / Department of Soil Science and Land Resources, Universitas Andalas, Kampus Unand Limau Manis, 25163, Padang, Indonesia
Soil Sci. Ann., 2025, 76(1)203709
SŁOWA KLUCZOWE
STRESZCZENIE
The demand for food is constantly increasing and becoming a problem in many parts of the world. Therefore, land resources must be optimally utilised to meet food needs and strengthen long-term food security. This research aimed to a) assess land suitability for irrigated paddy using GIS-based multi-criteria and analysing old land data and b) identify priority areas for the expansion of irrigated paddy in West Sumatra. The first phase of this research began with the creation of a geodatabase using GIS-based multi-criteria and old land data. Land suitability was analysed using the matching method. In addition, priorities for land expansion were evaluated based on land suitability, legal status of land, and existing land use. The results showed that 23% of the area in West Sumatra was suitable for irrigated paddy fields (827,065.5 ha). The suitability class consisted of an S2 class of 671,636.4 ha and an S3 class of 155,429.1 ha. The primary priority (P1) for the expansion of new paddy fields is 491,155.2 ha spread over 138,470.6 ha in Pasaman Barat, 99,713.7 ha in Dharmasraya and 57,892.2 ha in Pesisir Selatan. The second most important area (P2) in the area of convertible production forest (HPK) can be developed in Dharmasraya 14,951.0 ha, Pesisir Selatan 9,880.2 ha and Solok Selatan 7,078.2 ha. The limiting factors for suitability are mainly caused by slope factors and root media, such as poor drainage, coarse texture, and shallow soil depth.
REFERENCJE (54)
1.
Aflizar, Saidi, A., Indra, R., Somura, H., Wakatsuki, T., Masunaga, T., 2010. Soil erosion characterization in an agricultural watershed in West Sumatra, Indonesia. Tropics 19(1), 29–42. https://doi.org/10.3759/tropic....
2.
Akpoti, K., Kabo-bah, A.T Zwart, S.J., 2019. Agricultural land suitability analysis: State of the art and outlooks for integration of climate change analysis. Agricultural Systems 173, 172–208. https://doi.org/10.1016/j.agsy....
3.
BIG [Badan Informasi Geospasial - Geospatial Information Agency Indonesia]., 2023. Topography map of West Sumatera – Sheet of 0716, 0816, 0715, 0815, 0814, 0813 sheet, Sumatra. [Unpublihed data]. Bogor.
4.
BMKG [Badan Meteorologi, Klimatologi dan Geofisika – Meteorology, Climatology, and Geophysical Agency]., 2023. Data Kondisi Iklim Sumatera Barat – Climate data of West Sumatra. [Unpublihed Data]. Padang.
5.
BPS [Badan Pusat Statistik - Statistics Indonesia]., 2024a. Impor Beras Menurut Negara Asal Utama, 2017–2023 – Rice imports by Main Country of Origin 2017–2013. https://www.bps.go.id/id/stati....
6.
BPS [Badan Pusat Statistik - Statistics Indonesia]., 2024b. Luas Panen dan Produksi Padi di Indonesia 2023 – Harvesting Area and Rice Production in Indonesia 2023. https://www.bps.go.id/id/press....
7.
BPS [Badan Pusat Statistik –Statistics Indonesia]., 2020. Hasil Sensus Penduduk Indonesia Tahun 2020 – Indonesia Population Census in 2020. https://www.bps.go.id/news/202....
8.
BPS Sumatera Barat [Badan Pusat Statistik Sumatra Barat – Statistics of West Sumatra]., 2021. Luas Panen, Produksi, dan Produktivitas Padi Menurut Kabupaten/Kota Hasil Kerangka Sampel Area (KSA) – Harvesting Area, Production, and Productivity of Rice Based in City/Regency. https://sumbar.bps.go.id/indic....
9.
Braak, C., 1928. The climate of the Netherlands Indies. Proceedings of the Royal Magnetical and Meteorological Observatory. Batavia, 14, pp.192.
10.
Brown, A.E., Podger, G.M., Davidson, A.J., Dowling, T.I., Zhang, L., 2007. Predicting the impact of plantation forestry on water users at local and regional scales: An example for the Murrumbidgee River Basin, Australia. Forest Ecology and Management 251(1–2), 82–93. https://doi.org/10.1016/j.fore....
11.
Buol, S.W., Southard, R.J., Graham, R.C., McDaniel, P.A., 2011. Soil Genesis and Classification (6th Edition). John Wiley & Sons. Inc. West Sussex, UK.
12.
Buurman, P., Balsem, T., 1990. Land Unit Classification for the Reconnaissance Soil Survey of Sumatra. Centre for Soil and Agroclimate Research, Bogor.
13.
Canatoy, R.C., Jeong, S.T., Cho, S.R., Galgo, S.J.C., Kim, P.J., 2023. Importance of biochar as a key amendment to convert rice paddy into carbon negative. Science of The Total Environment 873, 162331. https://doi.org/10.1016/j.scit....
14.
Chen, D., Wei, W., Chen, L., 2017. Effects of terracing practices on water erosion control in China: A meta-analysis. Earth-Science Reviews 173, 109–121. https://doi.org/10.1016/j.ears....
15.
DBMCKTR [Dinas Dinas Bina Marga, Cipta Karya dan Tata Ruang] Sumatera Barat., 2023. Peta Tataguna Lahan Sumatera Barat – Map of the Legal Status of the Land of West Sumatra. [Unpublished data]. Padang.
16.
FAO., 1976. A Framevork for Land Evaluation, Soils Bulletin, 32. Food and Agriculture Organization of the United Nations. Rome, Italy. https://edepot.wur.nl/149437.
17.
FAO., 1985. Guidelines: Land Evaluation for Irrigated Agriculture - FAO soils bulletin 55. Rome, Italy. https://www.fao.org/4/x5648e/x....
18.
FAO., 2007. Land Evaluation – toward a revised framework. Rome. https://www.fao.org/fileadmin/....
19.
Goulart, R.Z., Reichert, J.M., Rodrigues, M.F., 2020. Cropping poorly-drained lowland soils: Alternatives to rice monoculture, their challenges and management strategies. Agricultural Systems 177, 102715. https://doi.org/10.1016/j.agsy....
20.
Hardjowigeno, S., Widiatmaka., 2007. Evaluasi Kesesuaian Lahan dan Perencanaan Tataguna Lahan – Land Suitability and Land Use Planning. Gajah Mada University Press, Yogyakarta. https://repository.ipb.ac.id/h....
21.
Ishfaq, M., Farooq, M., Zulfiqar, U., Hussain, S., Akbar, N., Nawaz, A., Anjum, S.A., 2020. Alternate wetting and drying: A water-saving and ecofriendly rice production system. Agricultural Water Management 241, 106363. https://doi.org/10.1016/j.agwa....
22.
Jiang, M., Li, X., Xin, L., Tan, M., Zhang, W., 2023. Impacts of rice cropping system changes on paddy methane emissions in southern china. Land 12(2), 270. https://doi.org/10.3390/land12....
23.
Kirchhof, G., Priyono, S., Utomo, W.H., Adisarwanto, T., Dacanay, E.V., So, H.B., 2000. The effect of soil puddling on the soil physical properties and the growth of rice and post-rice crops. Soil and Tillage Research 56(1–2), 37–50. https://doi.org/10.1016/S0167-....
24.
Kompas., 2021. Kadis Ketahanan Pangan: Sumbar Masih Surplus Beras, Tak Butuh Impor. https://regional.kompas.com/re....
25.
Kukal SS, Aggarwal GC., 2002. Percolation losses of water in relation to puddling intensity and depth in a sandy loam rice (Oryza sativa) field. Agricultural Water Management 57, 49–59. https://doi.org/10.1016/S0378-....
26.
Lal, R., 2001. Soil degradation by erosion. Land Degradation & Development 12(6), 519–539. https://doi.org/10.1002/ldr.47....
27.
Lin, L., Zhang, Z.B., Janssen, M., Lennartz, B., 2013. Infiltration properties of paddy fields under intermittent irrigation. Paddy and Water Environment 12, 17–24. https://doi.org/10.1007/s10333....
28.
LP2B [Lahan Pertanian Pangan Berkelanjutan] Sumatera Barat., 2019. Basis data Lahan Pertanian Pangan Berkelanjutan Provinsi Sumatera Barat - Map of sustainable Food Area in 2019. [Unpublished Data]. Litbang Provinsi Sumatera Barat.
29.
Mayr, T., Rivas-Casando, M., Bellmy, P., Palmer, R., Zaawadzka, J., 2010. Two methods for using legacy data in soil mappring. [In:] Boettinger, J., Howell, DW., Moore, AC., Hartemink., AE., Brown, SK. (Eds.), Digital soil mapping - bridging research, environmental application, and operation. Progress in Soil Science 2. Springer. https://doi.org/10.1007/978-90....
30.
Minai, J.O., Schulze, D.G., Libohova, Z., 2022. Renewal of archival legacy soil data: A case study of the Busia Area, Kenya. Frontiers in Soil Science 1, 765248. https://doi.org/10.3389/fsoil.....
31.
Oldeman, L. R., Suardi, D., 1977. Climatic determinants in relation to cropping patterns. Proceeding of Symposium on Cropping Systems Research and Development for the Asian Farmer 61–81. The International Rice Research Institute, Los Baños, Philippines. http://books.irri.org/97110404....
32.
Orhan, O., 2021. Land suitability determination for citrus cultivation using a GIS-based multi-criteria analysis in Mersin, Turkey. Computers and Electronics in Agriculture 190, 106433. https://doi.org/10.1016/j.comp....
33.
Puslittanak [Pusat Penelitian Tanah dan Agroklimat]., 1990. Land unit and Soil Map of the 0716, 0816, 0715, 0815, 0814, 0813 sheet, Sumatra. Centre for Soils and Agroclimate Research, Bogor.
34.
Rath, S. S., Panda, J., Annadurai, R., Nanda, S., 2018. A study on land suitability for rice cultivation in Khordha District of Odisha (India) using remote sensing and GIS. Earth Systems and Environment 2, 119–132. https://doi.org/10.1007/s41748....
35.
Ritung, S., Nugroho K, Mulyani A, Suryani E., 2011. Petunjuk Teknis Evaluasi Lahan Untuk Komoditas Pertanian (Edisi Revisi). Indonesian Center for Agricultural Land Resources Research and Development (ICALRD), Bogor. https://bbsdlp.litbang.pertani....
36.
Soebandiono, S., Muhibuddin, A., Purwanto, E., Purnomo, D., 2021. The effect of indigenous organic fertilizer on paddy field methane emissions. Organic Agriculture 11, 393–407. https://doi.org/10.1007/s13165....
37.
Soil Science Division Staff., 2017. Soil Survey Manual. United States Department of Agriculture. https://www.nrcs.usda.gov/site....
38.
Storie, R., 1978. Storie Index Soil Rating. Special Publication 3203. Division of Agricultural Sciences, University of California, Oakland.
39.
Subiksa, I.G.M., Hartatik, W., Agus, F., 2011. Pengelolaan Lahan Gambut secara Berkelanjutan. [In:] Nurida, N.L., Mulyani, M., Agus, M. (Eds), Pengelolaan Lahan Gambut Berkelanjutan. Indonesian Soil Research Institute, Indonesian Center for Agricultural Land Resources Research and Development, 73–88. https://repository.pertanian.g....
40.
Sulaeman, Y., Minasny, B., McBratney, A., Sarwani, M., Sutandi, A., 2013. Harmonizing legacy soil data for digital soil mapping in Indonesia. Geoderma 192, 77–85. https://doi.org/10.1016/j.geod....
41.
Suriadikarta, D.A., 2009. Pembelajaran dari kegagalan penanganan kawasan PLG Sejuta Hektar menuju pengelolaan lahan gambut berkelanjutan. Badan Penelitian dan Pengembangan Pertanian. https://repository.pertanian.g....
42.
Sys, C., Van Ranst, E., Debaveye, J., 1991. Land evaluation. Part 1: Principles in land evaluation and crop production calculations. Agricultural publications 7.1, General Administration of Development Cooperation of Belgium, Brussels. https://edepot.wur.nl/494365.
43.
Sys, C., Van Ranst, E., Debaveye, J., Beernaert. F., 1993. Land Evaluation. Part III: crop requirements. Agricultural Publications 7, 1–191. GADC, Brussels, Belgium. https://www.researchgate.net/p....
44.
Tanaka, A., Saito, K., Azoma, K., Kobayashi, K., 2013. Factors affecting variation in farm yields of irrigated lowland rice in southern-central Benin. European Journal of Agronomy 44, 46–53. https://doi.org/10.1016/j.eja.....
45.
Tashayo, B., Honarbakhsh, A., Akbari, M., Eftekhari, M., 2020. Land suitability assessment for maize farming using a GIS-AHP method for a semi- arid region, Iran. Journal of the Saudi Society of Agricultural Sciences 19 (5), 332–338. https://doi.org/10.1016/j.jssa....
46.
The Government of the Republic of Indonesia., 2012. Peraturan Pemerintah (PP) No 30 tentang Pembiayaan Perlindungan Lahan Pertanian Pangan Berkelanjutan. https://peraturan.bpk.go.id/Ho....
47.
The House of Representatives of the Republic of Indonesia., 2009. Undang-Undang No 41 tentang Perlindungan Lahan Pertanian Pangan Berkelanjutan. https://www.dpr.go.id/dokjdih/....
48.
The Minister of Agriculture of the Republic of Indonesia., 1980. Keputusan Menteri Pertanian (Kepmentan) No 837 tentang Kriteria dan Tata Cara Penetapan Hutan Lindung. https://mrbudisantoso.files.wo....
49.
The Minister of Agriculture of the Republic of Indonesia., 1981. Keputusan Menteri Pertanian (Kepmentan) No 683 tentang Kriteria dan Tata Cara Penetapan Hutan Produksi. https://mrbudisantoso.files.wo....
50.
The Minister of Forestry of the Republic of Indonesia., 2014. Permenhut No 647 tentang Perubahan Ketiga Atas Peraturan Menteri Kehutanan Nomor P.33/MENHUT-II/2020 tentang Tata Cara Pelepasan Kawasan Hutan Produksi yang dapat Dikonversi. https://peraturan.go.id/common....
51.
Tirtalistyani, R., Murtiningrum, M.,Kanwar, R.S., 2022. Indonesia rice irrigation system: Time for innovation. Sustainability 14(19), 12477. https://doi.org/10.3390/su1419....
52.
Wibawa, W., 2022. Preferensi konsumen menentukan tingkat adopsi petani terhadap varietas Padi di Provinsi Sumatera Barat. Jurnal Pembangunan Nagari 7(2), 146– 160. https://doi.org/10.30559/jpn.v....
53.
Yagi, K., Tsuruta, H., Kanda, K.I., Minami, K., 1996. Effect of water management on methane emission from a Japanese rice paddy field: Automated methane monitoring. Global Biogeochemical Cycles 10(2), 255–267. https://doi.org/10.1029/96GB00....
54.
Yang J, Guan X, Luo M, Wang T., 2022. Cross-system legacy data applied to digital soil mapping: A case study of Second National Soil Survey data in China. Geoderma Regional 28, e00489. https://doi.org/10.1016/j.geod....
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