PL EN
PRACA ORYGINALNA
Soil characteristics, revised soil classification, and soil geochemistry related to soil suitability of West Lampung tropical volcanic residual soil, Sumatra, Indonesia
 
Więcej
Ukryj
1
Faculty of Geological Engineering, Padjadjaran University, Indonesia
2
Research Center of Geotechnology, Indonesian Institute of Sciences, Indonesia
AUTOR DO KORESPONDENCJI
Prahara Iqbal   

Faculty of Geological Engineering, Padjadjaran University, Jl. Raya Bandung Sumedang KM.21, 45363, kabupaten SUmedang, Indonesia
Data nadesłania: 28-10-2020
Data ostatniej rewizji: 09-04-2021
Data akceptacji: 08-09-2021
Data publikacji online: 31-12-2021
Data publikacji: 31-12-2021
 
Soil Sci. Ann., 2021, 72(3)142032
 
SŁOWA KLUCZOWE
STRESZCZENIE
In the area of West Lampung, Sumatra, Indonesia, soil quality problems have occurred. They include landslides, erosion, and soil cracks due to the increased dry land agriculture (coffee-based farming), rice fields, and residential areas. Here we provide information about optimizing land use based on geological, geotechnical, and geochemical approaches. For optimization of land use we determined salinity, plasticity, and mineral content in the soil. The aims of this study are: 1) identifying soil characteristics and classification based on geological, geotechnical, RSCS, and soil activity approach. 2) identifying the minerals contained in the soil based on XRD analysis. 3) determine soil suitability based on soil characteristics. 4) to quantify the area that has certain soil suitability. The methods used are geological and geotechnical soil characterization (USCS and soil activity analyses), XRD analysis, and Revised Soil Classification Systems (RSCS) analysis. The results showed that the study area is composed of tropical volcanic residual soil: Andosol soil type. The soil has low to high plasticity and it is included in the inactive to active soil category. Based on their characteristics, the soils of the studied area are divided into two categories. The first category are soils with low plasticity characteristic, have LL brine value <50% (low to intermediate salt content), electrical sensitivity of 0.18 to 1.48; soils with the inactive soil category, and contain minerals: despujolsite, hematite, chlorite, montmorillonite (0.3% - 0.6%), and quartz (2.8% - 30.2%). This category will be suitable for agriculture purposes, building foundations, and earth construction. The first category occupies 65% of the study area. While the second category are soils with intermediate to high plasticity characteristics, have LL brine value >50% (intermediate to high salt content), electrical sensitivity of 0.38 to 1.10, soils with the normal to active soil category, and contain minerals: despujolsite, hematite, magnetite, illite, montmorillonite (0.4% - 0.9%), dickite, and quartz (2.50% - 17.90%). The second category occupies 35% of the study area was more ideal for the primary forest growth.
 
REFERENCJE (57)
1.
Abd-Elmabod, S.K., Bakr, N., Muñoz-Rojas, M., Pereira, P., Zhang, Z., Cerdà, A., Jordán, A., Mansour, H., De la Rosa, D., and Jones, L., 2019. Assessment of soil suitability for improvement of soil factors and agricultural management. Sustainability 11, 1588. https://doi.org/10.3390/su1106....
 
2.
Agriculture and Horticulture Development Board and British Beet Research Organisation. 2019. Principles of Soil Management. AHDB, 20 p.
 
3.
Ande, O.T., 2011. Soil suitability evaluation and management for cassava production in the Derived Savanna Area of Southwestern Nigeria. International Journal of Soil Science 6(2), 142-149. https://doi.org/10.3923/ijss.2....
 
4.
ASTM D422. 2007. Standard Test Method for Particle-Size Analysis of Soils. Astm, D422-63(Reapproved): 1–8. https://doi.org/West Conshohocken, PA.
 
5.
ASTM, International A. 2017. ASTM D4318 - 17e1 Standard Test Methods for Liquid Limit, Plastic Limit, and Plasticity Index of Soils.
 
6.
Astuti, J.W., 2016. Deteksi Perubahan Penggunaan Lahan di Kabupaten Lampung Barat. Thesis, Institut Pertanian Bogor, 66 p. (in Bahasa with English abstract).
 
7.
Bergaya, F., and Lagaly, G., 2013. General introduction: clays, clay minerals, and clay science. in Developments in Clay Science, 5, Elsevier, 1–19. https://doi.org/10.1016/S1572-....
 
8.
Brevik, E.C., 2013. The potential impact of climate change on soil properties and processes and corresponding influence on food security. Agriculture 3, 398–417. https://doi.org/10.3390/agricu....
 
9.
Bodaghabadi, M.B., Faskhodib, A.A., Salehic, M.H., Hosseinifardd, S.J., Heydari, M. 2019. Soil suitability analysis and evaluation of pistachio orchard farming, using canonical multivariate analysis. Scientia Horticulturae 246, 528–534. https://doi.org/10.1016/j.scie....
 
10.
Bowles, J. E., 2012. Engineering Properties of Soils and their Measurements. 4th edition, McGraw Hill Education (India) Private Limited, New Delhi.
 
11.
Casagrande, A., 1948. Classification and Identification of Soils. Transaction, ASCE, 113(1), 901-930.
 
12.
Chen, P.Y., Wang, M.K., Yang, D.S., 2001. Mineralogy of dickite and nacrite from northern Taiwan. Clays and Clay Minerals, 49(6), 586–595, https://doi.org/10.1346/CCMN.2....
 
13.
Chesworth, W. 2007. Encyclopedia of soil science. Springer Science & Business Media.
 
14.
Colombo N., D’Amico M., Freppaz M., Hudeck C., Pintaldi E., Stanchi S., Viglietti D., Zecca O., 2020. Guidelines for sustainable soil management. Links4Soils, 2020: Guidelines for sustainable soil management Digest: Agriculture. Links4Soils project publications. EU Interreg Alpine Space; Links4Soils project. ISBN 978-88-99108-19-9.
 
15.
Cornell, R.M., Schwertmann, U., 2003. The iron oxides: structure, properties, reactions, occurrences and uses. John Wiley & Sons.
 
16.
Danso, H., 2018. Suitability of soil for earth construction as building material. Adv Civil Eng Tech Journal, 2(3), 199-211. https://doi.org/10.31031/ACET.....
 
17.
Dariah, A., Agus, F., Arsyad, S., Sudarsono, Maswar, 2003. Relationship Between Soil Characteristics and Rate of Soil Loss on Coffee Base-Farming System at Sumberjaya, West Lampung. Indonesian Soil and Climate Journal, no. 21, 78-86, (in Bahasa with English abs.). https://doi.org/10.2017/jti.v0....
 
18.
Dariah, A., Agus, F., Arsyad, S., Sudarsono, Maswar, 2004. Erosion and surface runoff in coffee-based agricultural land in Sumberjaya, West Lampung. Agrivita, 26(1), 52-60, (in Bahasa with English abs.).
 
19.
Dariah, A., Agus, F., Maswar, 2005. Soil Quality of the Land under Coffee-Based Farming System (Case Study at Sumberjaya, West Lampung). Indonesian Soil and Climate Journal, no. 23, 48-57, (in Bahasa with English abs.). http://dx.doi.org/10.21082/jti....
 
20.
De Castro, J., Ballesteros, F., Méndez, A., and Tarquis, A.M.., 2014. Fractal analysis of Laplacian Pyramidal filters applied to segmentation of soil images. The Scientific World Journal, Article ID 212897, 13 pages. https://doi.org/10.1155/2014/2....
 
21.
Elsheikh, R., Shariff, A.R.B.M., Amiri, F., Ahmad, N.B., Balasundram, S.K., Soom, M.A.M., 2013. Agriculture Land Suitability Evaluator (ALSE): A decision and planning support tool for tropical and subtropical crops Computers and Electronics in Agriculture, 93, 98–110. http://dx.doi.org/10.1016/j.co....
 
22.
FAO, 1995. Guidelines; Land evaluation for rainfall agriculture. Soil Resources Management and Conservation Service, Land and Water Development Division Rome, FAO Soil Bulletin, 52, 237.
 
23.
FAO. 2017. Voluntary Guidelines for Sustainable Soil Management. Food and Agriculture Organization of the United Nations, Rome, Italy, 26 p.
 
24.
Fernández-Getino, A.P., Duarte, A.C., 2015. Soil management guidelines in Spain and Portugal related to EU Soil Protection Strategy based on analysis of soil databases. Catena, 126, 146–154. http://dx.doi.org/10.1016/j.ca....
 
25.
Gaudefroy, C., M.-M. Granger, F. Permingeat, Protas., J., 1968. La despujolsite, une nouvelle esp`ece min´erale. Bull. Min´eral., 91, 43–50 (in French with English abs.).
 
26.
Hanh, H.Q., Azadi, H., Dogot, T., Ton, V.D., Lebailly, P., 2017. Dynamics of Agrarian Systems and Land Use Change in North Vietnam. Land Degrad. Dev, 28, 799–810. https://doi.org/10.1002/ldr.26....
 
27.
Iqbal, P., 2018. The Quaternary Geology and the Weather of West Lampung Area, Its relationship to the Landslide Event. Journal of Geologt and Mineral Resources, 19(3), 159-166, (in Bahasa with English abs.). http://dx.doi.org/10.33332/jgs....
 
28.
Iqbal P., Muslim D., Zakaria Z., Permana H., Syahbana A.J., Yunarto, Jakah. 2020a. Geotechnical characteristics of volcanic red clay soil related to geoengineering problem in Sekincau, Sumatra, Indonesia. International Journal of Advanced Science and Technology, 29(7), 3166–3173.
 
29.
Iqbal, P., Muslim D., Zakaria Z., Permana H., Satriyo, N.A., Syahbana, A.J., Yunarto, Khoirullah, N., Asykarullah, A.W., 2020b. Swelling potential of volcanic residual soils in Sumatra (Indonesia) in relation to environmental issues. Environ. Socio.-econ. Stud., 8(4), 1-10. https://doi.org/10.2478/enviro....
 
30.
Ipswich City Council and Ipswich Rivers Improvement Trust, 2014. Ipswich Soil Management Guidelines. Amec Foster Wheeler, 51 p.
 
31.
Jang, J., Santamarina, J.C., 2016. Fines classification based on sensitivity to pore-fluid chemistry. J. Geotech. Geoenviron. Eng., 142(4), 06015018. http://dx.doi.org/10.1061/(ASC....
 
32.
Krasilʹnikov, P.V., 2009. A Handbook of Soil Terminology, Correlation and Classification. Earthscan. p. 376. ISBN 978-1-84977-435-2.
 
33.
Lal, R., Stewart, B.A., 2013. Soil Management for Sustaining Ecosystem Services. Principles of Sustainable Soil Management in Agroecosystems, CRC Press, Chapter 19, p 521.
 
34.
Maniyunda, L.M., Gwari, M.G., 2014. Soil suitability assessment of Haplustalfs for maize and groundnut in sub-humid environment of Nigeria. International Journal of Development and Sustainability, 3(2), 393-403.
 
35.
Matecka, P., Świtoniak, M., 2020. Delineation, characteristic and classification of soils containing carbonates in plow horizons within young moraine areas. Soil Science Annual, 71(1), 23-36. https://doi.org/10.37501/soils....
 
36.
Naval Facilities Engineering Command. 2011. Soil Mechanics, Foundations and Earth Structures: NAVFAC DM 7. vulcanhammer.net, null edition, 652 p.
 
37.
Oji, A.S., Akinbiyi, O.A., Olayiwola, K.O., 2016. Geotechnical Characterization of Soil, a Tool in Determining The Suitability of Soil for Construction Purpose, A Case Study of Federal Polytechnic Ede, Osun State, Southwestern Nigeria. 2016. International Journal of Sciences, Engineering & Environmental Technology (IJOSEET), 1(2), 16-23.
 
38.
Prakash. S., Jain, P.K., 2002. Engineering Soil Testing. Nem Chand & Bros, Roorkee.
 
39.
Rasimeng, S., Dasaputra, A., dan Alimuddin., 2007. Identification of the basement rock structure using the 2D resistivity method along the Cross Provincial Road in the landslide potential area of Sumberjaya, West Lampung. SIGMA, 10(2), pp 151-158, (in Bahasa with English abs).
 
40.
Santamarina, J.C., Park, J., Terzariol, Cardona, A., Castro, G.M., Cha, W., Garcia, A., Hakiki, F., Lyu, C., Salva, M., Shen, Y., Sun, Z., Chong, S-H. 2019. Soil Properties: Physics Inspired, Data Driven. Book chapter in Geotechnical Fundamentals for Addressing New World Challenges, Springer, p 67-92.
 
41.
Sharififar, A., 2012. Assessment of different methods of soil suitability classification for wheat cultivation. J Agrobiol, 29(2), 47–54. https://doi.org/10.2478/v10146....
 
42.
Sharififar, A., Ghorbani, H., Sarmadian, F., 2016. Soil suitability evaluation for crop selection using fuzzy sets methodology. Acta agriculturae Slovenica, 107-1, 159-174. https://doi.org/10.14720/aas.2....
 
43.
Skempton, A. 1953. The colloidal activity of clays. Selected Papers on Soil Mechanics, 106–118.
 
44.
Soehaimi, A., Muslim, D., Karnawan, Ir., Negara, R.S., 2015. Microzonation of the Liwa City on the Great Sumatera Active Fault and Giant Ranau Volcanic Complex in South Sumatera, Indonesia. Engineering Geology for Society and Territory, 5, 1015-1019. https://doi.org/10.1007/978-3-....
 
45.
Sonneveld, M.P.W., Hack-ten Broeke, M.J.D., van Diepen, C.A., Boogaard, H.L., 2010. Thirty years of systematic land evaluation in the Netherlands. Geoderma, 156, 84–92. https://doi.org/10.1016/j.geod....
 
46.
Stell, E., Guevara, M., Vargas, R., 2019. Soil swelling potential across Colorado: A digital soil mapping assessment. Landscape and Urban Planning, 190: 103599.
 
47.
Sys, C., Van Ranst, E., Debaveye, J., 1993. Land Evaluation Part 3: Crop Requirements. Agricultural Publication 7, 3. General Administration of Development Cooperation of Belgium, Brussels, 199p.
 
48.
Tengberg, A., Radstake, F., Zhang, K., Dunn, B., 2016. Scaling up of Sustainable Land Management in the Western People’s Republic of China: Evaluation of a 10-Year Partnership. Land Degrad & Dev., 27, 134–144. https://doi.org/10.1002/ldr.22....
 
49.
Uddin, F., 2018. Montmorillonite: An Introduction to Properties and Utilization: Chapter 1. Current Topics in the Utilization of Clay in Industrial and Medical Applications, p 3-23. http://dx.doi.org/10.5772/inte....
 
50.
Ural, N., 2018. The Importance of Clay in Geotechnical Engineering. Current Topics in the Utilization of Clay in Industrial and Medical Applications, p. 83.
 
51.
Visconti, F., de Paz, J.M., 2016. Electrical Conductivity Measurements in Agriculture: The Assessment of Soil Salinity. New Trends and Developments in Metrology, Luigi Cocco, IntechOpen, DOI: 10.5772/62741. Available from: https://www.intechopen.com/boo....
 
52.
Warrence, N.J., Bauder, J.W., Pearson, K.E., 2003. Basics of Salinity and Sodicity Effects on Soil Physical Properties. Land Resources and Environmental Sciences Department Montana State University – Bozeman, 29 p.
 
53.
Wesley, L.D., 2010. Fundamentals of Soil Mechanics for Sedimentary and Residual Soils, John Wiley and Sons.
 
54.
Wesley, L.D., 2013. Residual soils and the teaching of soil mechanic. Proceedings of the 18th International Conference on Soil Mechanics and Geotechnical Engineering, pp 3479-3482.
 
55.
Yustika, R.D., Somura, H., Yuwono, S.B., Arifin, B, Ismono, H., Masunaga, T., 2019. Assessment of soil erosion in social forest-dominated watersheds in Lampung, Indonesia. Environ Monit Assess, 191, 726. https://doi.org/10.1007/s10661....
 
56.
https://www.isric.org/explore/... accessed on January, 01st, 2021.
 
57.
https://www.worldometers.info/ accessed on December 31st, 2020.
 
eISSN:2300-4975
ISSN:2300-4967