Marginal lands: a review of papers from the Scopus database published in English for the period of 1979–2022
Tashkent Institute of Irrigation and Agricultural Mechanization Engineers” National Research University, Kary-Niaziy str. 39, Tashkent, 100000, Uzbekistan
New Uzbekistan University, 100007, Mustaqillik ave. 54, Tashkent, Uzbekistan
Turin Polytechnic University in Tashkent, Little Ring Road Street 17, 100095 Tashkent, Uzbekistan
Food and Agriculture Organization, Food and Agriculture Organization Representation in Uzbekistan, Uzbekistan
National University of Uzbekistan named after Mirzo Ulugbek, University str. 4, Tashkent, 100174, Uzbekistan
Data nadesłania: 12-02-2023
Data ostatniej rewizji: 15-06-2023
Data akceptacji: 15-07-2023
Data publikacji online: 15-07-2023
Data publikacji: 08-09-2023
Autor do korespondencji
Ilyaskhoja Jumaniyazov   

Tashkent Institute of Irrigation and Agricultural Mechanization Engineers” National Research University, Kary-Niaziy str. 39, Tashkent, 100000, Uzbekistan
Soil Sci. Ann., 2023, 74(2)169657
A marginal land definition is a contemporary scientific term that is constantly changing and unstoppable. There are many ways in which marginal lands are referred to, unproductive lands, including waste lands, unutilized lands, idle lands, abandoned lands, or degraded land. In the present research, we tried to collect all Scopus-based publications in English from 1979 to 2022 years using crucial keywords: Marginal lands, Land degradation, and Agricultural land. We analyzed the most popular journals, top authors, top-cited papers, top countries, top-cited years, etc. A common way to identify ML is to use biophysical constraints related to agricultural productivity or bioenergy. For instance, using a multi-criteria decision approach based on Geographic Information Systems (GIS) and remote sensing, combined data on land use/land cover (LULC), slope, soil depth, erosion, moisture, water holding capacity, texture, and availability of nutrient to study the land suitability for agriculture in hilly zones. There is a high potential for applying remote sensing (RS) and geographical information systems (GIS) for the mapping and monitoring of marginal lands. In addition, the role of remote sensing (RS) and geographic information systems (GIS) in other disciplines around the world is significantly high. In contrast, in this research work, we find out that the usage scale of RS and GIS technologies is not common all around the world on the given marginal land issues.
Ahmadzai, H., Tutundjian, S., Elouafi, I., 2021. Policies for sustainable agriculture and livelihood in marginal lands: A review. Sustain. Switz.
Alexandratos, N., 2012. World Agriculture towards 2030/2050: the 2012 revision 154.
Arshad, M.N., Donnison, I., Rowe, R.L., 2021. Marginal lands: Concept, classification criteria and management 36.
Bertaglia, M., Joost, S., Roosen, J., 2007. Identifying European marginal areas in the context of local sheep and goat breeds conservation: A geographic information system approach. Agric. Syst. 94, 657–670.
Breuning-Madsen, H., Reenberg, A., Holst, K., 1990. Mapping potentially marginal land in Denmark. Soil Use and Management 6, 114–120.
Cai, X., Zhang, X., Wang, D., 2011. Land Availability for Biofuel Production. Environmental Science and Technology 45, 334–339.
Campbell, J.E., Lobell, D.B., Genova, R.C., Field, C.B., 2008. The Global Potential of Bioenergy on Abandoned Agriculture Lands. Environmental Science and Technology 42, 5791–5794.
Carbonell-Rivera, J.P., Estornell, J., Ruiz, L.Á., Abad, A., Felten, B., Torralba, J., 2021. A review of the use of remote sensing for monitoring and quantifying carbon sequestration in marginal lands, in: Proceedings - 3rd Congress in Geomatics Engineering - CIGeo. Presented at the 3rd Congress in Geomatics Engineering, Universitat Politècnica de València.
Ciria, C.S., Sanz, M., Carrasco, J., Ciria, P., 2019. Identification of arable marginal lands under rainfed conditions for bioenergy purposes in Spain. Sustainability Switz.
Csikós, N., Tóth, G., 2023. Concepts of agricultural marginal lands and their utilisation: A review. Agricultural Systems 204, 103560.
Dauber, J., Brown, C., Fernando, A.L., Finnan, J., Krasuska, E., Ponitka, J., Styles, D., Thrän, D., Van Groenigen, K.J., Weih, M., Zah, R., 2012. Bioenergy from “surplus” land: environmental and socio-economic implications. BioRisk 7, 5–50.
Fischer, T., Byerlee, D., Edmeades, G., 2014. Crop yields and global food security: will yield increase continue to feed the world, ACIAR monograph series. ACIAR, Canberra.
Gopalakrishnan, G., Cristina Negri, M., Snyder, S.W., 2011. A Novel Framework to Classify Marginal Land for Sustainable Biomass Feedstock Production. Journal of Environmental Quality 40, 1593–1600.
Heimlich, R.E., 1989. Productivity and Erodibility of U.S. Cropland.
Hollander, J.H., 1895. The Concept of Marginal Rent. Q. J. Econ. 9, 175.
Jiang, H.-D., Dong, K.-Y., Liang, Q.-M., 2019. Research on marginal abatement cost: A bibliometric analysis. Energy Procedia 158, 4073–4078.
Kang, S., Post, W.M., Nichols, J.A., Wang, D., West, T.O., Bandaru, V., Izaurralde, R.C., 2013. Marginal Lands: Concept, Assessment and Management. Journal of Agricultural Sciences 5.
Karlen, D.L., Mausbach, M.J., Doran, J.W., Cline, R.G., Harris, R.F., Schuman, G.E., 1997. Soil Quality: A Concept, Definition, and Framework for Evaluation (A Guest Editorial). Soil Science Society of America Journal 61, 4–10.
Khamzina, A., Lamers, J.P.A., Vlek, P.L.G., 2008. Tree establishment under deficit irrigation on degraded agricultural land in the lower Amu Darya River region, Aral Sea Basin. Forest Ecology and Management 255, 168–178.
Li, G., Messina, J.P., Peter, B.G., Snapp, S.S., 2017. Mapping Land Suitability for Agriculture in Malawi. Land Degradation and Development 28, 2001–2016.
Li, Z., Wang, G., Lu, J., Broo, D.G., Kiritsis, D., Yan, Y., 2022. Bibliometric Analysis of Model-Based Systems Engineering: Past, Current, and Future. IEEE Trans. Eng. Manag. 1–18.
Lin, B.B., 2011. Resilience in Agriculture through Crop Diversification: Adaptive Management for Environmental Change. BioScience 61, 183–193.
McKenzie, F.C., Williams, J., 2015. Sustainable food production: constraints, challenges and choices by 2050. Food Security 7, 221–233.
Mongeon, P., Paul-Hus, A., 2016. The journal coverage of Web of Science and Scopus: a comparative analysis. Scientometrics 106, 213–228.
Peterson, G.M., Galbraith, J.K., 1932. The Concept of Marginal Land. Journal of Farm Economics 14, 295.
Reger, B., Otte, A., Waldhardt, R., 2007. Identifying patterns of land-cover change and their physical attributes in a marginal European landscape. Landscape and Urban Planning 81, 104–113.
Ricardo, D., 2005. From The Principles of Political Economy and Taxation, in: Increasing Returns and Inframarginal Economics. World scientific, pp. 127–130.
Senior Scientist – Irrigation and Water Management, International Center for Biosaline Agriculture (ICBA), P.O. Box 14660, Dubai, UAE, Qureshi, A.S., 2017. Sustainable use of marginal lands to improve food security in the United Arab Emirates. J. Exp. Biol. Agric. Sci. 5, 41–49.
Strijker, D., 2005. Marginal lands in Europe—causes of decline. Basic and Applied Ecology 6, 99–106.
South Australia Marginal Lands Act. (1940)., 2002. An act to confer powers upon the minister of lands in relation to the settlement of marginal lands.
Tang, Y., Xie, J.-S., Geng, S., 2010. Marginal Land-based Biomass Energy Production in China. Journal of Integrative Plant Biology 52, 112–121.
Tong, S., Zhiming, F., Yanzhao, Y., Yumei, L., Yanjuan, W., 2018. Research on Land Resource Carrying Capacity: Progress and Prospects. Journal of Resources and Ecology 9, 331–340.
Torralba, J., Ruiz, L.Á., Georgiadis, C., Patias, P., Gómez-Conejo, R., Verde, N., Tassapoulou, M., Bezares Sanfelip, F., Grommy, E., Aleksandrowicz, S., Krätzschmar, E., Krupiński, M., Carbonell-Rivera, J.P., 2021. Methodological proposal for the identification of marginal lands with remote sensing-derived products and ancillary data, in: Proceedings - 3rd Congress in Geomatics Engineering - CIGeo. Presented at the 3rd Congress in Geomatics Engineering, Universitat Politècnica de València.
Wells, G.J., Stuart, N., Furley, P.A., Ryan, C.M., 2018. Ecosystem service analysis in marginal agricultural lands: A case study in Belize. Ecosystem Services 32, 70–77.
Wicke, B., Smeets, E., Dornburg, V., Vashev, B., Gaiser, T., Turkenburg, W., Faaij, A., 2011. The global technical and economic potential of bioenergy from salt-affected soils. Energy & Environmental Science 4, 2669–2681.
Wiegmann, K., Hennenberg, K.J., Fritsche, U.R., 2008. Öko-Institut, Darmstadt Office.
Wood, S., Sebastian, K.L., Scherr, S.J., 2000. Pilot analysis of global ecosystems: agroecosystems. World Resources Institute, Washington, D.C.
Worldwatch Institute, 2006. Biofuels for transportation: Global potential and implications for sustainable agriculture and energy in 21st century. Prepared for the Federal Ministry of Food, Agriculture and Consumer Protection (BMELV), Germany in cooperation with GTZ and FNR. Washington D.C.
Zolekar, R.B., Bhagat, V.S., 2015. Multi-criteria land suitability analysis for agriculture in hilly zone: Remote sensing and GIS approach. Computers and Electronics in Agriculture 118, 300–321.
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