nach oben

Environmental Earth Sciences

Erschienen in:

01.03.2024 | Original Article

A RUSLE-based comprehensive strategy to assess soil erosion in a riverine country, Bangladesh

verfasst von: Md. Rabiul Islam, H. M. Imran, Md. Rakibul Islam, Ganesh Chandra Saha

Erschienen in: Environmental Earth Sciences | Ausgabe 6/2024

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Recognizing soil as a vital resource for food production and animal habitat, this study employed a comprehensive, nationwide erosion assessment in Bangladesh using the Revised Universal Soil Loss Equation (RUSLE) model. Rainfall, soil data, the Digital Elevation Model (DEM), Landsat 8 imagery, and land use and land cover (LULC) maps were employed as inputs for the prediction of potential soil erosion. Utilizing the zonal statistics tool within a geographic information system (GIS) platform, the study area's most erosion-vulnerable zones were subsequently identified and mapped. These zones were designated as 'erosion hotspots' (EHs) with demonstrably clear connections to river basins and networks. Analysis revealed an annual average erosion rate of 1.3 t ha⁻¹ yr⁻¹, resulting in an alarming loss of 17.68 million tons of topsoil annually. Notably, four distinct EHs were identified within the study area. The southeast region, due to its specific topography and climate, was found to be highly susceptible to erosion. Within this region, 2.22% (2995.93 km²) experience erosion exceeding 10.0 t ha⁻¹ yr⁻¹. RUSLE-based results were validated by comparison with outputs from the Global Soil Erosion Modeling Platform (GloSEM) and Google Earth imagery. In addition, the model's performance was evaluated using the receiver operating characteristic (ROC) curve and area under the ROC curve (AUC). The high AUC value of 0.94 achieved in this study reinforces the accuracy and confidence of the soil erosion estimations.

Vorheriger Artikel Monitoring and modelling approaches for quantitative assessment of irrigation return flows in a command

Nächster Artikel Modeling and forecasting rainfall patterns in India: a time series analysis with XGBoost algorithm

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Adediji A, Tukur A, Adepoju K (2010) Assessment of revised universal soil loss equation (RUSLE) in Katsina area, Katsina state of Nigeria using remote sensing (RS) and geographic information system (GIS). Iranica J Energy Environ 1(3):255–264

Anache J, Bacchi CG, Alves-Sobrinho T (2014) Modeling of (R) USLE C-factor for pasture as a function of normalized difference vegetation index. Eur Int J Sci Technol 3(9):214–221

Aslam B, Maqsoom A, Kazmi ZA, Sodangi M, Anwar F, Bakri MH, Farooq D (2020) Effects of landscape changes on soil erosion in the built environment: application of geospatial-based RUSLE technique. Sustainability 12(15):5898CrossRef

Aziz M, Shohan HUS, Rahman NM, Rahman MC, Nihad SAI, Hassan S, Qayum M (2022) Projection of future precipitation in Bangladesh at Kharif-II season using geospatial techniques. Earth Syst Environ 7:1–12

Bagarello V, Ferro V (2004) Plot-scale measurement of soil erosion at the experimental area of Sparacia (southern Italy). Hydrol Process 18(1):141–157CrossRef

Balthazar V, Vanacker V, Girma A, Poesen J, Golla S (2013) Human impact on sediment fluxes within the Blue Nile and Atbara River basins. Geomorphology 180:231–241CrossRef

Bangladesh, S. P. B. (2008). Bangladesh Bureau of Statistics (BBS): Retrieved 2009–10–10.

Baptista I, Ritsema C, Geissen V (2015) Effect of integrated water-nutrient management strategies on soil erosion mediated nutrient loss and crop productivity in Cabo Verde drylands. PLoS ONE 10(7):e0134244PubMedPubMedCentralCrossRef

Bari R, Hossain MA, Alam MJ, Islam T (2022) Quantitatification of soil erosion using causative factors in the GIS environment for Sylhet district, Bangladesh. Malays J Civil Eng 34(1):37–43CrossRef

Bhattacharya RK, Das Chatterjee N, Das K (2021) Land use and land cover change and its resultant erosion susceptible level: an appraisal using RUSLE and Logistic Regression in a tropical plateau basin of West Bengal, India. Environ Dev Sustain 23(2):1411–1446CrossRef

Billah MM, Rahman M, Abedin J, Akter H (2021) Land cover change and its impact on human–elephant conflict: a case from Fashiakhali forest reserve in Bangladesh. SN Appl Sci 3(6):1–17CrossRef

Borrelli P, Robinson DA, Fleischer LR, Lugato E, Ballabio C, Alewell C, Meusburger K, Modugno S, Schütt B, Ferro V, Bagarello V, Van Oost K, Montanarella M, Panago P (2017) An assessment of the global impact of 21st century land use change on soil erosion. Nat Commun 8(1):1–13CrossRef

Borrelli P, Robinson DA, Panagos P, Lugato E, Yang JE, Alewell C, Wuepper D, Montanarella L, Ballabio C (2020) Land use and climate change impacts on global soil erosion by water (2015–2070). Proc Natl Acad Sci 117(36):21994–22001PubMedPubMedCentralCrossRef

Cao Y, Ouyang Z, Zheng H, Huang Z, Wang X, Miao H (2008) Effects of forest plantations on rainfall redistribution and erosion in the red soil region of Southern China. Land Degrad Dev 19(3):321–330CrossRef

Chen T, Niu R-Q, Wang Y, Li P-X, Zhang L-P, Du B (2011) Assessment of spatial distribution of soil loss over the upper basin of Miyun reservoir in China based on RS and GIS techniques. Environ Monit Assess 179(1):605–617PubMedCrossRef

Dapin IG, Ella VB (2023) GIS-based soil erosion risk assessment in the Watersheds of Bukidnon, Philippines using the RUSLE model. Sustainability 15(4):3325CrossRef

Das B, Paul A, Bordoloi R, Tripathi OP, Pandey PK (2018) Soil erosion risk assessment of hilly terrain through integrated approach of RUSLE and geospatial technology: a case study of Tirap District, Arunachal Pradesh. Model Earth Syst Environ 4(1):373–381CrossRef

Desmet P, Govers G (1996) A GIS procedure for automatically calculating the USLE LS factor on topographically complex landscape units. J Soil Water Conserv 51(5):427–433

Devatha C, Deshpande V, Renukaprasad M (2015) Estimation of soil loss using USLE model for Kulhan Watershed, Chattisgarh-a case study. Aquat Procedia 4:1429–1436CrossRef

Dewan AM, Yamaguchi Y (2009) Land use and land cover change in Greater Dhaka, Bangladesh: using remote sensing to promote sustainable urbanization. Appl Geogr 29(3):390–401CrossRef

Di Stefano C, Pampalone V, Todisco F, Vergni L, Ferro V (2019) Testing the universal soil loss equation-MB equation in plots in Central and South Italy. Hydrol Process 33(18):2422–2433CrossRef

Dissanayake DMSLB, Morimoto T, Ranagalage M (2019) Accessing the soil erosion rate based on RUSLE model for sustainable land use management: a case study of the Kotmale watershed, Sri Lanka. Model Earth Syst Environ 5:291–306CrossRef

Duarte L, Teodoro A, Gonçalves J, Soares D, Cunha M (2016) Assessing soil erosion risk using RUSLE through a GIS open source desktop and web application. Environ Monit Assess 188(6):351PubMedCrossRef

Dutta D, Das S, Kundu A, Taj A (2015) Soil erosion risk assessment in Sanjal watershed, Jharkhand (India) using geo-informatics, RUSLE model and TRMM data. Model Earth Syst Environ 1(4):1–9CrossRef

Fagbohun BJ, Anifowose AY, Odeyemi C, Aladejana OO, Aladeboyeje AI (2016) GIS-based estimation of soil erosion rates and identification of critical areas in Anambra sub-basin, Nigeria. Model Earth Syst Environ 2(3):1–10CrossRef

Gayen A, Saha S, Pourghasemi HR (2020) Soil erosion assessment using RUSLE model and its validation by FR probability model. Geocarto Int 35(15):1750–1768CrossRef

Ghosal K, Das Bhattacharya S (2020) A review of RUSLE model. J Indian Soc Remote Sens 48(4):689–707CrossRef

Gilani, H., Ahmad, A., Younes, I., & Abbas, S. (2021). Estimation of annual soil erosion dynamics (2005–2015) in Pakistan using Revised Universal Soil Loss Equation (RUSLE). Authorea Preprints.

Gyeltshen S, Adhikari R, Budha PB, Thapa G, Subedi KK, Singh BK (2022) Remote sensing and GIS based soil loss estimation for Bhutan, using RUSLE model. Geocarto Int 37(21):6331–6350CrossRef

Htwe TN, Brinkmann K, Buerkert A (2015) Spatio-temporal assessment of soil erosion risk in different agricultural zones of the Inle Lake region, southern Shan State, Myanmar. Environ Monit Assess 187(10):1–14CrossRef

Islam MS, Alam MJ (2009). Geological aspects of soil formation of Bangladesh

Islam MA, Hasan MA, Farukh MA (2017) Application of GIS in general soil mapping of Bangladesh. J Geogr Inf Syst 9(5):604–621

Islam MR, Islam MR, Imran HM (2022) Assessing wind farm site suitability in Bangladesh: a GIS-AHP approach. Sustainability 14(22):14819CrossRef

Jaafar WZW, Islam MR, Hin LS, Osman N, Othman FB, Din MAM, Karim R (2020) Assessment of rainfall-induced soil erosion on hillslope: a case study at the Guthrie Corridor Expressway, Malaysia. Sustain Water Resour Manag 6(2):1–10CrossRef

Jin F, Yang W, Fu J, Li Z (2021) Effects of vegetation and climate on the changes of soil erosion in the Loess Plateau of China. Sci Total Environ 773:145514PubMedCrossRef

Kamruzzaman M, Jang M-W, Cho J, Hwang S (2019) Future changes in precipitation and drought characteristics over Bangladesh under CMIP5 climatological projections. Water 11(11):2219CrossRef

Kamruzzaman M, Shahid S, Roy DK, Islam ARMT, Hwang S, Cho J, Zaman MAU, Sultana T, Rashid T, Akter F (2022) Assessment of CMIP6 global climate models in reconstructing rainfall climatology of Bangladesh. Int J Climatol 42(7):3928–3953CrossRef

Karydas CG, Panagos P, Gitas IZ (2014) A classification of water erosion models according to their geospatial characteristics. Int J Digit Earth 7(3):229–250CrossRef

Kayet N, Pathak K, Chakrabarty A, Sahoo S (2018) Evaluation of soil loss estimation using the RUSLE model and SCS-CN method in hillslope mining areas. Int Soil Water Conserv Res 6(1):31–42CrossRef

Kemp P, Sear D, Collins A, Naden P, Jones I (2011) The impacts of fine sediment on riverine fish. Hydrol Process 25(11):1800–1821CrossRef

Koirala P, Thakuri S, Joshi S, Chauhan R (2019) Estimation of soil erosion in Nepal using a RUSLE modeling and geospatial tool. Geosciences 9(4):147CrossRef

Kovacs AS, Fulop B, Honti M (2012) Detection of hot spots of soil erosion and reservoir siltation in ungauged Mediterranean catchments. Energy Procedia 18:934–943CrossRef

Kumar S, Kushwaha S (2013) Modelling soil erosion risk based on RUSLE-3D using GIS in a Shivalik sub-watershed. J Earth Syst Sci 122(2):389–398CrossRef

Kumar R, Deshmukh B, Kumar A (2022) Using Google Earth Engine and GIS for basin scale soil erosion risk assessment: a case study of Chambal river basin, central India. J Earth Syst Sci 131(4):228CrossRef

Lakaria BL, Biswas H, Mandal D (2008) Soil loss tolerance values for different physiographic regions of Central India. Soil Use Manag 24(2):192–198CrossRef

Le Roux J, Morgenthal T, Malherbe J, Pretorius D, Sumner P (2008) Water erosion prediction at a national scale for South Africa. Water Sa 34(3):305–314CrossRef

Lehner B, Grill G (2013) Global river hydrography and network routing: baseline data and new approaches to study the world’s large river systems. Hydrol Process 27(15):2171–2186CrossRef

Lin C-Y, Lin W-T, Chou W-C (2002) Soil erosion prediction and sediment yield estimation: the Taiwan experience. Soil Tillage Res 68(2):143–152MathSciNetCrossRef

Liu X, Xin L, Lu Y (2021) National scale assessment of the soil erosion and conservation function of terraces in China. Ecol Ind 129:107940CrossRef

Marcinkowski P, Szporak-Wasilewska S, Kardel I (2022) Assessment of soil erosion under long-term projections of climate change in Poland. J Hydrol 607:127468CrossRef

Mas J-F, Filho BS, Pontius RG Jr, Gutiérrez MF, Rodrigues H (2013) A suite of tools for ROC analysis of spatial models. ISPRS Int J Geo Inf 2(3):869–887CrossRef

McCool DK, Foster GR, Mutchler C, Meyer L (1989) Revised slope length factor for the universal soil loss equation. Trans ASAE 32(5):1571–1576CrossRef

Mirza M, Warrick R, Ericksen N (2003) The implications of climate change on floods of the Ganges, Brahmaputra and Meghna rivers in Bangladesh. Clim Change 57(3):287–318CrossRef

Moore ID, Wilson JP (1992) Length-slope factors for the Revised Universal Soil Loss Equation: Simplified method of estimation. J Soil Water Conserv 47(5):423–428

Morgan RPC (2009) Soil erosion and conservation. Wiley, Hoboken

Napoli M, Cecchi S, Orlandini S, Mugnai G, Zanchi CA (2016) Simulation of field-measured soil loss in Mediterranean hilly areas (Chianti, Italy) with RUSLE. CATENA 145:246–256CrossRef

Onori F, De Bonis P, Grauso S (2006) Soil erosion prediction at the basin scale using the revised universal soil loss equation (RUSLE) in a catchment of Sicily (southern Italy). Environ Geol 50(8):1129–1140CrossRef

Panagos P, Borrelli P, Poesen J, Ballabio C, Lugato E, Meusburger K, Alewell C (2015) The new assessment of soil loss by water erosion in Europe. Environ Sci Policy 54:438–447CrossRef

Pandey A, Chowdary V, Mal B (2007) Identification of critical erosion prone areas in the small agricultural watershed using USLE, GIS and remote sensing. Water Resour Manage 21(4):729–746CrossRef

Pereira P, Barceló D, Panagos P (2020) Soil and water threats in a changing environment. Environ Res 186:109501PubMedCrossRef

Perović V, Životić L, Kadović R, Đorđević A, Jaramaz D, Mrvić V, Todorović M (2013) Spatial modelling of soil erosion potential in a mountainous watershed of South-eastern Serbia. Environ Earth Sci 68(1):115–128CrossRef

Pourghasemi HR, Jirandeh AG, Pradhan B, Xu C, Gokceoglu C (2013) Landslide susceptibility mapping using support vector machine and GIS at the Golestan Province, Iran. J Earth Syst Sci 122(2):349–369CrossRef

Prasannakumar V, Vijith H, Abinod S, Geetha NJGF (2012) Estimation of soil erosion risk within a small mountainous sub-watershed in Kerala, India, using Revised Universal Soil Loss Equation (RUSLE) and geo-information technology. Geosci Front 3(2):209–215CrossRef

Rahman, N. (2021). Application of the Revised Universal Soil Loss Equation to Develop a Management Plan in the Chittagong Hill Tracts Region of Bangladesh

Rao W, Shen Z, Duan X (2023) Spatiotemporal patterns and drivers of soil erosion in Yunnan, Southwest China: RULSE assessments for recent 30 years and future predictions based on CMIP6. CATENA 220:106703CrossRef

Rashid HE (2019) Geography of Bangladesh. Routledge, Milton ParkCrossRef

Rashid T, Agrafiotis I, Nurse JR (2016) A new take on detecting insider threats: exploring the use of hidden markov models. Paper presented at the Proceedings of the 8th ACM CCS International workshop on managing insider security threats

Renard KG (1997) Predicting soil erosion by water: a guide to conservation planning with the Revised Universal Soil Loss Equation (RUSLE). United States Government Printing, Washington

Renard KG, Freimund JR (1994) Using monthly precipitation data to estimate the R-factor in the revised USLE. J Hydrol 157(1–4):287–306CrossRef

Renard KG, Foster GR, Weesies GA, Porter JP (1991) RUSLE: Revised universal soil loss equation. J Soil Water Conserv 46(1):30–33

Rosas MA, Gutierrez RR (2020) Assessing soil erosion risk at national scale in developing countries: the technical challenges, a proposed methodology, and a case history. Sci Total Environ 703:135474PubMedCrossRef

Routschek A, Schmidt J, Kreienkamp F (2015). Climate Change impacts on soil erosion: a high-resolution projection on catchment scale until 2100 Engineering Geology for Society and Territory-Volume 1 (pp. 135–141). Springer

Safari Z, Rahimi ST, Ahmed K, Sharafati A, Ziarh GF, Shahid S, Ismail T, Al-Ansari N, Chung E-S, Wang X (2021) Estimation of spatial and seasonal variability of soil erosion in a cold arid river Basin in Hindu Kush Mountainous region using remote sensing. Sustainability 13(3):1549CrossRef

Saha A, Ghosh P, Mitra B (2018) GIS based soil erosion estimation using RUSLE model: a case study of Upper Kangsabati, Watershed, West Bengal, India. Int J Environ Sci Nat Res 13(5):001–008

Saha M, Sauda SS, Mahmud MS (2019) Estimation of annual soil erosion rate using RUSLE: a study on the Jamuna River sub-basin in Bangladesh. Paper presented at the Conference: European Space Agency's Living Planet Symposium

Saha M, Sauda SS, Real HRK, Mahmud M (2022) Estimation of annual rate and spatial distribution of soil erosion in the Jamuna basin using RUSLE model: a geospatial approach. Environ Chall 8:100524CrossRef

Sharpley AN, Williams JR (1990) EPIC. Erosion/Productivity impact calculator: 1. Model documentation. 2. User manual.

Singh G, Panda RK (2017) Grid-cell based assessment of soil erosion potential for identification of critical erosion prone areas using USLE, GIS and remote sensing: a case study in the Kapgari watershed, India. Int Soil Water Conserv Res 5(3):202–211CrossRef

Somasiri I, Hewawasam T, Rambukkange M (2022) Adaptation of the revised universal soil loss equation to map spatial distribution of soil erosion in tropical watersheds: a GIS/RS-based study of the Upper Mahaweli River Catchment of Sri Lanka. Model Earth Syst Environ 8(2):2627–2645CrossRef

Sourn T, Pok S, Chou P, Nut N, Theng D, Prasad PV (2022) Assessment of land use and land cover changes on soil erosion using remote sensing, GIS and RUSLE model: a case study of battambang province, Cambodia. Sustainability 14(7):4066CrossRef

Sun P, Wu Y, Wei X, Sivakumar B, Qiu L, Mu X, Gao J (2020) Quantifying the contributions of climate variation, land use change, and engineering measures for dramatic reduction in streamflow and sediment in a typical loess watershed, China. Ecol Eng 142:105611CrossRef

Tamene L, Adimassu Z, Ellison J, Yaekob T, Woldearegay K, Mekonnen K, Thorne P, Le QB (2017) Mapping soil erosion hotspots and assessing the potential impacts of land management practices in the highlands of Ethiopia. Geomorphology 292:153–163CrossRef

Tang Q, Xu Y, Bennett SJ, Li Y (2015) Assessment of soil erosion using RUSLE and GIS: a case study of the Yangou watershed in the Loess Plateau, China. Environ Earth Sci 73(4):1715–1724CrossRef

Tanyaş H, Kolat Ç, Süzen ML (2015) A new approach to estimate cover-management factor of RUSLE and validation of RUSLE model in the watershed of Kartalkaya Dam. J Hydrol 528:584–598CrossRef

Thomas J, Joseph S, Thrivikramji K (2018) Assessment of soil erosion in a tropical mountain river basin of the southern Western Ghats, India using RUSLE and GIS. Geosci Front 9(3):893–906CrossRef

Tian P, Zhu Z, Yue Q, He Y, Zhang Z, Hao F, Guo W, Chen L, Liu M (2021) Soil erosion assessment by RUSLE with improved P factor and its validation: case study on mountainous and hilly areas of Hubei Province, China. Int Soil Water Conserv Res 9(3):433–444CrossRef

Tiruwa DB, Khanal BR, Lamichhane S, Acharya BS (2021) Soil erosion estimation using Geographic Information System (GIS) and Revised Universal Soil Loss Equation (RUSLE) in the Siwalik Hills of Nawalparasi, Nepal. J Water Clim Change 12(5):1958–1974CrossRef

Uddin K, Murthy M, Wahid SM, Matin MA (2016) Estimation of soil erosion dynamics in the Koshi basin using GIS and remote sensing to assess priority areas for conservation. PLoS ONE 11(3):e0150494PubMedPubMedCentralCrossRef

Uddin K, Abdul Matin M, Maharjan S (2018) Assessment of land cover change and its impact on changes in soil erosion risk in Nepal. Sustainability 10(12):4715CrossRef

Ugese AA, Ajiboye JO, Ibrahim ES, Gajere EN, Itse A, Shaba HA (2022) Soil loss estimation using remote sensing and RUSLE model in Koromi-Federe catchment area of Jos-east LGA, Plateau State, Nigeria. Geomatics 2(4):499–517CrossRef

Vrieling A, Sterk G, de Jong SM (2010) Satellite-based estimation of rainfall erosivity for Africa. J Hydrol 395(3–4):235–241CrossRef

Wang H, Zhao H (2020) Dynamic changes of soil erosion in the taohe river basin using the RUSLE model and google earth engine. Water 12(5):1293CrossRef

Wischmeier WH, Smith DD (1978). Predicting rainfall erosion losses: a guide to conservation planning: Department of Agriculture, Science and Education Administration.

Wischmeier WH, Johnson C, Cross B (1971) Soil erodibility nomograph for farmland and construction sites

Wu Y, Chen J (2012) Modeling of soil erosion and sediment transport in the East River Basin in southern China. Sci Total Environ 441:159–168PubMedCrossRef

Yue-Qing X, Xiao-Mei S, Xiang-Bin K, Jian P, Yun-Long C (2008) Adapting the RUSLE and GIS to model soil erosion risk in a mountains karst watershed, Guizhou Province, China. Environ Monit Assess 141(1):275–286PubMedCrossRef

Zerihun M, Mohammedyasin MS, Sewnet D, Adem AA, Lakew M (2018) Assessment of soil erosion using RUSLE, GIS and remote sensing in NW Ethiopia. Geoderma Reg 12:83–90CrossRef

Zisheng Y (2002) Study on soil loss equation in Jinsha River Basin of Yunnan Province. J Mt Sci 20(1):9

Titel: A RUSLE-based comprehensive strategy to assess soil erosion in a riverine country, Bangladesh
verfasst von: Md. Rabiul Islam
H. M. Imran
Md. Rakibul Islam
Ganesh Chandra Saha
Publikationsdatum: 01.03.2024
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 6/2024
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-024-11455-y

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 6/2024

Hg distribution and risk assessment in soil–Bozhou peony system

Experimental study on nonlinear flow behavior in smooth and rough sandstone fractures subjected to various injection pressure and normal compressive stress

Hydrological modeling and simulation of water balance components using the SWAT model in the coal mining province of the Mahan River catchment, Central India

Hydrogeochemical evolution and water–rock interaction processes in the multilayer volcanic aquifer of Yogyakarta-Sleman Groundwater Basin, Indonesia

Hydrochemical characteristics, evolution and health risk assessment of surface water and groundwater in Lhasa, China

Can extreme climatic and bioclimatic indices reproduce soy and maize yields in Latin America? Part 1: an observational and modeling perspective