Predicting Arsenic Contamination Hotspots in Abandoned River Bends in Bangladesh: A Machine Learning Approach

Julian Peter Biesheuvel; Marinus Eric Donselaar; Devanita Ghosh; Roderik Lindenbergh

Predicting Arsenic Contamination Hotspots in Abandoned River Bends in Bangladesh: A Machine Learning Approach

Julian Peter Biesheuvel^*, Marinus Eric Donselaar, Devanita Ghosh, Roderik Lindenbergh

^*Corresponding author for this work

Research output: Contribution to conference › Paper › peer-review

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Abstract

Arsenic contamination in shallow aquifers of Holocene alluvial basins is a serious health risk affecting millions of people [1]. Detection of arsenic hotspots is a slow and tedious process based on the analysis of groundwater samples. This study improves arsenic risk prediction by incorporating geomorphological features such as oxbow lakes and clay plugs into a machine learning (ML) approach. Advances in remote sensing [2], often combined with ML, enable the efficient detection of these and other proxy features, significantly reducing reliance on labour-intensive fieldwork. By combining these features with environmental and demographic data, the approach provides more accurate and cost-effective risk assessments, enabling better-targeted interventions in vulnerable regions and supporting proactive environmental monitoring.

Original language	English
Number of pages	3
Publication status	Published - 2025
Event	ESA Living Planet Symposium 2025 - Vienna, Austria Duration: 23 Jun 2025 → 27 Jun 2025 https://lps25.esa.int/

Conference

Conference	ESA Living Planet Symposium 2025
Abbreviated title	LPS25
Country/Territory	Austria
City	Vienna
Period	23/06/25 → 27/06/25
Internet address	https://lps25.esa.int/

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@conference{a84f421483e443f290d226f887e4fcf9,

title = "Predicting Arsenic Contamination Hotspots in Abandoned River Bends in Bangladesh: A Machine Learning Approach",

abstract = "Arsenic contamination in shallow aquifers of Holocene alluvial basins is a serious health risk affecting millions of people [1]. Detection of arsenic hotspots is a slow and tedious process based on the analysis of groundwater samples. This study improves arsenic risk prediction by incorporating geomorphological features such as oxbow lakes and clay plugs into a machine learning (ML) approach. Advances in remote sensing [2], often combined with ML, enable the efficient detection of these and other proxy features, significantly reducing reliance on labour-intensive fieldwork. By combining these features with environmental and demographic data, the approach provides more accurate and cost-effective risk assessments, enabling better-targeted interventions in vulnerable regions and supporting proactive environmental monitoring.",

author = "Biesheuvel, {Julian Peter} and Donselaar, {Marinus Eric} and Devanita Ghosh and Roderik Lindenbergh",

year = "2025",

language = "English",

note = "ESA Living Planet Symposium 2025, LPS25 ; Conference date: 23-06-2025 Through 27-06-2025",

url = "https://lps25.esa.int/",

}

TY - CONF

T1 - Predicting Arsenic Contamination Hotspots in Abandoned River Bends in Bangladesh

T2 - ESA Living Planet Symposium 2025

AU - Biesheuvel, Julian Peter

AU - Donselaar, Marinus Eric

AU - Ghosh, Devanita

AU - Lindenbergh, Roderik

PY - 2025

Y1 - 2025

N2 - Arsenic contamination in shallow aquifers of Holocene alluvial basins is a serious health risk affecting millions of people [1]. Detection of arsenic hotspots is a slow and tedious process based on the analysis of groundwater samples. This study improves arsenic risk prediction by incorporating geomorphological features such as oxbow lakes and clay plugs into a machine learning (ML) approach. Advances in remote sensing [2], often combined with ML, enable the efficient detection of these and other proxy features, significantly reducing reliance on labour-intensive fieldwork. By combining these features with environmental and demographic data, the approach provides more accurate and cost-effective risk assessments, enabling better-targeted interventions in vulnerable regions and supporting proactive environmental monitoring.

AB - Arsenic contamination in shallow aquifers of Holocene alluvial basins is a serious health risk affecting millions of people [1]. Detection of arsenic hotspots is a slow and tedious process based on the analysis of groundwater samples. This study improves arsenic risk prediction by incorporating geomorphological features such as oxbow lakes and clay plugs into a machine learning (ML) approach. Advances in remote sensing [2], often combined with ML, enable the efficient detection of these and other proxy features, significantly reducing reliance on labour-intensive fieldwork. By combining these features with environmental and demographic data, the approach provides more accurate and cost-effective risk assessments, enabling better-targeted interventions in vulnerable regions and supporting proactive environmental monitoring.

UR - https://www.researchgate.net/publication/393164935_Title_Predicting_Arsenic_Contamination_Hotspots_in_Abandoned_River_Bends_in_Bangladesh_A_Machine_Learning_Approach

M3 - Paper

Y2 - 23 June 2025 through 27 June 2025

ER -

Predicting Arsenic Contamination Hotspots in Abandoned River Bends in Bangladesh: A Machine Learning Approach

Abstract

Conference

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