Predicting debris flow pathways using volume-based thresholds for effective risk assessment

A. Rajaneesh; V.K. Krishnapriya; K.S. Sajinkumar; Nikhil Nedumpallile Vasu; C. van Westen; Thomas Oommen; Ali P. Yunus; Vanessa J. Banks; A.P. Pradeepkumar

doi:10.1038/s44304-024-00055-2

Predicting debris flow pathways using volume-based thresholds for effective risk assessment

A. Rajaneesh
, V.K. Krishnapriya
, K.S. Sajinkumar^*
, Nikhil Nedumpallile Vasu
, C. van Westen
, Thomas Oommen
, Ali P. Yunus
, Vanessa J. Banks
, A.P. Pradeepkumar

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Investigating the preferential flow path of a debris flow is crucial for quantifying the risk and developing mitigation strategies. Here, we examined 66 debris flows from the Western Ghats in India employing Rapid Mass Movement Simulation (RAMMS)::Debris Flow software to understand the kinematics of run-out. Our analysis revealed that the debris flow run-out in the study area follow two main routes: 60 along the existing stream channels (SC) and six following the steepest hill slope (SH). We further simulated these debris flows to identify their drivers, and derived a threshold that distinguishes between SC and SH-type debris flows. Our results indicate that the debris flow volumes greater than 7072 cu. m is SH-type, whereas those with smaller volumes are more likely to follow SC paths. The model’s accuracy was validated against field observations, achieving a success rate of 93% for SH-type flows and 85% for SC.

Original language	English
Article number	1
Journal	npj Natural Hazards
Volume	2
Issue number	1
DOIs	https://doi.org/10.1038/s44304-024-00055-2
Publication status	Published - 10 Jan 2025

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title = "Predicting debris flow pathways using volume-based thresholds for effective risk assessment",

abstract = "Investigating the preferential flow path of a debris flow is crucial for quantifying the risk and developing mitigation strategies. Here, we examined 66 debris flows from the Western Ghats in India employing Rapid Mass Movement Simulation (RAMMS)::Debris Flow software to understand the kinematics of run-out. Our analysis revealed that the debris flow run-out in the study area follow two main routes: 60 along the existing stream channels (SC) and six following the steepest hill slope (SH). We further simulated these debris flows to identify their drivers, and derived a threshold that distinguishes between SC and SH-type debris flows. Our results indicate that the debris flow volumes greater than 7072 cu. m is SH-type, whereas those with smaller volumes are more likely to follow SC paths. The model{\textquoteright}s accuracy was validated against field observations, achieving a success rate of 93\% for SH-type flows and 85\% for SC.",

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doi = "10.1038/s44304-024-00055-2",

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T1 - Predicting debris flow pathways using volume-based thresholds for effective risk assessment

AU - Rajaneesh, A.

AU - Krishnapriya, V.K.

AU - Sajinkumar, K.S.

AU - Nedumpallile Vasu, Nikhil

AU - van Westen, C.

AU - Oommen, Thomas

AU - Yunus, Ali P.

AU - Banks, Vanessa J.

AU - Pradeepkumar, A.P.

PY - 2025/1/10

Y1 - 2025/1/10

N2 - Investigating the preferential flow path of a debris flow is crucial for quantifying the risk and developing mitigation strategies. Here, we examined 66 debris flows from the Western Ghats in India employing Rapid Mass Movement Simulation (RAMMS)::Debris Flow software to understand the kinematics of run-out. Our analysis revealed that the debris flow run-out in the study area follow two main routes: 60 along the existing stream channels (SC) and six following the steepest hill slope (SH). We further simulated these debris flows to identify their drivers, and derived a threshold that distinguishes between SC and SH-type debris flows. Our results indicate that the debris flow volumes greater than 7072 cu. m is SH-type, whereas those with smaller volumes are more likely to follow SC paths. The model’s accuracy was validated against field observations, achieving a success rate of 93% for SH-type flows and 85% for SC.

AB - Investigating the preferential flow path of a debris flow is crucial for quantifying the risk and developing mitigation strategies. Here, we examined 66 debris flows from the Western Ghats in India employing Rapid Mass Movement Simulation (RAMMS)::Debris Flow software to understand the kinematics of run-out. Our analysis revealed that the debris flow run-out in the study area follow two main routes: 60 along the existing stream channels (SC) and six following the steepest hill slope (SH). We further simulated these debris flows to identify their drivers, and derived a threshold that distinguishes between SC and SH-type debris flows. Our results indicate that the debris flow volumes greater than 7072 cu. m is SH-type, whereas those with smaller volumes are more likely to follow SC paths. The model’s accuracy was validated against field observations, achieving a success rate of 93% for SH-type flows and 85% for SC.

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Predicting debris flow pathways using volume-based thresholds for effective risk assessment

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