A Prefire Approach for Probabilistic Assessments of Postfire Debris‐Flow Inundation

Author:

Liu Tao12ORCID,McGuire Luke A.1ORCID,Youberg Ann M.3ORCID,Prescott Alexander B.1ORCID,Gorr Alexander N.1ORCID,Struble William T.1ORCID,Beers Rebecca3ORCID

Affiliation:

1. Department of Geosciences University of Arizona Tucson AZ USA

2. Earth and Environmental Sciences Division Los Alamos National Laboratory Los Alamos NM USA

3. Arizona Geological Survey University of Arizona Tucson AZ USA

Abstract

AbstractIncreases in wildfire activity and rainfall intensification are driving more postfire debris flows (PFDF) in many regions around the world. PFDFs are most common in the first postfire year and may even occur before a fire is fully controlled. This underscores the importance of assessing postfire hazards before a fire starts. Evaluation of PFDF hazards prior to fire can help strategize interventions lessening the negative effects of future fires. However, debris‐flow runout and inundation analyses are not routine in PFDF hazard assessments, partially due to time constraints and substantial uncertainties in boundary conditions. Here, we propose a prefire PFDF inundation assessment framework using a debris‐flow runout model based on the Herschel‐Bulkley (HB) rheology (HEC‐RAS v6.1). We constrain model inputs and parameters using Bayesian posterior analysis, rainfall‐runoff simulations, and a debris‐flow volume model. We use observations from recent PFDF incidents in northern Arizona, USA, to calibrate model components and then apply our prefire inundation assessment framework in a nearby unburned area. Specifically, we (a) identify yield stress as the most influential factor on inundation extent and arrival time in a HB model, (b) establish posterior distributions for model parameters suitable for forward modeling by leveraging uncertainties in field observations, and (c) implement a predictive forward analysis in an area that has not burned recently to evaluate PFDF inundation under several future fire scenarios. This study improves our ability to assess postfire debris‐flow hazards before a fire begins and provides guidance for future applications of single‐phase rheological models when assessing PFDF hazards.

Funder

Federal Emergency Management Agency

University of Arizona

Publisher

American Geophysical Union (AGU)

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