Your search keyword '"Banerjee, Tirtha"' showing total 21 results

1. Historical spatiotemporal changes in fire danger potential across biomes.

Author

Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Le, Phong VV, Foufoula-Georgiou, Efi, Banerjee, Tirtha, Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Le, Phong VV, Foufoula-Georgiou, Efi, and Banerjee, Tirtha

Abstract

This study 1) identifies the seasons and biomes that exhibit significant (1980-2019) changes in fire danger potential, as quantified by the Canadian Fire Weather Index (FWI); 2) explores what types of fire behavior potentials may be contributing to changes in fire danger potential, as quantified by the United States Energy Release Component (ERC) and the Ignition Component (IC); 3) provides spatiotemporal insight on how fire danger potential and fire behavior potential are responding in relation to changes in seasonal precipitation totals and seasonal mean air temperature across biomes. Time series of these fire potentials, as well as seasonal mean temperature, and seasonal precipitation totals are generated using data from the 0.25° ECMWF spatial resolution Reanalysis 5th Generation (ERA5) and the Climatic Research Unit gridded Time Series (CRU TS). The Mann-Kendall test is then applied to identify significant spatiotemporal trends across each biome. Results indicate that the September-November season (SON) exhibits the greatest rate of increase in fire danger potential, followed by the June-August season (JJA), December, January-February season (DJF), and March-May season (MAM), and this is predominant over the Tropical and Subtropical Moist Broadleaf Forest Biome, as well as all vegetation types of the temperate biomes. Similarly, the temperate biomes experience the greatest rate of increase in fire intensity potential and ignition potential, but prevalent during the DJF and MAM seasons. Furthermore, there is a significant positive correlation between fire danger potential and seasonal mean air temperature during JJA in the Northern Hemisphere for the temperate biomes in North America and Europe, as well as the Tropical and Subtropical biomes in Africa. Our analysis provides quantitative insight as to how fire danger potential and fire behavior potential have been responding to changes in seasonal mean temperature and seasonal precipitation totals across differen

Published

2023

2. Quantifying the effectiveness of shaded fuel breaks from ground-based, aerial, and spaceborne observations

Author

Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Martinez, Alexandre, York, Robert A, Foufoula-Georgiou, Efi, AghaKouchak, Amir, Banerjee, Tirtha, Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Martinez, Alexandre, York, Robert A, Foufoula-Georgiou, Efi, AghaKouchak, Amir, and Banerjee, Tirtha

Abstract

Shaded fuel breaks are treatments that aim to mitigate wildfires by establishing linearly aligned locations where wildfire suppression efforts can be more effective at stopping wildfires. Despite the potential of fuel breaks to alter fire behavior, there have been limited quantitative assessments of their effectiveness following exposure to wildfires. In addition, wildfires often occur in complex terrains that are difficult to access with ground vehicles and sensors, posing challenges for data acquisition. However, the use of Remote-controlled Aerial Vehicles (RAVs), such as drones, is becoming increasingly popular as a viable means of conducting high-resolution observations in areas of interest. This study presents the results from a unique opportunity to utilize three distinct observation scale platforms (in-situ, aerial, and spaceborne) to investigate the burn severity impacts across a prior shaded fuel break that serendipitously encountered the 2020 Creek Fire in the Sierra Nevada forests of California, USA. To provide a direct measure of fire severity, ground-based measurements determined the percentage crown volume (PCV) of scorch and char as a function of distance from the fuel break edge. Along five transects of the fuel break, we also utilized visible bands from drone imagery and digital photogrammetry, to generate georeferenced orthophotos and quantify vegetation health using the Green Leaf Index (GLI). We also quantified burn severity by computing the Delta Normalized Burn Ratio (dNBR) and vegetation health using the Normalized Difference Vegetation Index (NDVI) from Sentinel 2 spaceborne observations. Our results indicate that within the fuel break, the PCV of char is 2 × less than it was outside of it (with PCV char declining at a rate of 2% per 3 m into the fuel break). Burn severity is 5 × less, and vegetation health is approximately 3 × greater within the fuel break compared to directly outside. Furthermore, postfire vegetation health was only 1 × le

Published

2023

3. Features of turbulence during wildland fires in forested and grassland environments

Author

Desai, Ajinkya, Desai, Ajinkya, Heilman, Warren E, Skowronski, Nicholas S, Clark, Kenneth L, Gallagher, Michael R, Clements, Craig B, Banerjee, Tirtha, Desai, Ajinkya, Desai, Ajinkya, Heilman, Warren E, Skowronski, Nicholas S, Clark, Kenneth L, Gallagher, Michael R, Clements, Craig B, and Banerjee, Tirtha

Abstract

Fire-induced turbulence and the feedback into the fire, following ambient changes, differ for forested (sub-canopy) and grassland environments. Here, we synthesize observations from multiple experimental surface fires: two sub-canopy backing fires, one sub-canopy heading fire, and a grassland heading fire. We identify and compare the most essential coherent structures and processes of each case from the turbulent momentum fluxes and turbulent kinetic energy (TKE) budget terms. In the sub-canopy burns, turbulent eddies are strongest near the canopy top: high streamwise turbulent flux accompanies low cross-stream turbulent flux and vice versa. In the grassland fire, both streamwise and cross-stream eddies strengthen simultaneously until a certain height, informing a vertical length scale for the fire-influence. Moreover, the forward sweep from streamwise eddies assists in the fire spread by pushing hot gases towards unburnt fuel. In the sub-canopy fires, shear production and buoyancy production are more substantial near the canopy top for more intense fires, while their magnitudes decrease with decreasing fire intensity. At mid-canopy-height scales, buoyancy production dominates shear production, becoming the key mechanism for vertical transport of TKE. In the grassland fire, shear production dominates buoyancy production near the surface and is insignificant beyond a certain height relative to the flame length, while buoyancy production increases with height, becoming substantial further away from the surface. Turbulent transport terms are also active in both environments. For intense sub-canopy fires, there is a loss in TKE due to its expulsion to the boundary layer aloft via the transport term, compensated by a reversal process: TKE influx via the transport term. In the grassland fire, the transport term mimics this behavior until a certain height. The insights into the relative significance of the respective turbulent fluxes and TKE budget terms in each environmen

Published

2023

4. Effects of canopy midstory management and fuel moisture on wildfire behavior.

Author

Banerjee, Tirtha, Banerjee, Tirtha, Heilman, Warren, Goodrick, Scott, Hiers, J Kevin, Linn, Rod, Banerjee, Tirtha, Banerjee, Tirtha, Heilman, Warren, Goodrick, Scott, Hiers, J Kevin, and Linn, Rod

Abstract

Increasing trends in wildfire severity can partly be attributed to fire exclusion in the past century which led to higher fuel accumulation. Mechanical thinning and prescribed burns are effective techniques to manage fuel loads and to establish a higher degree of control over future fire risk, while restoring fire prone landscapes to their natural states of succession. However, given the complexity of interactions between fine scale fuel heterogeneity and wind, it is difficult to assess the success of thinning operations and prescribed burns. The present work addresses this issue systematically by simulating a simple fire line and propagating through a vegetative environment where the midstory has been cleared in different degrees, leading to a canopy with almost no midstory, another with a sparse midstory and another with a dense midstory. The simulations are conducted for these three canopies under two different conditions, where the fuel moisture is high and where it is low. These six sets of simulations show widely different fire behavior, in terms of fire intensity, spread rate and consumption. To understand the physical mechanisms that lead to these differences, detailed analyses are conducted to look at wind patterns, mean flow and turbulent fluxes of momentum and energy. The analyses also lead to improved understanding of processes leading to high intensity crowning behavior in presence of a dense midstory. Moreover, this work highlights the importance of considering fine scale fuel heterogeneity, seasonality, wind effects and the associated fire-canopy-atmosphere interactions while considering prescribed burns and forest management operations.

Published

2020

5. Effects of canopy midstory management and fuel moisture on wildfire behavior.

Author

Banerjee, Tirtha, Banerjee, Tirtha, Heilman, Warren, Goodrick, Scott, Hiers, J Kevin, Linn, Rod, Banerjee, Tirtha, Banerjee, Tirtha, Heilman, Warren, Goodrick, Scott, Hiers, J Kevin, and Linn, Rod

Abstract

Increasing trends in wildfire severity can partly be attributed to fire exclusion in the past century which led to higher fuel accumulation. Mechanical thinning and prescribed burns are effective techniques to manage fuel loads and to establish a higher degree of control over future fire risk, while restoring fire prone landscapes to their natural states of succession. However, given the complexity of interactions between fine scale fuel heterogeneity and wind, it is difficult to assess the success of thinning operations and prescribed burns. The present work addresses this issue systematically by simulating a simple fire line and propagating through a vegetative environment where the midstory has been cleared in different degrees, leading to a canopy with almost no midstory, another with a sparse midstory and another with a dense midstory. The simulations are conducted for these three canopies under two different conditions, where the fuel moisture is high and where it is low. These six sets of simulations show widely different fire behavior, in terms of fire intensity, spread rate and consumption. To understand the physical mechanisms that lead to these differences, detailed analyses are conducted to look at wind patterns, mean flow and turbulent fluxes of momentum and energy. The analyses also lead to improved understanding of processes leading to high intensity crowning behavior in presence of a dense midstory. Moreover, this work highlights the importance of considering fine scale fuel heterogeneity, seasonality, wind effects and the associated fire-canopy-atmosphere interactions while considering prescribed burns and forest management operations.

Published

2020

6. Mapping the wildland-urban interface in California using remote sensing data.

Author

Li, Shu, Li, Shu, Dao, Vu, Kumar, Mukesh, Nguyen, Phu, Banerjee, Tirtha, Li, Shu, Li, Shu, Dao, Vu, Kumar, Mukesh, Nguyen, Phu, and Banerjee, Tirtha

Abstract

Due to the mixed distribution of buildings and vegetation, wildland-urban interface (WUI) areas are characterized by complex fuel distributions and geographical environments. The behavior of wildfires occurring in the WUI often leads to severe hazards and significant damage to man-made structures. Therefore, WUI areas warrant more attention during the wildfire season. Due to the ever-changing dynamic nature of California's population and housing, the update frequency and resolution of WUI maps that are currently used can no longer meet the needs and challenges of wildfire management and resource allocation for suppression and mitigation efforts. Recent developments in remote sensing technology and data analysis algorithms pose new opportunities for improving WUI mapping methods. WUI areas in California were directly mapped using building footprints extracted from remote sensing data by Microsoft along with the fuel vegetation cover from the LANDFIRE dataset in this study. To accommodate the new type of datasets, we developed a threshold criteria for mapping WUI based on statistical analysis, as opposed to using more ad-hoc criteria as used in previous mapping approaches. This method removes the reliance on census data in WUI mapping, and does not require the calculation of housing density. Moreover, this approach designates the adjacent areas of each building with large and dense parcels of vegetation as WUI, which can not only refine the scope and resolution of the WUI areas to individual buildings, but also avoids zoning issues and uncertainties in housing density calculation. Besides, the new method has the capability of updating the WUI map in real-time according to the operational needs. Therefore, this method is suitable for local governments to map local WUI areas, as well as formulating detailed wildfire emergency plans, evacuation routes, and management measures.

Published

2022

7. Historical seasonal changes in prescribed burn windows in California.

Author

Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Li, Shu, Martinez, Alexandre, Kumar, Mukesh, Quinn-Davidson, Lenya N, York, Robert A, Banerjee, Tirtha, Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Li, Shu, Martinez, Alexandre, Kumar, Mukesh, Quinn-Davidson, Lenya N, York, Robert A, and Banerjee, Tirtha

Abstract

Prescribed (Rx) burns are conducted on days when the meteorological thresholds of maximum air temperature, relative humidity, and wind speeds are all met (burn window) in order to ensure safe Rx burn practices. Limited burn windows have been consistently identified as one of the most important constraints for conducting Rx burns in California. We investigate whether burn windows across California can be extended from the typical fall season to include other opportune seasons for facilitating specific management objectives. We quantify the seasonal Rx burn efficiencies by assessing the frequency and burned areas using an aggregate of Rx datasets, and we compute the seasonal spatiotemporal trends in the number of days the set of meteorological parameters are met over thirty-five years (1984 to 2019) using the gridMET 4 km dataset. Our results indicate that while fall burns are most frequently executed (40% of the time), the spring (and to a lesser extent winter) seasons yield efficient Rx burns similar to fall, because greater acres are being consumed with less burns. In addition, winter and spring seasons experience burn window opportunities (70-90% of the time) over larger areas than the other seasons, and this is predominantly over forested regions in Northern California. Our results also indicate that burn windows in the winter and spring are decreasing at a rate of one day per year over a larger spatial area than that of summer and fall. This decrease is primarily driven by changes in the number of days the relative humidity thresholds are met. Policymakers recognize the critical importance Rx burns have on a multitude of ecosystem restoration factors, fire behavior dynamics, and firefighter safety. Therefore, there is a need to capitalize on these additional burn window seasons before these opportunities become less feasible in the future.

Published

2022

8. Investigating the turbulent dynamics of small-scale surface fires.

Author

Desai, Ajinkya, Desai, Ajinkya, Goodrick, Scott, Banerjee, Tirtha, Desai, Ajinkya, Desai, Ajinkya, Goodrick, Scott, and Banerjee, Tirtha

Abstract

High frequency (30 Hz) two-dimensional particle image velocimetry data recorded during a field experiment exploring fire spread from point ignition in hand-spread pine needles under calm ambient wind conditions are analysed in this study. In the initial stages, as the flame spreads approximately radially away from the ignition point in the absence of a preferred wind-forcing direction, it entrains cooler ambient air into the warmer fire core, thereby experiencing a dynamic pressure resistance. The fire-front, comprising a flame that is tilted inward, is surrounded by a region of downdraft. Coherent structures describe the initial shape of the fire-front and its response to local wind shifts while also revealing possible fire-spread mechanisms. Vortex tubes originating outside the fire spiral inward and get stretched thinner at the fire-front leading to higher vorticity there. These tubes comprise circulation structures that induce a radially outward velocity close to the fuel bed, which pushes hot gases outward, thereby causing the fire to spread. Moreover, these circulation structures confirm the presence of counter-rotating vortex pairs that are known to be a key mechanism for fire spread. The axis of the vortex tubes changes its orientation alternately towards and away from the surface of the fuel bed, causing the vortex tubes to be kinked. The strong updraft observed at the location of the fire-front could potentially advect and tilt the kinked vortex tube vertically upward leading to fire-whirl formation. As the fire evolves, its perimeter disintegrates in response to flow instabilities to form smaller fire "pockets". These pockets are confined to certain points in the flow field that remain relatively fixed for a while and resemble the behavior of a chaotic system in the vicinity of an attractor. Increased magnitudes of the turbulent fluxes of horizontal momentum, computed at certain such fixed points along the fire-front, are symptomatic of irregular fir

Published

2022

9. Mapping the wildland-urban interface in CA using remote sensing data

Author

Li, Shu, Li, Shu, Dao, Vu, Kumar, Mukesh, Nguyen, Phu, Banerjee, Tirtha, Li, Shu, Li, Shu, Dao, Vu, Kumar, Mukesh, Nguyen, Phu, and Banerjee, Tirtha

Published

2022

10. Investigating the turbulent dynamics of small-scale surface fires.

Author

Desai, Ajinkya, Desai, Ajinkya, Goodrick, Scott, Banerjee, Tirtha, Desai, Ajinkya, Desai, Ajinkya, Goodrick, Scott, and Banerjee, Tirtha

Abstract

High frequency (30 Hz) two-dimensional particle image velocimetry data recorded during a field experiment exploring fire spread from point ignition in hand-spread pine needles under calm ambient wind conditions are analysed in this study. In the initial stages, as the flame spreads approximately radially away from the ignition point in the absence of a preferred wind-forcing direction, it entrains cooler ambient air into the warmer fire core, thereby experiencing a dynamic pressure resistance. The fire-front, comprising a flame that is tilted inward, is surrounded by a region of downdraft. Coherent structures describe the initial shape of the fire-front and its response to local wind shifts while also revealing possible fire-spread mechanisms. Vortex tubes originating outside the fire spiral inward and get stretched thinner at the fire-front leading to higher vorticity there. These tubes comprise circulation structures that induce a radially outward velocity close to the fuel bed, which pushes hot gases outward, thereby causing the fire to spread. Moreover, these circulation structures confirm the presence of counter-rotating vortex pairs that are known to be a key mechanism for fire spread. The axis of the vortex tubes changes its orientation alternately towards and away from the surface of the fuel bed, causing the vortex tubes to be kinked. The strong updraft observed at the location of the fire-front could potentially advect and tilt the kinked vortex tube vertically upward leading to fire-whirl formation. As the fire evolves, its perimeter disintegrates in response to flow instabilities to form smaller fire "pockets". These pockets are confined to certain points in the flow field that remain relatively fixed for a while and resemble the behavior of a chaotic system in the vicinity of an attractor. Increased magnitudes of the turbulent fluxes of horizontal momentum, computed at certain such fixed points along the fire-front, are symptomatic of irregular fir

Published

2022

11. Reimagine fire science for the anthropocene

Author

Shuman, Jacquelyn K, Nelson, Karen E1, Shuman, Jacquelyn K, Balch, Jennifer K, Barnes, Rebecca T, Higuera, Philip E, Roos, Christopher I, Schwilk, Dylan W, Stavros, E Natasha, Banerjee, Tirtha, Bela, Megan M, Bendix, Jacob, Bertolino, Sandro, Bililign, Solomon, Bladon, Kevin D, Brando, Paulo, Breidenthal, Robert E, Buma, Brian, Calhoun, Donna, Carvalho, Leila MV, Cattau, Megan E, Cawley, Kaelin M, Chandra, Sudeep, Chipman, Melissa L, Cobian-Iñiguez, Jeanette, Conlisk, Erin, Coop, Jonathan D, Cullen, Alison, Davis, Kimberley T, Dayalu, Archana, De Sales, Fernando, Dolman, Megan, Ellsworth, Lisa M, Franklin, Scott, Guiterman, Christopher H, Hamilton, Matthew, Hanan, Erin J, Hansen, Winslow D, Hantson, Stijn, Harvey, Brian J, Holz, Andrés, Huang, Tao, Hurteau, Matthew D, Ilangakoon, Nayani T, Jennings, Megan, Jones, Charles, Klimaszewski-Patterson, Anna, Kobziar, Leda N, Kominoski, John, Kosovic, Branko, Krawchuk, Meg A, Laris, Paul, Leonard, Jackson, Loria-Salazar, S Marcela, Lucash, Melissa, Mahmoud, Hussam, Margolis, Ellis, Maxwell, Toby, McCarty, Jessica L, McWethy, David B, Meyer, Rachel S, Miesel, Jessica R, Moser, W Keith, Nagy, R Chelsea, Niyogi, Dev, Palmer, Hannah M, Pellegrini, Adam, Poulter, Benjamin, Robertson, Kevin, Rocha, Adrian V, Sadegh, Mojtaba, Santos, Fernanda, Scordo, Facundo, Sexton, Joseph O, Sharma, A Surjalal, Smith, Alistair MS, Soja, Amber J, Still, Christopher, Swetnam, Tyson, Syphard, Alexandra D, Tingley, Morgan W, Tohidi, Ali, Trugman, Anna T, Turetsky, Merritt, Varner, J Morgan, Wang, Yuhang, Whitman, Thea, Yelenik, Stephanie, Zhang, Xuan, Shuman, Jacquelyn K, Nelson, Karen E1, Shuman, Jacquelyn K, Balch, Jennifer K, Barnes, Rebecca T, Higuera, Philip E, Roos, Christopher I, Schwilk, Dylan W, Stavros, E Natasha, Banerjee, Tirtha, Bela, Megan M, Bendix, Jacob, Bertolino, Sandro, Bililign, Solomon, Bladon, Kevin D, Brando, Paulo, Breidenthal, Robert E, Buma, Brian, Calhoun, Donna, Carvalho, Leila MV, Cattau, Megan E, Cawley, Kaelin M, Chandra, Sudeep, Chipman, Melissa L, Cobian-Iñiguez, Jeanette, Conlisk, Erin, Coop, Jonathan D, Cullen, Alison, Davis, Kimberley T, Dayalu, Archana, De Sales, Fernando, Dolman, Megan, Ellsworth, Lisa M, Franklin, Scott, Guiterman, Christopher H, Hamilton, Matthew, Hanan, Erin J, Hansen, Winslow D, Hantson, Stijn, Harvey, Brian J, Holz, Andrés, Huang, Tao, Hurteau, Matthew D, Ilangakoon, Nayani T, Jennings, Megan, Jones, Charles, Klimaszewski-Patterson, Anna, Kobziar, Leda N, Kominoski, John, Kosovic, Branko, Krawchuk, Meg A, Laris, Paul, Leonard, Jackson, Loria-Salazar, S Marcela, Lucash, Melissa, Mahmoud, Hussam, Margolis, Ellis, Maxwell, Toby, McCarty, Jessica L, McWethy, David B, Meyer, Rachel S, Miesel, Jessica R, Moser, W Keith, Nagy, R Chelsea, Niyogi, Dev, Palmer, Hannah M, Pellegrini, Adam, Poulter, Benjamin, Robertson, Kevin, Rocha, Adrian V, Sadegh, Mojtaba, Santos, Fernanda, Scordo, Facundo, Sexton, Joseph O, Sharma, A Surjalal, Smith, Alistair MS, Soja, Amber J, Still, Christopher, Swetnam, Tyson, Syphard, Alexandra D, Tingley, Morgan W, Tohidi, Ali, Trugman, Anna T, Turetsky, Merritt, Varner, J Morgan, Wang, Yuhang, Whitman, Thea, Yelenik, Stephanie, and Zhang, Xuan

Abstract

Fire is an integral component of ecosystems globally and a tool that humans have harnessed for millennia. Altered fire regimes are a fundamental cause and consequence of global change, impacting people and the biophysical systems on which they depend. As part of the newly emerging Anthropocene, marked by human-caused climate change and radical changes to ecosystems, fire danger is increasing, and fires are having increasingly devastating impacts on human health, infrastructure, and ecosystem services. Increasing fire danger is a vexing problem that requires deep transdisciplinary, trans-sector, and inclusive partnerships to address. Here, we outline barriers and opportunities in the next generation of fire science and provide guidance for investment in future research. We synthesize insights needed to better address the long-standing challenges of innovation across disciplines to (i) promote coordinated research efforts; (ii) embrace different ways of knowing and knowledge generation; (iii) promote exploration of fundamental science; (iv) capitalize on the “firehose” of data for societal benefit; and (v) integrate human and natural systems into models across multiple scales. Fire science is thus at a critical transitional moment. We need to shift from observation and modeled representations of varying components of climate, people, vegetation, and fire to more integrative and predictive approaches that support pathways toward mitigating and adapting to our increasingly flammable world, including the utilization of fire for human safety and benefit. Only through overcoming institutional silos and accessing knowledge across diverse communities can we effectively undertake research that improves outcomes in our more fiery future.

Published

2022

12. Mapping the wildland-urban interface in California using remote sensing data.

Author

Li, Shu, Li, Shu, Dao, Vu, Kumar, Mukesh, Nguyen, Phu, Banerjee, Tirtha, Li, Shu, Li, Shu, Dao, Vu, Kumar, Mukesh, Nguyen, Phu, and Banerjee, Tirtha

Abstract

Due to the mixed distribution of buildings and vegetation, wildland-urban interface (WUI) areas are characterized by complex fuel distributions and geographical environments. The behavior of wildfires occurring in the WUI often leads to severe hazards and significant damage to man-made structures. Therefore, WUI areas warrant more attention during the wildfire season. Due to the ever-changing dynamic nature of California's population and housing, the update frequency and resolution of WUI maps that are currently used can no longer meet the needs and challenges of wildfire management and resource allocation for suppression and mitigation efforts. Recent developments in remote sensing technology and data analysis algorithms pose new opportunities for improving WUI mapping methods. WUI areas in California were directly mapped using building footprints extracted from remote sensing data by Microsoft along with the fuel vegetation cover from the LANDFIRE dataset in this study. To accommodate the new type of datasets, we developed a threshold criteria for mapping WUI based on statistical analysis, as opposed to using more ad-hoc criteria as used in previous mapping approaches. This method removes the reliance on census data in WUI mapping, and does not require the calculation of housing density. Moreover, this approach designates the adjacent areas of each building with large and dense parcels of vegetation as WUI, which can not only refine the scope and resolution of the WUI areas to individual buildings, but also avoids zoning issues and uncertainties in housing density calculation. Besides, the new method has the capability of updating the WUI map in real-time according to the operational needs. Therefore, this method is suitable for local governments to map local WUI areas, as well as formulating detailed wildfire emergency plans, evacuation routes, and management measures.

Published

2022

13. Historical seasonal changes in prescribed burn windows in California.

Author

Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Li, Shu, Martinez, Alexandre, Kumar, Mukesh, Quinn-Davidson, Lenya N, York, Robert A, Banerjee, Tirtha, Baijnath-Rodino, Janine A, Baijnath-Rodino, Janine A, Li, Shu, Martinez, Alexandre, Kumar, Mukesh, Quinn-Davidson, Lenya N, York, Robert A, and Banerjee, Tirtha

Abstract

Prescribed (Rx) burns are conducted on days when the meteorological thresholds of maximum air temperature, relative humidity, and wind speeds are all met (burn window) in order to ensure safe Rx burn practices. Limited burn windows have been consistently identified as one of the most important constraints for conducting Rx burns in California. We investigate whether burn windows across California can be extended from the typical fall season to include other opportune seasons for facilitating specific management objectives. We quantify the seasonal Rx burn efficiencies by assessing the frequency and burned areas using an aggregate of Rx datasets, and we compute the seasonal spatiotemporal trends in the number of days the set of meteorological parameters are met over thirty-five years (1984 to 2019), using the gridMET 4 km dataset. Our results indicate that while fall burns are most frequently executed (40% of the time), the spring (and to a lesser extent winter) seasons yield efficient Rx burns similar to fall because greater acres are being consumed with less burns. In addition, winter and spring seasons experience burn window opportunities (70-90% of the time) over larger areas than the other seasons, and this is predominantly over forested regions in Northern California. Our results also indicate that burn windows in the winter and spring are decreasing at a rate of one day per year over a larger spatial area than that of summer and fall. This decrease is primarily driven by changes in the number of days the relative humidity thresholds are met. Policymakers recognize the critical importance that Rx burns have on a multitude of ecosystem restoration factors, fire behavior dynamics, and firefighter safety. Therefore, there is a need to capitalize on these additional burn windows before these opportunities become less feasible in the future.

Published

2022

14. On the Viability of Quantum Annealers to Solve Fluid Flows

Author

Ray, Navamita, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balu, Karra, Satish, Ray, Navamita, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balu, and Karra, Satish

Abstract

This paper explores the suitability of upcoming novel computing technologies, particularly adiabatic annealing based quantum computers, to solve fluid dynamics problems that form a critical component of several science and engineering applications. For our experiments, we start with a well-studied one-dimensional simple flow problem, and provide a framework to convert such problems in continuum to a form amenable for deployment on such quantum annealers. Since the DWave annealer returns multiple states sampling the energy landscape of the problem, we explore multiple solution selection strategies to approximate the solution of the problem. We analyze the continuum solutions obtained both qualitatively and quantitatively as well as their sensitivities to the particular solution selection scheme.

Published

2022

15. Spatial and temporal pattern of wildfires in California from 2000 to 2019.

Author

Li, Shu, Li, Shu, Banerjee, Tirtha, Li, Shu, Li, Shu, and Banerjee, Tirtha

Abstract

The environmental pollution, property losses and casualties caused by wildfires in California are getting worse by the year. To minimize the interference of wildfires on economic and social development, and formulate targeted mitigation strategies, it is imperative to understand the scale and extent of previous wildfire occurrences. In this study, we first investigated the temporal distributions of past wildfires in California divided by size and causes and analyzed the changes observed in the past two decades against the last century. The trend of wildfires in different time scales (yearly and monthly), as well as the distribution of wildfires across different spatial scales (administrative units, climate divisions in California from 2000 to 2019) were also studied. Furthermore, to extract the significant variables on the risk of wildfire occurrence, multivariate analyses of environmental and human-related variables with wildfire densities were carried out. The results show that the wildfire density distribution of the burned area in California conforms to the characteristics of the Pareto distribution. Over the past two decades, the frequency of small (< 500 acres), human-caused wildfires has increased most rapidly, and they are widely distributed in central and western California. The wildfire season has lengthened and the peak months have been advanced from August to July. In terms of the variables related to the risk of wildfire occurrence, the temperature, vapor pressure deficit, grass cover, and the distance to roads are crucial. This study reveals the relationship between environmental and social background conditions and the spatial-temporal distribution of wildfires, which can provide a reference for wildfire management, the formulation of future targeted wildfire emergency plans, and the planning of future land use in California.

Published

2021

16. Spatial and temporal pattern of wildfres in California from 2000 to 2019

Author

Li, Shu, Li, Shu, Banerjee, Tirtha, Li, Shu, Li, Shu, and Banerjee, Tirtha

Published

2021

17. Spatial and temporal pattern of wildfires in California from 2000 to 2019.

Author

Li, Shu, Li, Shu, Banerjee, Tirtha, Li, Shu, Li, Shu, and Banerjee, Tirtha

Abstract

The environmental pollution, property losses and casualties caused by wildfires in California are getting worse by the year. To minimize the interference of wildfires on economic and social development, and formulate targeted mitigation strategies, it is imperative to understand the scale and extent of previous wildfire occurrences. In this study, we first investigated the temporal distributions of past wildfires in California divided by size and causes and analyzed the changes observed in the past two decades against the last century. The trend of wildfires in different time scales (yearly and monthly), as well as the distribution of wildfires across different spatial scales (administrative units, climate divisions in California from 2000 to 2019) were also studied. Furthermore, to extract the significant variables on the risk of wildfire occurrence, multivariate analyses of environmental and human-related variables with wildfire densities were carried out. The results show that the wildfire density distribution of the burned area in California conforms to the characteristics of the Pareto distribution. Over the past two decades, the frequency of small (< 500 acres), human-caused wildfires has increased most rapidly, and they are widely distributed in central and western California. The wildfire season has lengthened and the peak months have been advanced from August to July. In terms of the variables related to the risk of wildfire occurrence, the temperature, vapor pressure deficit, grass cover, and the distance to roads are crucial. This study reveals the relationship between environmental and social background conditions and the spatial-temporal distribution of wildfires, which can provide a reference for wildfire management, the formulation of future targeted wildfire emergency plans, and the planning of future land use in California.

Published

2021

18. Spatial and temporal pattern of wildfres in California from 2000 to 2019

Author

Li, Shu, Li, Shu, Banerjee, Tirtha, Li, Shu, Li, Shu, and Banerjee, Tirtha

Published

2021

19. Towards Solving the Navier-Stokes Equation on Quantum Computers

Author

Ray, Navamita, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balasubramanya, Karra, Satish, Ray, Navamita, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balasubramanya, and Karra, Satish

Abstract

In this paper, we explore the suitability of upcoming novel computing technologies, in particular adiabatic annealing based quantum computers, to solve fluid dynamics problems that form a critical component of several science and engineering applications. We start with simple flows with well-studied flow properties, and provide a framework to convert such systems to a form amenable for deployment on such quantum annealers. We analyze the solutions obtained both qualitatively and quantitatively as well as the sensitivities of the various solution selection schemes on the obtained solution.

Published

2019

20. Towards Solving the Navier-Stokes Equation on Quantum Computers

Author

Ray, Navamita, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balasubramanya, Karra, Satish, Ray, Navamita, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balasubramanya, and Karra, Satish

Abstract

In this paper, we explore the suitability of upcoming novel computing technologies, in particular adiabatic annealing based quantum computers, to solve fluid dynamics problems that form a critical component of several science and engineering applications. We start with simple flows with well-studied flow properties, and provide a framework to convert such systems to a form amenable for deployment on such quantum annealers. We analyze the solutions obtained both qualitatively and quantitatively as well as the sensitivities of the various solution selection schemes on the obtained solution.

Published

2019

21. Towards Solving the Navier-Stokes Equation on Quantum Computers

Author

Ray, Navamita, Banerjee, Tirtha, Nadiga, Balasubramanya, Karra, Satish, Ray, Navamita, Banerjee, Tirtha, Nadiga, Balasubramanya, and Karra, Satish

Abstract

In this paper, we explore the suitability of upcoming novel computing technologies, in particular adiabatic annealing based quantum computers, to solve fluid dynamics problems that form a critical component of several science and engineering applications. We start with simple flows with well-studied flow properties, and provide a framework to convert such systems to a form amenable for deployment on such quantum annealers. We analyze the solutions obtained both qualitatively and quantitatively as well as the sensitivities of the various solution selection schemes on the obtained solution.

Published

2019