New Biomass Estimates for Chaparral-Dominated Southern California Landscapes

Schrader-Patton, Charlie; Underwood, Emma C.

doi:10.3390/rs13081581

Cited by 9 publications

(5 citation statements)

References 73 publications

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“…Remote sensing has been used to assess the impacts of drought on chaparral communities (Dong et al, 2019), estimate changes in biomass (Schrader‐Patton & Underwood, 2021), and monitor changes over time (Coates et al, 2015; Gillespie et al, 2018). To assess the spatial extent of chaparral dieback that occurred following the drought of 2011–2017, and prior to the Thomas and Woolsey Fires, we used Landsat 4/5/7/8 surface reflectance NDVI data (normalized difference vegetation index) data to quantify changes in green biomass or living vegetation.…”

Section: Methodsmentioning

confidence: 99%

The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral

2022

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Drought contributed to extensive dieback of southern California chaparral, and normalized difference vegetation index before drought and near the end of the drought was used to estimate this dieback, after accounting for other disturbances recorded in aerial photographs. Within the perimeters of two megafires that occurred after the drought, the 2017 Thomas Fire and the 2018 Woolsey Fire, there had been extensive areas of dieback. Comparing dieback with Monitoring Trends in Burn Severity measures of fire severity, there was a highly significant negative relationship between drought-caused shrub dieback and fire-caused dieback as measured by fire severity. We interpret this as further support for our remote sensing methodology for prefire dieback. Models of fire behavior suggest that one means by which dieback contributes to fire size is through increasing the density and distance of spot fires, particularly under extreme wind conditions. Lower elevation chaparral associations appear to be most vulnerable and are closer to urban environments, which should be a concern to fire managers in regions subjected to extended droughts.

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Section: Methodsmentioning

confidence: 99%

The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral

2022

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“…For example, in the nearshore SBC surface waters, atmospheric nitrogen deposition from natural and anthropogenic sources was estimated to account for the largest annually integrated nitrogen flux (430 kg N km −2 yr −1 ) [ 52 ]. Spatio-temporal complexity of atmospheric aerosol deposition precludes precise quantification of Thomas Fire ash deposition to the SBC; however, based on the area burned [ 8 ], average above-ground live biomass (4.2 kg m −2 ) [ 54 ], and assuming 75–100% of vegetation was consumed with 50–80% of biomass undergoing complete combustion [ 40 ] we estimate that 0.7 × 10 9 –2.4 × 10 9 kg of ash was produced by the Thomas Fire. If all ash produced was deposited throughout the SBC (approx.…”

Section: Discussionmentioning

confidence: 99%

Food for all? Wildfire ash fuels growth of diverse eukaryotic plankton

Ladd,

Catlett,

Maniscalco

et al. 2023

Proc. R. Soc. B.

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In December 2017, one of the largest wildfires in California history, the Thomas Fire, created a large smoke and ash plume that extended over the northeastern Pacific Ocean. Here, we explore the impact of Thomas Fire ash deposition on seawater chemistry and the growth and composition of natural microbial communities. Experiments conducted in coastal California waters during the Thomas Fire revealed that leaching of ash in seawater resulted in significant additions of dissolved nutrients including inorganic nitrogen (nitrate, nitrite and ammonium), silicic acid, metals (iron, nickel, cobalt and copper), organic nitrogen and organic carbon. After exposure to ash leachate at high (0.25 g ash l −1 ) and low (0.08 g ash l −1 ) concentrations for 4 days, natural microbial communities had 59–154% higher particulate organic carbon concentrations than communities without ash leachate additions. Additionally, a diverse assemblage of eukaryotic microbes (protists) responded to the ash leachate with taxa from 11 different taxonomic divisions increasing in relative abundance compared with control treatments. Our results suggest that large fire events can be important atmospheric sources of nutrients (particularly nitrogen) to coastal marine systems, where, through leaching of various nutrients, ash may act as a ‘food for all’ in protist communities.

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“…After a fire occurrence, different development stages of the shrub vegetation can be found: areas with low shrub development, others with high shrub development, and areas with only short shrubs or only high size shrubs. Regardless of the stage and structure, remote sensing and field data were used to estimate biomass in shrub areas in Portugal [8] and California [38], to identify changes in aboveground biomass after fire in the Amazon [39], and to evaluate vegetation recovery after fire in Siberia [40]. In this line, the methods can be considered suitable for the proposed objectives of the manuscript as it accurately estimated the carbon stock in small coppice areas.…”

Section: Discussionmentioning

confidence: 99%

Biomass Assessment and Carbon Sequestration in Post-Fire Shrublands by Means of Sentinel-2 and Gaussian Processes

Vinué-Visús

Ruíz-Peinado

Fuente

et al. 2022

Forests

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In this contribution, we assessed the biomass and carbon stock of a post-fire area covered by a young oak coppice of Quercus pyrenaica Willd. associated with shrubs, mainly of Cistus laurifolius L. This area was burned during the fire event of Chequilla (Guadalajara, Spain) in 2012. Sentinel-2 imagery was used together with our own forest inventories in 2020 and machine learning methods to assess the total biomass of the area. The inventory includes plots of total dry weight ranging between 6 and 14 Mg·ha−1 with individuals up to 8 years old. Nonlinear, nonparametric Gaussian process regression methods were applied to link reflectance values from Sentinel-2 imagery with total shrub biomass. With a reduced inventory of only 32 plots covering 136 ha, the total biomass could be assessed with a root-mean-square error of 1.36 Mg·ha−1 and a bias of −0.04 Mg·ha−1, getting a relative error between 9.8% and 20.4% for the gathered biomass. This is a rather good estimation considering the little effort and time invested; thus, the suggested methodology is very suitable for forest monitoring and management.

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New Biomass Estimates for Chaparral-Dominated Southern California Landscapes

Cited by 9 publications

References 73 publications

The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral

The effects of prolonged drought on vegetation dieback and megafires in southern California chaparral

Food for all? Wildfire ash fuels growth of diverse eukaryotic plankton

Biomass Assessment and Carbon Sequestration in Post-Fire Shrublands by Means of Sentinel-2 and Gaussian Processes

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