Prescribed Fire in a Florida Landscape with Mixed Ownership: Spatial Interactions

Geiger, Richelle

15 August 2012

Across the U.S., wildfires have become increasingly destructive and costly over the past few decades, with impacts particularly severe in the State of Florida. Because of an increase in wildfire frequency and severity and the number of people living in fire-prone areas the issue of wildfire risk management is of growing significance. One of the most important wildfire risk reduction tools is prescribed fire to reduce fuel loads, thereby reducing wildfire intensity and resulting damages. Because fire moves across a landscape and ownership boundaries, the spatial pattern of fuel load reduction may influence individual landowners' decisions about fire risk management on their own property. We develop and empirically test a spatial econometric model to study the interaction between Florida landowners in their wildfire risk management decisions. / Master of Science

Wildfire

Mixed ownership

Spatial econometrics

Biochar in Land Reclamation, Biosolids Applications and Prescribed Fires

Fields-Johnson, Christopher Warren

01 December 2016

Biochar is a form of stable organic carbon whose application to soils has the potential to sequester large amounts of atmospheric CO2 while improving the physical, chemical and biological properties of soil. However, the optimal rates and methods of biochar application are unknown for many situations. Three experiments were performed to test methods of biochar application to soils as a stand-alone amendment, in combination with biosolids as a complementary amendment and in-situ through controlled landscape burning. The first was a greenhouse pot study, which involved combining biochar with spoil from an Appalachian surface coal mine to grow trees. Biochar combined with mine soil produced a much higher growth rate for trees, and pure biochar helped tree root growth, suggesting that it might be useful as a broadcasted amendment, as a nursery growing medium or as a backfill in tree planting holes. The second experiment explored methods to combine biochar and biosolids materials to form a granular product. Combining biochar and biosolids before applications reduced windborne losses of biochar as well as the nutrient leachate produced by the biosolids. Drum rolling was found to work best for producing aggregate granules. Wetting pure biochar to 100% gravimetric water content before applications reduced windborne losses from over 50% to under 5% as compared to when it was applied as a dry product. A series of controlled burns were conducted in the third experiment to determine the ideal range of meteorological conditions to produce the highest possible biochar yields in-situ. Relative humidity, forest litter moisture and ambient temperature were found to be the governing factors over the tonnage of biochar produced. Up to 3.0 Mg Ha-1 of biochar were produced under ideal conditions by controlled burning. Repeated high-yielding burns have the potential accumulate large amounts of biochar in the soil to improve soil properties. / Ph. D.

Reforestation

Wildfire

Charcoal

Pelletization

Silvopasture

An integrated study of mechanical forest fuel reduction : quantifying multiple factors at the stand level /

Bolding, Michael Chad, 1977-

January 1900

Thesis (Ph. D.)--Oregon State University, 2007. / Printout. Includes bibliographical references. Also available on the World Wide Web.

Examining the Impacts of Wildfire on Throughfall and Stemflow Chemistry and Flux at Plot and Catchment Scales

White, Alissa Marie

January 2015

This study investigates the effects of fire on the chemistry and flux of precipitation diverted to the forest floor as stemflow and throughfall by observing the impact of the June 2013 Thompson Ridge Wildfire in the Jemez River Basin of New Mexico. The loss of canopy cover from wildfire drastically modifies landscapes and alters ecosystems as fire replaces leafy canopies with charred branches and trunks, changes soil composition and erosion processes, and affects hydrologic flow paths and water chemistry. In order to track these changes, throughfall and stemflow collectors were installed beneath burned and unburned canopies in two catchments impacted by the Thompson Ridge Fire. Throughfall, stemflow, and open precipitation samples were analyzed for major cations, anions, dissolved inorganic and organic carbon, trace metals, and rare earth elements to determine how fire affects the chemical composition of the precipitation that interacts with burned canopies. Precipitation samples collected from both burned and unburned sites during the 2014 summer monsoon season show variations across burn severity, specifically in calcium, strontium, phosphate, and dissolved inorganic carbon concentrations, and across collector type with stemflow concentrations generally higher than throughfall and open precipitation concentrations. A stem count model was used to determine tree density for individual plots and catchments from LiDAR images taken before the 2013 fire. The stem count model was used to upscale event and monsoon season solute fluxes from plot to catchment scale. Higher nutrient concentrations combined with higher volumes of precipitation diverted as stemflow in burned forests have a multiplicative effect resulting in greater nutrient fluxes via stemflow creating nutrient hot spots surrounding burned tree trunks. Upscaling these plot scale concentrations and solute fluxes allows this study to represent changes to an entire catchment and quantify effects of wildfire on chemical loads and water chemistry.

Solute Flux

Stemflow

Throughfall

Wildfire

Hydrology

Scale

FIREWISE Plant Materials for 3,000 ft. and Higher Elevations

Deneke, Fred, DeGomez, Tom, Schalau, Jeff, Jones, Chris

08 1900

4 pp.

fire

wildfire

firewise

forestry

high elevation

Soil Erosion Control after Wildfire

Deneke, Fred

07 1900

6 pp.

soil erosion

soil

wildfire

fire

forest

trees

Recovering from Wildfire: A Guide for Arizona's Forest Owners

Deneke, Fred

08 1900

8 pp.

wildfire

fire

forest

trees

firewise

forest owners

FIREWISE Plant Materials for 3,000 ft. and Higher Elevations

DeGomez, Tom, Schalau, Jeff, Jones, Chris, Campbell, Steve

12 1900

Revised; Originally Published: 2002 / 5 pp.

fire

wildfire

firewise

forestry

high elevation

Soil Erosion Control after Wildfire

DeGomez, Tom

12 1900

Revised; Originally Published: 2002 / 6 pp.

soil erosion

soil

wildfire

fire

forest

trees

Recovering from Wildfire: A Guide for Arizona's Forest Owners

DeGomez, Tom

12 1900

Revised; Originally Published: 2002 / 8 pp.

wildfire

fire

forest

trees

firewise

forest owners