421-8 Short Term Soil Respiration Response to Fire in a Semi-Arid Ecosystem.

Poster Number 1008

See more from this Division: SSSA Division: Pedology
See more from this Session: Fire Effects on the Soil System: II

Wednesday, November 18, 2015
Minneapolis Convention Center, Exhibit Hall BC

Alexandra G Rozin, Geological Sciences, Idaho State University, Pocatello, ID, Katheen A Lohse, Biological Sciences, Idaho State University, Pocatello, ID and Mark S Seyfried, Northwest Watershed Research Center, USDA-ARS, Boise, ID
Abstract:
In the Intermountain West (USA), fire is an important driver of carbon cycling in the environment. Increasing frequency and severity of fires, either through management actions or wildfires, is expected with changing climates in the Western United States. When burning is used as a management tool, it may be beneficial and control the growth of nuisance vegetation, promote the regeneration of grasses and forage species, and reduce hazardous fuel loads to minimize the risk of future wildfires. However, high intensity wildfires often have a negative effect, resulting in a loss of carbon storage and a shift of vegetation communities. This delays recovery of the ecosystem for years or decades and alters the historic fire regime.

A 2000 acre prescribed burn in the Reynolds Creek Critical Zone Observatory provided the opportunity to quantify pre and post-burn soil carbon stores and soil carbon losses by heterotrophic respiration. Pre and post-burn soil samples were collected for physical and biogeochemical characterization to quantify substrate availability and possible limitations for heterotrophic respiration. CO2 fluxes were continuously monitored in situ before and immediately after the fire to understand the short-term response of soil respiration to varying burn severities.

See more from this Division: SSSA Division: Pedology
See more from this Session: Fire Effects on the Soil System: II