From an article by Van R. Kane, et al in EOS.
Despite their destructive power, fires are natural phenomena in many forests, where they are essential to the biomes’ long-term health. Decades of field-based studies have built the field of fire ecology and have informed nuanced views of fire as both a threat and a restorative process. However, the expense of such fieldwork has meant that relatively small portions of forests—and their relation to fire—have been studied in detail. Even extensive field studies involving hundreds of forest plots may cumulatively measure conditions over only dozens to hundreds of hectares, yet because of the limited data available, these samples are taken to represent highly varied conditions over millions of hectares.
Today, with help from remote sensing technologies, fire ecologists are more often examining continuous forest landscapes to understand their conditions before and after fires. In particular, they are using high-resolution laser imaging measurements gathered by lidar instruments aboard planes to map conditions from the treetops to the ground. Lidar allows us, for the first time, to quantify forest structure directly—that is, to determine tree heights, canopy densities, and the distribution of branches and leaves throughout the canopy—a feat previously possible only by painstaking field measurements. Lidar-based studies are beginning to enrich our understanding of wildfires historically, and they are providing forest managers with new tools to use in planning forest restorations and thus to improve forests’ resilience to future fires.
For the complete article on wildfire resilience CLICK HERE.
