Sunday 27 July 2014

Canada’s Northwest Territories Are On Fire

Global Fire Maps

Period: 2014/191 - 2014/200 (07/10/2014 - 07/19/2014)




Each of these fire maps accumulates the locations of the fires detected by MODIS on board the Terra and Aqua satellites over a 10-day period. Each colored dot indicates a location where MODIS detected at least one fire during the compositing period. Color ranges from red where the fire count is low to yellow where number of fires is large. The compositing periods are referenced by their start and end dates (julian day). The duration of each compositing period was set to 10 days. Compositing periods are reset every year to make year-to-year comparisons straightforward. The first compositing period of each year starts on January 1. The last compositing period of each year includes a few days from the next year.

The About Rapid Response Imagery page provides more information on usage guidelines, product quality, and algorithms for the fire location data.



Fire location data:

MODIS fire location data are distributed in a variety of forms (e.g. interactive web mapper, GIS, Google Earth, text files) through the Fire Information for Resource Management System (FIRMS) at the University of Maryland. The official monthly MODIS active fire location text files are distributed from the University of Maryland via the FTP server fuoco.geog.umd.edu (login name is fire and password is burnt) in the directory modis/C5/mcd14ml. These data lag a few months behind the LANCE fire locations available from FIRMS. The fire detection code is identical to that used to process the official science quality data. However, there will be slight differences in the locations of the fires detected due to the geolocation differences caused by using predicted ephemeris.


Credits:
Fire maps created by Jacques Descloitres. Fire detection algorithm developed by Louis Giglio. Blue Marble background image created by Reto Stokli.

References:

Giglio, L., J. Descloitres, C. O. Justice, and Y. J. Kaufman. 2003. An enhanced contextual fire detection algorithm for MODISRemote Sensing of Environment, 87:273-282

Davies, D., Kumar, S., and Descloitres, J. (2004). Global fire monitoring using MODIS near-real-time satellite data. GIM International, 18(4):41-43




Canada’s Northwest Territories Are On Fire, and Everyone Should Care



Adventure Journal,
27 July, 2014



For the past few weeks, dry and warm weather have fueled large forest fires across Canada’s remote Northwest Territories. The extent of those fires is well above average for the year to-date, and is in line with climate trends of more fires burning in the northern reaches of the globe.


Of the 243 wildfires in the Northwest Territories to-date this year, 202 of them are currently burning. That includes the Birch Creek Fire complex, which stretches over 250,000 acres.
The amount of acres burned in the Northwest Territories is six times greater than the 25-year average to-date according to data from the Canadian Interagency Forest Fire Center.
Boreal forests like those in the Northwest Territories are burning at rates “unprecedented” in the past 10,000 years according to the authors of a study put out last year. The northern reaches of the globe are warming at twice the rate as areas closer to the equator, and those hotter conditions are contributing to more widespread burns.
The combined boreal forests of Canada, Europe, Russia and Alaska, account for 30 percent of the world’s carbon stored in land, carbon that’s taken up to centuries to store. Forest fires like those currently raging in the Northwest Territories, as well as ones in 2012 and 2013 in Russia, can release that stored carbon into the atmosphere and contribute to global warming. 
Warmer temperatures can in turn create a feedback loop, priming forests for wildfires that release more carbon into the atmosphere and cause more warming. 
The Intergovernmental Panel on Climate Change’s landmark climate report released earlier this year indicates that for every 1.8°F rise in temperatures, wildfire activity is expected to double.
adventure journal nwt fire 02
In addition, soot from forest fires can also darken ice in the Arctic and melt it faster. The 2012 fires in Siberia released so much soot that they helped create a shocking melt of Greenland’s ice sheet. Over the course of a few weeks in July that year, 95 percent of the surface melted. That could become a yearly occurrence by 2100 if temperatures continue to rise along with wildfire activity.
Forest in other parts of the globe are also feeling the effects of climate change. In the western U.S., wildfire season has lengthened by 75 days compared to 40 years ago. Additionally, rising temperatures and shrinking snowpack have helped drive an increase in the number of large forest fires. In Australia, fire danger is also increasing, if not the total number of fires, due to a similar trend of hotter, dryer weather.
Perhaps not surprisingly then, the current Northwest Territories fires have been fueled by hot and dry weather. Yellowknife’s June high temperatures were 3.8°F above normal highs while rainfall was only 15 percent of normal. Through July 15, high temperatures have been running 4°F above July averages and the city has only seen 2 percent of its normal rainfall for the month. While these conditions can’t be tied specifically to climate change, they’re in line with those trends.
The fires have shut down parts of territory’s Highway 3, a main thoroughfare, and inundated Yellowknife with a thick haze of smoke and ash. The city’s 19,000 residents are also under a health warning. At points last week, the smoke plume was whisked south across the provinces of Alberta and Saskatchewan and even reaching the Dakotas, 2,000 miles away.



See also Song of Flood and Fire Refrain: Epic Canadian Floods Wreck 5.5 Million Acres of Cropland



No comments:

Post a Comment

Note: only a member of this blog may post a comment.