The Vicious Climate-Wildfire Cycle
By Carly Phillips
With little fanfare and scant news coverage, fire season 2019 has arrived. Firefighters are already containing blazes in several states, including Colorado, Florida and Oklahoma, and seasonal outlooks suggest that significant wildfires are likely in parts of Alaska, Hawaii and the West Coast.
While forest management and human development have increased wildfire incidence and risk, climate change has exacerbated the trend of large fires and contributed to the lengthening of the fire season, in some cases making wildfires a year-round phenomenon. In the Western U.S., climate change is a major driver behind the near doubling in burned area that we've experienced over the past 35 years, and has contributed to an increase in the frequency and severity of fires, while lengthening the fire season in some regions.
Fires also simultaneously aggravate the impact of climate change by releasing huge quantities of carbon dioxide and other global warming gases into our atmosphere.
As the first act of this new fire season begins to unfold, we have a renewed opportunity and obligation to address the connections between wildfires, climate change and human activity, and take steps to interrupt this vicious cycle.
Climate Change Worsens Fires
Climate change is priming ecosystems in the Western U.S., Southeastern U.S. and Alaska to burn, while climate disasters like drought, rising temperatures and hurricanes compound wildfire risk and spread.
Drought and Rising Temperatures Change How Water Enters and Leaves Ecosystems
Drought is a natural occurrence. However, now we have a greater risk of hotter droughts. Rising temperatures dry out soils and trees. While drought means that less water is entering the ecosystem, rising temperatures mean that water is leaving more quickly. As temperatures rise, plants lose more water per unit of carbon dioxide, exacerbating the already dry and dangerous conditions produced by drought.
With less water coming into the ecosystem, plants become water stressed, which can kill huge numbers of plants if drought conditions persist. In extreme cases, drought itself can kill trees. Plants lose water when they perform photosynthesis, the process where plants use sunlight and carbon dioxide to make food, because they open their pores (aka stomata) to take in carbon dioxide, and water evaporates out in the process.
(This is such a big deal for plants that some have evolved special processes so they can avoid this water loss. In the desert, many plants only do gas exchange at night, when temperatures are lower and water-loss risk is the lowest.) #CAMLife #DinnerPartyFactoid
So in periods of extreme water stress like drought, they close those same pores to conserve what water they have. However, since plants aren't able to photosynthesize with their stomata closed, they then use up their carbon reserves and literally starve, known as carbon starvation.
Hydraulic failure is another way drought can lead to plant death: where air bubbles in the xylem (water transporting plant tissue) block water transport and the plant dies. When droughts are longer and more severe, the risk of hydraulic failure increases.
Alternatively, trees can also die from complications associated with drought, like an insect infestation that a healthy tree could usually defend against. Climate change has magnified the negative impacts of insects, as in the case of California's bark beetle. Cold temperatures have historically regulated the populations of these insects, but as climate change continues to shrink the temperature range that any one given ecosystem experiences, these cold temperatures just aren't happening anymore. These insects also grow and reproduce more quickly in warmer temperatures, which may further enhance their spread. While these outbreaks and subsequent tree deaths are changing the overall composition and structure of the ecosystem, they also can lead to a build-up of dry forest kindling. As a result, we can expect that forests in the West, Southeast and Alaska will continue to be full of dried out, ready-to-burn material.
Hurricanes Can Increase Fuel Loads in Landfall Areas
When hurricanes make landfall, violent winds can bring down huge amounts of timber. While landfalling hurricanes are rare, these natural disasters bring down huge amounts of timber that can easily become create fuel for wildfires. In 1989, Hurricane Hugo damaged approximately 4.39 million acres of forested land in South Carolina alone and generated widespread concerns about increased fire risk from larger fuel loads and higher wind speeds. In the past month, we've seen a similar phenomenon play out in Florida, where downed trees from Hurricane Michael aggravated a small debris fire and inhibited firefighters as they worked to access and contain the blaze. The risk this year, however, is not isolated to Florida, and threatens large portions of the southeastern U.S.
Fires Worsen Climate Change
On the flip side, the burning of trees, dead biomass and soil sends huge pulses of carbon to the atmosphere. Carbon enters an ecosystem when plants take carbon dioxide out of the atmosphere and incorporate it into their tissues. Over time, that carbon becomes integrated into soil, the largest land carbon pool, via plant roots and as dead plants decompose. These processes take time and the buildup of carbon stores is gradual. However, when fire roars through, all that carbon literally goes up in smoke.
In carbon-rich areas like boreal forests, arctic tundra and peatlands, the impact of fire on climate change is further amplified. The carbon in these ecosystems accounts for about 50 percent of global soil organic carbon or twice what is currently in the atmosphere as CO2. These ecosystems have built up carbon in their soil over MILLENNIA and a single fire can devastate these stocks.
In addition, fires release particulate black carbon that can magnify the effects of climate change in two ways. When suspended in the atmosphere, the particles trap heat, magnifying the warming of Earth's surface. Once these same particles disperse and settle on ice or snowy surfaces, they can decrease the reflectivity and melt ice in areas like Greenland, further warming the world.
We Worsen Both
Due to our prolonged and ever-growing addiction to fossil fuels, we're exacerbating climate change which feeds back to catastrophic wildfires. Our continued spewing of global warming gases to the atmosphere has caused many of the climatic complications discussed above. As a result, we're continuing to worsen a problem that we ourselves created.
Beyond fossil fuels, humans have aggravated wildfires by suppressing most fires, moving into wild areas, and simply igniting the fires ourselves. Total suppression has been the primary strategy of the U.S. federal government on nearly all conterminous U.S. land for decades, despite indigenous knowledge and practices that preceded this policy. Unlike homes, restaurants and businesses, our national forests have evolved with fire, requiring it for seed germination, competition reduction and general ecosystem maintenance. The absence of fire means that material (branches, logs and understory shrubs) that would normally burn off in regularly returning fires, has accumulated in these forests over time, creating fuel-rich conditions that drive these devastating wildfires. This suppression has also increased forest density creating greater competition for resources (especially in drought) and allowing fires to spread more easily through the forest.
Interrupting the Cycle
This vicious feedback loop where warming begets fire begets warming begets fire will continue without targeted, science-based intervention.
To interrupt the climate side of this cycle, we NEED to reduce our overall global warming emissions. This is achievable through a number of channels, including reducing our dependence on fossil fuels and moving to cleaner energy sources. We can also remove carbon from the atmosphere and protect the large stores of carbon that already exist. Regardless of the mechanism, addressing our current wildfire predicament and guarding against future disasters requires that we also address climate change and global warming emissions.
To interrupt the cycle from the fire side, we need to codify information from fire science into proactive fire management policy. Research demonstrates that prescribed burns, reduction of fuel loads, reestablishing historic fire return intervals (the frequency with which an ecosystem experiences a fire event), reducing expansion into the wildland urban interface and strategic preventative planning at the can all decrease the prevalence and intensity of the mega fires we've seen in recent years. On a more local and regional scale, fuel treatments and prescribed burns can be an effective strategy to reduce wildfire risk.
While science has revealed how we can work to resolve our current predicament, we are slow to follow through. Democrats, Republicans and bipartisan coalitions in the Senate have drafted legislation to address our nation's wildfire problem in the past 3 years, but none of these bills made it into law. In March 2018, we made progress with a budget that included a major restructuring of funds for fire fighting efforts, including a disaster fund for wildfires. However, President Trump's most recent budget proposal slashes funds for forestry in both the USDA and DOI, suggesting the progress made in 2018 may not be sustained.
Prescribed fires, where managers intentionally set and monitor fires towards ecological ends, are already used as a tool across the country to reduce fuel loads and mimic natural fire return intervals. The risks of this strategy, such as fire escape and increases in air pollution, often discourages decision makers from using this management option. While nearly 99 percent of prescribed fires are successful, those that escape are often the ones we hear about, like the Cerro Grande fire in 2000. As an alternative, manual removal of fuels (mechanical thinning) can reduce burn intensity and speed of fire spread while maintaining the ecological integrity of the ecosystem. In situations where prescribed fire is untenable, like following Hurricane Hugo, alternative strategies like fuel breaks and strategic build-up of suppression capacity can more effectively reduce risks of catastrophic wildfires.
Despite the bleakness of our current situation and the dangers that wildfires pose, we have the knowledge and skills to break this vicious cycle. 2019 seems as good a time as any to start.
Carly Phillips is the Kendall Fellow for Protecting Carbon in Alaska's Boreal Forests with the Climate & Energy program at the Union of Concerned Scientists.
EcoWatch Daily Newsletter
The U.S. reported more than 55,000 new coronavirus cases on Thursday, in a sign that the outbreak is not letting up as the Fourth of July weekend kicks off.
- The U.S. Isn't in a Second Wave of Coronavirus – The First Wave ... ›
- Navajo Nation Has Highest Covid-19 Infection Rate in the U.S. ... ›
- U.S. Coronavirus Cases Top 2 Million as All 50 States Start ... ›
By Jason Bruck
Human actions have taken a steep toll on whales and dolphins. Some studies estimate that small whale abundance, which includes dolphins, has fallen 87% since 1980 and thousands of whales die from rope entanglement annually. But humans also cause less obvious harm. Researchers have found changes in the stress levels, reproductive health and respiratory health of these animals, but this valuable data is extremely hard to collect.
Researchers work with trained dolphins to learn more about their sensory abilities, seen here testing a dolphin's hearing. Jason Bruck / CC BY-ND
A Lot to Learn From Hormones<p>When sampling the blow, we are looking for hormones in mucus as these can be used to gauge psychological and physiological health. We are specifically interested in <a href="https://dx.doi.org/10.1371%2Fjournal.pone.0114062" target="_blank">hormones like cortisol</a> and <a href="https://doi.org/10.1016/j.ygcen.2018.04.003" target="_blank">progesterone</a>, which indicate stress levels and reproductive ability respectively, but can also help determine overall health.</p><p>Additionally, blow samples can detect <a href="https://dx.doi.org/10.1128%2FmSystems.00119-17" target="_blank">respiratory pathogens</a> in the lungs or nasal passages - blowholes evolved from noses after all.</p><p>This health analysis is especially important in areas with oil spills as the chemicals can cause hormonal problems that harm <a href="https://www.carmmha.org/investigating-how-oil-spills-affect-dolphins-and-whales/" target="_blank">development, metabolism and reproduction</a> in dolphins.</p><p>Hormone samples can provide scientists with valuable data, but collecting them from intelligent and unpredictable animals is challenging.</p>
Cetacean Collaborators<p>To build a drone that can stealthily collect spray from moving dolphins, we needed more data on their eyesight and hearing, and this is data that couldn't be collected in the wild nor simulated in a lab.</p><p>We worked with dolphins at facilities like Dolphin Quest in Bermuda, which provides guests opportunities to learn about dolphins while allowing <a href="https://dolphinquest.com/about-us/our-story/" target="_blank">scientists access to animals for noninvasive research</a>. Here the dolphins can swim away if they choose not to work with us, so we had to design the study like a game; the way a kindergarten teacher entertains a class. If the dolphins aren't interested, we don't get to do the science.</p><p>Over the course of hundreds of sessions, we sought to answer two questions: What can dolphins hear and what can they see around their heads?</p><p>To test dolphin hearing, we set up microphones and cameras to record dolphin behavior as we played drone noise in the air. We analyzed the responses to each noise – such as how many dolphins looked at the speaker – and used these as a proxy for their ability to hear the sounds.</p>
<span style="display:block;position:relative;padding-top:56.25%;" class="rm-shortcode" data-rm-shortcode-id="5f31daf07a652b8d64a093b993ee4e96"><iframe lazy-loadable="true" src="https://www.youtube.com/embed/UjmQeH3vXHI?rel=0" width="100%" height="auto" frameborder="0" scrolling="no" style="position:absolute;top:0;left:0;width:100%;height:100%;"></iframe></span>
Robodolphin doesn't look like a real dolphin, but it doesn't need to in order to train our drone pilots. C.J. Barton / Oklahoma State University / CC BY-ND<p>To build robodolphin, we worked with dolphins trained to "chuff" or sneeze on command to measure spray characteristics. We used high-speed photography to see the dolphins' breath as it moved through the air. Then we conducted high resolution CT scans of a dolphin head and 3D-printed a replica of a nasal passage.</p><p>Now, we have a complete robodolphin and are tweaking its sprays to be nearly identical to the real thing. This will allow us to determine how close we need to get to collect the samples, and therefore, how quiet our drone needs to be.</p>
The replica dolphin blowhole was designed from a scan of a real blowhole passage, and the spray it produces closely matches the real thing. Alvin Ngo, Mitch Ford and CJ Barton / Oklahoma State University / CC BY-ND
A Bit of Practice, Then Into the Wild<p>In the next few months, we will test flights over robodolphin with existing drones to determine the timing and strategy for collection. From there, we will fabricate a low-noise drone that can fly fast enough and with sufficient maneuverability to capture samples from wild dolphins. Like a video game, we will use the visual field data to develop approach trajectories to stay in the visual blindspots.</p><p>We plan to test our drones on a truck-mounted robodolphin moving down a runway, then using a boat to simulate realistic conditions. The next steps will involve ocean testing with dolphins trained for open ocean swimming. These tests will determine if our devices can catch and hold the hormones as the drone flies back to a researcher's boat.</p><p>Finally, we will deploy the system to collect data on wild dolphins. Our first goal is to test resident dolphins – animals that live on the coasts and deal directly with boat and oil industry noise – which will allow us to learn more about stress resulting from human impacts.</p><p>Those samples are a way off, but if all goes well we will have a specially built drone capable of flying long distances and capturing samples undetected in a few years. The samples collected will allow researchers to do better science with impact on the animals they study.</p>
- Drone Footage Captures Rare Finless Porpoises in Hong Kong ... ›
- Brazil's Amazon River Dolphin Faces Extinction After Fishing ... ›
- 10 Surprising Dolphin 'Superpowers' - EcoWatch ›
Sunscreen pollution is accelerating the demise of coral reefs globally by causing permanent DNA damage to coral. gonzalo martinez / iStock / Getty Images Plus
On July 29, Florida Governor Ron DeSantis signed into law a controversial bill prohibiting local governments from banning certain types of sunscreens.
- Your Guide to Reef Friendly Sunscreens - EcoWatch ›
- Hundreds of Sunscreens Don't Work or Have Unsafe Ingredients ... ›
- FDA Study: Sunscreen Chemicals Seep Into the Bloodstream ... ›
By Kelli McGrane
Oat milk is popping up at coffee shops and grocery stores alike, quickly becoming one of the trendiest plant-based milks.
- Is Oat Milk Gluten-Free? - EcoWatch ›
- What Nutritionists Think About Starbucks' Three New Plant-Based ... ›
- 6 Alternatives to Milk: Which Is the Healthiest? - EcoWatch ›
"Emissions from pyrotechnic displays are composed of numerous organic compounds as well as metals," a new study reports. Nodar Chernishev / EyeEm / Getty Images
Fireworks have taken a lot of heat recently. In South Dakota, fire experts have said President Trump's plan to hold a fireworks show is dangerous and public health experts have criticized the lack of plans to enforce mask wearing or social distancing. Now, a new study shows that shooting off fireworks at home may expose you and your family to dangerous levels of lead, copper and other toxins.
- No Social Distancing or Mask Requirement at Trump's Mt ... ›
- Trump's Fireworks Show at Mt. Rushmore Is a Dangerous Idea, Fire ... ›
By Ashutosh Pandey
Billions worth of valuable metals such as gold, silver and copper were dumped or burned last year as electronic waste produced globally jumped to a record 53.6 million tons (Mt), or 7.3 kilogram per person, a UN report showed on Thursday.
Environmental and Health Hazard<p>Experts say e-waste, which is now the world's fastest-growing domestic waste stream, poses serious environmental and health risks.</p><p>Simply throwing away electronic items without ensuring they get properly recycled leads to the loss of key materials such as iron, copper and gold, which can otherwise be recovered and used as primary raw materials to make new equipment, thereby reducing greenhouse gas emissions from extraction and refinement of raw materials.</p><p>Refrigerants found in electronic equipment such as fridge and air conditioners also contribute to global warming. A total of 98 Mt of CO2-equivalents, or about 0.3% of global energy-related emissions, were released into the atmosphere in 2019 from discarded refrigerators and ACs that were not recycled properly, the report said.</p><p>E-waste contains several toxic additives or hazardous substances, such as mercury and brominated flame retardants (BFR), and simply burning it or throwing it away could lead to serious health issues. Several studies have linked unregulated recycling of e-waste to adverse birth outcomes like stillbirth and premature birth, damages to the human brain or nervous system and in some cases hearing loss and heart troubles.</p><p>"Informal and improper e-waste recycling is a major emerging hazard silently affecting our health and that of future generations. One in four children are dying from avoidable environmental exposures," said Maria Neira, director of the Environment, Climate Change and Health Department at the World Health Organization. "One in four children could be saved, if we take action to protect their health and ensure a safe environment."</p>
Europe Leads the Way<p>While most of the e-waste was generated in Asia (24.9 Mt) in 2019, Europe led the charts on a per person basis with 16.2 kg per capita, the report said.</p><p>But the continent also recorded the <a href="https://www.dw.com/en/the-eu-declares-war-on-e-waste/a-51108790" target="_blank">highest documented formal e-waste collection and recycling</a> rate at 42.5%, still below its target of 65%. Europe was well ahead of the others on this front. Asia ranked second with 11.7%.</p><p>The authors said while more that 70% of the world's population was covered by some form of e-waste policy or laws, not much was being done toward implementation and enforcement of the regulations to encourage the take-up of a collection and recycling infrastructure due to lack of investment and political motivation.</p><p>"You have to think about new economic systems," said Kühr.</p><p>One approach could be that consumers no longer buy the products, but only the service they offer. The device would remain the property of the maker, who would then have an interest in offering his customers the best service and the necessary equipment. The maker would also be interested in designing his products in such a way that they are easier to repair and easier to recycle, Kühr said.</p>
- Dangerous Chemicals From E-Waste Found in Black Plastics From ... ›
- Electronic Waste Study Finds $65 Billion in Raw Materials ... ›
- Electronic Waste: New EU Rules Target Throwaway Culture ... ›
- COVID-19 Masks Are Polluting Beaches and Oceans - EcoWatch ›
- Plastic Packaging Use Increases During the Coronavirus - EcoWatch ›
- Coronavirus Worsens Thailand's Plastic Waste Crisis - EcoWatch ›
- Coronavirus Plastic Waste Polluting the Environment - EcoWatch ›