Global warming

Courtesy : www.livescience.com/

Global warming is the rise in average temperatures across the globe, which has been ongoing at least since record keeping began in 1880. 

Here are the bare numbers, according to the National Oceanic and Atmospheric Administration (NOAA)(opens in new tab): Between 1880 and 1980, the global annual temperature increased at a rate of 0.13 degrees Fahrenheit (0.07 degrees Celsius) per decade, on average. Since 1981, the rate of increase has sped up, to 0.32 F (0.18 C) per decade. This has led to an overall 3.6 F (2 C) increase in global average temperature today compared with the preindustrial era. So far, 2016 is the hottest year on record, but that record has been close to falling several times already. The years 2019 and 2020 both came within fractions of degrees of knocking 2016 off its perch. In 2020, the average global temperature over land and ocean was 1.76 F (0.98 C) warmer than the 20th-century average of 57.0 F (13.9 C). 

Modern global warming is caused by humans. The burning of fossil fuels has released greenhouse gases into the atmosphere, which trap warmth from the sun and drive up surface and air temperatures. Global warming is a synonym for climate change, though “climate change” has become the preferred term among scientists

WHAT CAUSES GLOBAL WARMING?

The main driver of today’s warming is the combustion of fossil fuels. These hydrocarbons heat up the planet via the greenhouse effect, which is caused by the interaction between Earth’s atmosphere and incoming radiation from the sun. 

“The basic physics of the greenhouse effect were figured out more than a hundred years ago by a smart guy using only pencil and paper,” Josef Werne, a professor of geology and environmental science at the University of Pittsburgh, told Live Science.

That “smart guy” was Svante Arrhenius, a Swedish scientist and eventual recipient of a Nobel Prize in chemistry. Simply put, solar radiation hits Earth’s surface and then bounces back toward the atmosphere as heat. Gases in the atmosphere trap this heat, preventing it from escaping into the void of space (good news for life on the planet). In a paper presented in 1895, Arrhenius figured out that greenhouse gases such as carbon dioxide could trap heat close to the Earth‘s surface, and that small changes in the amount of those gases could make a big difference in how much heat is trapped.

HOW GREENHOUSE GASES CAUSE GLOBAL WARMING

Since the beginning of the Industrial Revolution, humans have been rapidly changing the balance of gases in the atmosphere. Burning fossil fuels like coal and oil releases water vapor, carbon dioxide (CO2), methane (CH4), ozone and nitrous oxide (N2O), which are considered the primary greenhouse gases. Carbon dioxide is the most common greenhouse gas. Between about 800,000 years ago and the beginning of the Industrial Revolution, CO2’s presence in the atmosphere amounted to about 280 parts per million (ppm, meaning there were about 280 molecules of CO2 in the air per every million air molecules). As of 2020 (the last year when full data are available), the average CO2 in the atmosphere was 412.5 ppm, according to the National Centers for Environmental Information(opens in new tab)

That may not sound like much, but according to the Scripps Institution of Oceanography, levels of CO2 haven’t been that high since the Pliocene epoch, from about 5.3 million to 2.6 million years ago. At that time, the Arctic was ice-free for at least part of the year and significantly warmer than it is today, according to 2013 research published in the journal Science(opens in new tab)

How Greenhouse Gases Warm the Planet

Greenhouse gases like carbon dioxide absorb radiation and release it back toward Earth, causing our planet to warm up over time.

In 2016, CO2 accounted for 81.6% of all U.S. greenhouse gas emissions, according to an analysis from the Environmental Protection Agency(opens in new tab) (EPA).

“We know through high-accuracy instrumental measurements that there is an unprecedented increase in CO2 in the atmosphere. We know that CO2 absorbs infrared radiation [heat] and the global mean temperature is increasing,” Keith Peterman, a professor of chemistry at York College of Pennsylvania, and his research partner, Gregory Foy, an associate professor of chemistry at York College of Pennsylvania, told Live Science in a joint email message.

CO2 makes its way into the atmosphere through a variety of routes. Burning fossil fuels releases CO2 and is, by far, the biggest U.S. contribution to emissions that warm the globe. According to the 2018 EPA report, U.S. fossil fuel combustion, including electricity generation, released just over 5.8 billion tons (5.3 billion metric tons) of CO2 into the atmosphere in 2016. Other processes — such as non-energy use of fuels, iron and steel production, cement production and waste incineration — boost the total annual CO2 release in the U.S. to 7 billion tons (6.5 billion metric tons).

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Deforestation is also a large contributor to excess CO2 in the atmosphere. In fact, deforestation is the second largest anthropogenic (human-made) source of carbon dioxide, according to the Food and Agriculture Organization of the United Nations(opens in new tab). After trees die, they release the carbon they have stored during photosynthesis. The transformation of forest land into ranching, residential or agricultural land also means fewer trees to take up carbon from the atmosphere. According to the UN’s 2020 Global Forest Resources Assessment(opens in new tab), about 1,040 acres (420 hectares) of forest have been lost to deforestation since 1990, but the good news is that since 2015, the rate of forest loss has slowed.

Globally, methane is the second most common greenhouse gas, but it is the most efficient at trapping heat. The EPA reports that methane is 25 times more efficient at trapping heat than carbon dioxide. In 2016, the gas accounted for about 10% of all U.S. greenhouse gas emissions, according to the EPA. 

Methane can come from many natural sources, but humans cause a large portion of methane emissions through mining, the use of natural gas, the mass raising of livestock and the use of landfills. Cattle constitute the largest single source of methane in the U.S., according to the EPA, with the animals producing nearly 26% of total methane emissions. 

WHAT ARE THE EFFECTS OF GLOBAL WARMING?

Global warming doesn’t just mean warming, which is why “climate change” has become the favored term among researchers and policymakers. While the globe is becoming hotter on average, this temperature increase can have paradoxical effects, such as more frequent and severe snowstorms. Climate change can and will affect the globe in several big ways: by melting ice, by drying out already-arid areas, by causing weather extremes and by disrupting the delicate balance of the oceans.

Melting ice

Perhaps the most visible effect of global warming so far is the melting of glaciers and sea ice. The ice sheets have been retreating since the end of the last ice age, about 11,700 years ago, but the last century’s warming has hastened their demise. A 2016 study found that there is a 99% chance that global warming has caused the recent retreat of glaciers; in fact, the research showed, these rivers of ice retreated 10 to 15 times the distance they would have if the climate had stayed stable. Glacier National Park in Montana had 150 glaciers in the late 1800s. As of 2015, when the last full survey was taken(opens in new tab), there were 26.. The loss of glaciers can cause the loss of human life, when icy dams holding back glacier lakes destabilize and burst or when avalanches caused by unstable ice bury villages.

At the North Pole, warming is proceeding twice as quickly as it is at middle latitudes, and the sea ice is showing the strain. Fall and winter ice in the Arctic hit record lows in both 2015 and 2016, meaning the ice expanse did not cover as much of the open sea as previously observed. In 2020, summer sea ice hit the second-lowest extent ever recorded, according to the National Snow and Ice Data Center(opens in new tab) (NSIDC). According to NASA, the 13 smallest values for maximum winter extent of sea ice in the Arctic were all measured in the last 13 years. The ice also forms later in the season and melts more readily in spring. According to the NSIDC(opens in new tab), January sea ice extent has declined 3.15% per decade over the past 40 years. Some scientists think the Arctic Ocean will see ice-free summers within 20 or 30 years.

Three Trillion Tons of Ice Have Vanished From Antarctica

Between 1992 and 2017, Antarctica lost a staggering amount of ice — more than three trillion tons, researchers found.

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In the Antarctic, the effects of global warming have been more variable.. The Western Antarctic Peninsula is warming faster than anywhere else besides some parts of the Arctic, according to the Antarctic and Southern Ocean Coalition(opens in new tab). The peninsula is where the Larsen C ice shelf just broke in July 2017, spawning an iceberg the size of Delaware. Now, scientists say that a quarter of West Antarctica’s ice is in danger of collapse and the enormous Thwaites and Pine Island glaciers are flowing five times faster than they did in 1992. The Thwaites glacier is especially vulnerable because 2021 research suggests it sits over a region where Earth’s crust is relatively thin and geothermal heat can weaken the ice from below.

East Antarctica has long been more resilient to the effects of global warming. But recent data suggests that even this last cold bastion of the southern continent may be feeling the effects of rising temperatures. According to Yale’s Environment360(opens in new tab), glaciers in East Antarctica are starting to move faster. That means more land-based ice headed toward the ocean — a major driver of sea level rise. 

Heating up

Global warming will change things between the poles, too. Many already-dry areas are expected to get even drier as the world warms. The southwest and central plains of the United States, for example, are expected to experience decades-long “megadroughts” harsher than anything else in human memory.

“The future of drought in western North America is likely to be worse than anybody has experienced in the history of the United States,” Benjamin Cook, a climate scientist at NASA’s Goddard Institute for Space Studies in New York City who published research in 2015 projecting these droughts, told Live Science. “These are droughts that are so far beyond our contemporary experience that they are almost impossible to even think about.”

The study predicted an 85% chance of droughts lasting at least 35 years in the region by 2100. The main driver, the researchers found, is the increasing evaporation of water from hotter and hotter soil. Much of the precipitation that does fall in these arid regions will be lost.

Meanwhile, 2014 research found that many areas will likely see less rainfall as the climate warms. Subtropical regions, including the Mediterranean, the Amazon, Central America and Indonesia, will likely be hardest hit, that study found, while South Africa, Mexico, western Australia and California will also dry out.

Droughts, in turn, can set the stage for devastating wildfires. Many factors go into how many acres are burned each year and how much damage fires do, but according to National Interagency Fire Center data(opens in new tab), there has been a steady increase in the extent of wildfires since the 1980s. The top 10 years of acreage burned have all occurred since 2005.

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