Is Current Warming Natural?
In Earth’s history before the Industrial Revolution, Earth’s climate changed due to natural causes not related to human activity. Most often, global climate has changed because of variations in sunlight. Tiny wobbles in Earth’s orbit altered when and where sunlight falls on Earth’s surface. Variations in the Sun itself have alternately increased and decreased the amount of solar energy reaching Earth. Volcanic eruptions have generated particles that reflect sunlight, brightening the planet and cooling the climate. Volcanic activity has also, in the deep past, increased greenhouse gases over millions of years, contributing to episodes of global warming.
A biographical sketch of Milutin Milankovitch describes how changes in Earth’s orbit affects its climate.
These natural causes are still in play today, but their
influence is too small or they occur too slowly to explain the rapid
warming seen in recent decades. We know this because
scientists closely monitor the natural and human activities that
influence climate with a fleet of satellites and surface instruments.
Remote meteorological stations (left) and
orbiting satellites (right) help scientists monitor the causes and
effects of global warming. [Images courtesy NOAA Network for the Detection of Atmospheric Composition Change (left) and Environmental Visualization Laboratory (right).]
NASA satellites record a host of vital signs including atmospheric
aerosols (particles from both natural sources and human activities, such
as factories, fires, deserts, and erupting volcanoes), atmospheric
gases (including greenhouse gases), energy radiated from Earth’s surface
and the Sun, ocean surface temperature changes, global sea level, the
extent of ice sheets, glaciers and sea ice, plant growth, rainfall,
cloud structure, and more.
On the ground, many agencies and nations support networks of weather and climate-monitoring stations that maintain temperature, rainfall, and snow depth records, and buoys that measure surface water and deep ocean temperatures. Taken together, these measurements provide an ever-improving record of both natural events and human activity for the past 150 years.
Scientists integrate these measurements into climate models to recreate temperatures recorded over the past 150 years. Climate model simulations that consider only natural solar variability and volcanic aerosols since 1750—omitting observed increases in greenhouse gases—are able to fit the observations of global temperatures only up until about 1950. After that point, the decadal trend in global surface warming cannot be explained without including the contribution of the greenhouse gases added by humans.
Though people have had the largest impact on our climate since 1950, natural changes to Earth’s climate have also occurred in recent times. For example, two major volcanic eruptions, El Chichon in 1982 and Pinatubo in 1991, pumped sulfur dioxide gas high into the atmosphere. The gas was converted into tiny particles that lingered for more than a year, reflecting sunlight and shading Earth’s surface. Temperatures across the globe dipped for two to three years.
On the ground, many agencies and nations support networks of weather and climate-monitoring stations that maintain temperature, rainfall, and snow depth records, and buoys that measure surface water and deep ocean temperatures. Taken together, these measurements provide an ever-improving record of both natural events and human activity for the past 150 years.
Scientists integrate these measurements into climate models to recreate temperatures recorded over the past 150 years. Climate model simulations that consider only natural solar variability and volcanic aerosols since 1750—omitting observed increases in greenhouse gases—are able to fit the observations of global temperatures only up until about 1950. After that point, the decadal trend in global surface warming cannot be explained without including the contribution of the greenhouse gases added by humans.
Though people have had the largest impact on our climate since 1950, natural changes to Earth’s climate have also occurred in recent times. For example, two major volcanic eruptions, El Chichon in 1982 and Pinatubo in 1991, pumped sulfur dioxide gas high into the atmosphere. The gas was converted into tiny particles that lingered for more than a year, reflecting sunlight and shading Earth’s surface. Temperatures across the globe dipped for two to three years.
Although Earth’s temperature fluctuates
naturally, human influence on climate has eclipsed the magnitude of
natural temperature changes over the past 120 years. Natural influences
on temperature—El Niño, solar variability, and volcanic aerosols—have
varied approximately plus and minus 0.2° C (0.4° F), (averaging to about
zero), while human influences have contributed roughly 0.8° C (1° F) of
warming since 1889. (Graphs adapted from Lean et al., 2008.)
Although volcanoes are active around the world, and continue to
emit carbon dioxide as they did in the past, the amount of carbon
dioxide they release is extremely small compared to human emissions. On
average, volcanoes emit between 130 and 230 million tonnes of carbon
dioxide per year. By burning fossil fuels, people release in excess of
100 times more, about 26 billion tonnes of carbon dioxide, into the
atmosphere every year (as of 2005). As a result, human activity
overshadows any contribution volcanoes may have made to recent global
warming.
Changes in the brightness of the Sun can influence the climate from decade to decade, but an increase in solar output falls short as an explanation for recent warming. NASA satellites have been measuring the Sun’s output since 1978. The total energy the Sun radiates varies over an 11-year cycle. During solar maxima, solar energy is approximately 0.1 percent higher on average than it is during solar minima.
Changes in the brightness of the Sun can influence the climate from decade to decade, but an increase in solar output falls short as an explanation for recent warming. NASA satellites have been measuring the Sun’s output since 1978. The total energy the Sun radiates varies over an 11-year cycle. During solar maxima, solar energy is approximately 0.1 percent higher on average than it is during solar minima.
The transparent halo known as the solar corona changes between solar maximum (left) and solar minimum (right). (NASA Extreme Ultraviolet Telescope images from the SOHO Data Archive.)
Each cycle exhibits subtle differences in intensity and duration.
As of early 2010, the solar brightness since 2005 has been slightly
lower, not higher, than it was during the previous 11-year minimum in
solar activity, which occurred in the late 1990s. This implies that the
Sun’s impact between 2005 and 2010 might have been to slightly decrease
the warming that greenhouse emissions alone would have caused.
Satellite measurements of daily (light line)
and monthly average (dark line) total solar irradiance since 1979 have
not detected a clear long-term trend. (NASA graph by Robert Simmon,
based on data from the ACRIM Science Team.)
Scientists theorize that there may be a multi-decadal trend in
solar output, though if one exists, it has not been observed as yet.
Even if the Sun were getting brighter, however, the pattern of warming
observed on Earth since 1950 does not match the type of warming the Sun
alone would cause. When the Sun’s energy is at its peak (solar maxima),
temperatures in both the lower atmosphere (troposphere) and the
upper atmosphere (stratosphere) become warmer. Instead, observations
show the pattern expected from greenhouse gas effects: Earth’s surface
and troposphere have warmed, but the stratosphere has cooled.
Satellite measurements show warming in the
troposphere (lower atmosphere, green line) but cooling in the
stratosphere (upper atmosphere, red line). This vertical pattern is
consistent with global warming due to increasing greenhouse gases, but
inconsistent with warming from natural causes. (Graph by Robert Simmon,
based on data from Remote Sensing Systems, sponsored by the NOAA Climate and Global Change Program.)
The stratosphere gets warmer during solar maxima because the ozone
layer absorbs ultraviolet light; more ultraviolet light during solar
maxima means warmer temperatures. Ozone depletion explains the biggest
part of the cooling of the stratosphere over recent decades, but it
can’t account for all of it. Increased concentrations of carbon dioxide
in the troposphere and stratosphere together contribute to cooling in
the stratosphere.
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