Guest “I’ve lost track of how many things this guy got wrong” by David Middelton
Humans are causing climate change: It’s just been proven directly for the first time
by: David Yeomans
Posted: Apr 5, 2021 / 04:00 PM CDT / Updated: Apr 6, 2021 / 07:04 AM CDT
AUSTIN (KXAN) — While it’s now common knowledge that man-made greenhouse gas emissions trap more heat at the Earth’s surface and cause global temperatures to rise, it’s never been proven 100% by conclusive, direct, and observational data.
But that’s now changed.
In a first-of-its-kind study, academic researchers along with NASA scientists are quantifying the direct impact that human activity is having on our climate system — and proving human activity is to blame for recent warming trends.
Before the Industrial Revolution, the Earth’s climate was, for a large amount of time, in a relatively stable, harmonious stasis where heat energy coming in to the atmosphere was equivalent to energy going out. Note that the sun brings incoming heat energy, and the Earth itself gives off outgoing energy to maintain balance.
There is a natural greenhouse effect caused by the aerosols and clouds in our atmosphere…
“Before the Industrial Revolution, the Earth’s climate was, for a large amount of time, in a relatively stable, harmonious stasis…”
Horst schist! Ever hear of the Little Ice Age?
Or maybe the 1970’s?
Without the roughly 0.8 °C of warming since 1975, that allegedly can’t be explained by natural factors alone, we’d still be waiting for The Ice Age Cometh!
Even if humans are the primary cause of the warming since 1975, the fracking climate was doing this before we mucked up the “stable, harmonious stasis”!
How about the Pleistocene? Ever hear of that?
“There is a natural greenhouse effect caused by the aerosols and clouds in our atmosphere…”
Water vapor is a “greenhouse gas”… Clouds aren’t water vapor.
Clouds are not water vapor. Water vapor is the gas state of H2O and is invisible.
West Texas A&M University
Aerosols do not cause the “greenhouse effect.”
Aerosols: Tiny Particles, Big Impact
Take a deep breath. Even if the air looks clear, it’s nearly certain that you’ll inhale tens of millions of solid particles and liquid droplets. These ubiquitous specks of matter are known as aerosols, and they can be found in the air over oceans, deserts, mountains, forests, ice, and every ecosystem in between. They drift in Earth’s atmosphere from the stratosphere to the surface and range in size from a few nanometers—less than the width of the smallest viruses—to several several tens of micrometers—about the diameter of human hair. Despite their small size, they have major impacts on our climate and our health.
The bulk of aerosols—about 90 percent by mass—have natural origins. Volcanoes, for example, eject huge columns of ash into the air, as well as sulfur dioxide and other gases, yielding sulfates.
Aerosols and Incoming Sunlight (Direct Effects)
The Sun provides the energy that drives Earth’s climate, but not all of the energy that reaches the top of the atmosphere finds its way to the surface. That’s because aerosols—and clouds seeded by them—reflect about a quarter of the Sun’s energy back to space.
The first-of-its-kind study mentioned aerosols…. Didn’t you read it?
Changes in atmospheric composition, such as increasing greenhouse gases, cause an initial radiative imbalance to the climate system, quantified as the instantaneous radiative forcing. This fundamental metric has not been directly observed globally and previous estimates have come from models. In part, this is because current space‐based instruments cannot distinguish the instantaneous radiative forcing from the climate’s radiative response. We apply radiative kernels to satellite observations to disentangle these components and find all‐sky instantaneous radiative forcing has increased 0.53±0.11 W/m2 from 2003 through 2018, accounting for positive trends in the total planetary radiative imbalance. This increase has been due to a combination of rising concentrations of well‐mixed greenhouse gases and recent reductions in aerosol emissions. These results highlight distinct fingerprints of anthropogenic activity in Earth’s changing energy budget, which we find observations can detect within 4 years.
Kramer et al., 2021
Willis discussed the paper in this WUWT post… Losing Ones Balance. It’s interesting. It might even have some merit… But this graph from Mr. Yeomans’ article doesn’t have any climatological merit, even if it is correct…
If the only difference between the Little Ice Age, the coldest climatic episode of the Holocene Epoch, is about 130 ppm CO2… Then CO2 isn’t such a bad thing.
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