I was privileged to give one of the keynote
talks at the first joint meeting of the American Geophysical Union (AGU)
and the Chinese Academy of Sciences (CAS). The meeting was timely and
propitious. Both of these nations and the world as a whole need
increased cooperation between the United States and China, cooperation
in science and technology, cooperation based on facts and mutual
interests, cooperation upon which the future of young people and other
life on the planet depend.
All the charts and my talk are available on my web site as a Recent Presentation.
My talk is provided by the notes attached to each chart; I have edited
these descriptions for clarity. Please feel free to use these charts in
your classes or any other educational efforts – you do not need to ask
my permission. I have also included back-up charts not shown during my
talk.
My talk was nominally about atmospheric aerosols, the portion of the
climate story that is poorly defined, in contrast to the greenhouse gas
portion. However, we must look at the broad climate picture to
appreciate the importance of aerosols. Global warming accelerated
markedly in the past several years (see Chart 13). What is driving that
acceleration? I suggest that at least a portion of the increased
warming rate is probably because growth of atmospheric aerosols is no
longer keeping pace with growth of greenhouse gases.
Indeed, global aerosol forcing of climate may have stabilized or even
decreased slightly during the past several years, because of efforts to
reduce air pollution in parts of the world such as China. However, as I
emphasized in Storms of My Grandchildren, the high precision
global measurements needed to define changes in aerosol climate forcing,
especially the effect of aerosols on clouds, are not being made.
Historically, aerosol cooling has partially offset greenhouse gas
warming. Aerosols have a direct cooling effect by reflecting sunlight.
Increasing aerosols also have an indirect cooling effect by altering
the brightness and lifetime of clouds. The indirect effect arises
because some aerosols serve as cloud condensation nuclei, so they can
alter cloud particle size and thus the brightness and lifetime of
clouds.
The direct aerosol forcing is sensitive to small amounts of aerosol
absorption. The indirect effect via aerosol and cloud interactions is
complex. Computer modeling helps develop understanding of the
processes, but quantitative evaluation can only be achieved via global
satellite observations of aerosol and cloud microphysics to extremely
high precision. Specifically, the polarization of sunlight reflected by
the clouds and aerosols must be measured with an accuracy of 0.1
percent. The ability to achieve such accuracy has been demonstrated in
studies of the veil of smog that shrouds the planet Venus, but the
United States has been remarkably resistant to proposals to make
polarization measurements of Earth to that accuracy, as will be
recounted in detail in Sophie’s Planet.
There are other reasons, besides interpretation of accelerating global
warming, for measuring global aerosol properties very accurately.
Human-made aerosols are carried by the winds and deposited on land and
ocean surfaces almost globally. These aerosols contain nutrients such
as nitrogen, phosphorous and iron, which, together with increasing
atmospheric CO2, fertilize Earth’s biosphere (see Charts 10
and 11). We have suggested that this fertilization effect is at least
partly responsible for increased uptake of fossil fuel carbon during the
past three decades, compared with the preceding three decades (see
Charts 8 and 9). If this interpretation is correct, we can anticipate
that continuing efforts to reduce particulate air pollution, which is
essential for the sake of human health, will lead to an upsurge of
atmospheric CO2. Again, precise global satellite measurement of aerosols is needed, in coordination with surface data and modeling.
Still another reason to monitor and understand aerosol climate effects
relates to the likelihood that the world will overshoot the safe level
of atmospheric CO2. Indeed, Chart 21 implies that we have already overshot the level of CO2 that will be safe on the long-term. Because of the time required to draw down atmospheric CO2,
even with aggressive phase-out of fossil fuels (see Charts 51 and 52),
it may prove essential to take steps to alter Earth’s energy imbalance
and the rate of ice melt, if the loss of coastal cities is to be
averted.
We are not at a point to recommend such actions, but there is a real
danger that such a point may be reached, especially if phase-out of
fossil fuels as our principal energy source is not achieved soon. Most
large cities are located on coastlines (see Chart 23), China has several
hundred million people living near sea level (Chart 24), and much of
global infrastructure is on coastlines.
One of the oldest proposals for solar radiation management (SRM),
popularized by Russian climatologist Mikhail Budyko, is to mimic the
effect of volcanoes by injecting SO2 gas into the
stratosphere. This would form aerosols that reflect sunlight, cooling
Earth. Because the aerosols fall out on a time scale of about a year,
they require continual replenishment, and thus this purposeful
intervention with climate can be terminated easily, if it is found to
have undesirable effects.
Focused objectives of SRM might be achieved via the latitude of SO2
injection. Stratospheric aerosols tend to move toward the poles, where
they descend and are “washed out” of the atmosphere. Thus we are
carrying out climate simulations for four idealized distributions of
stratospheric aerosols: (1) globally uniform, (2) Southern Hemisphere,
(3) Southern Ocean and Antarctica, and (4) Antarctica (see Chart 33).
Aerosol properties and amount correspond to those in the year after the
Pinatubo eruption. The most interesting result is for case (3), which
has aerosols over the Southern Ocean and Antarctica. This leads to
large cooling of the internal ocean along the coast of Antarctica at the
depths where ice sheets are presently melting rapidly (see Chart 35).
The ocean temperature response is the mirror opposite to the warming at
depth (and surface cooling) found in observations and in our simulations
for increasing greenhouse gases (see our Ice Melt, Sea Level Rise & Superstorms paper).
We are not suggesting such aerosol experiments in the real world. SRM
seems appropriate only as a last resort, if we are unable to achieve
phasedown of fossil fuel emissions and atmospheric CO2
levels, and if unacceptable consequences such as loss of coastal cities
seem to be in the offing. Even if aerosols were confined to the
Southern Ocean and Antarctic region, they likely would affect some
populated areas such as New Zealand. The aerosols might also have
undesirable effects such as ozone depletion. The principal effect of
such studies should be a redoubling of efforts to phase down CO2 emissions.
There is breaking news on the efforts to minimize human-made climate
change. First, in remarkably good news, Citizens Climate Lobby (CCL) is
reporting that Canada plans to adopt carbon fee & dividend,
beginning in January 2019; I copy the press release from CCL below.
Second, the Supreme Court of the United States has ordered a temporary
administrative stay in the Juliana v. United States case while it
considers the federal government’s most recent writ of mandamus
petition. The OCT attorney’s filed their response to the Supreme Court
on 22 October and requested the Court to allow the trial to proceed. We
are awaiting the Supreme Court’s response.
If the CCL and OCT efforts bear fruit, especially in the United States, it becomes plausible to imagine that global CO2 emissions could begin a real decreasing trend within a few years. The climate simulations in Young People’s Burden show that global warming can be kept less than +1.5°C, if phasedown of emissions begins in 2021 (Charts 51 and 52).
Ultimately the fate of the planet and the future of young people, their
offspring, and other life on Earth depends upon cooperation between the
United States and China. If these nations agree to a rising carbon fee,
it could be made near global (Charts 43 and 44). Cooperation should
extend to technology, because the crucial requirement for deep
decarbonization is carbon-free electricity generation.
CCL Press Release follows:
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