[geo] HERE’S HOW WE COULD BRIGHTEN CLOUDS TO COOL THE EARTH

[Geoeng Info]

https://spectrum.ieee.org/climate-change


*HERE’S HOW WE COULD BRIGHTEN CLOUDS TO COOL THE EARTH*

*AS WE CONFRONT *the enormous challenge of climate change, we should take
inspiration from even the most unlikely sources. Take, for example, the
tens of thousands of fossil-fueled ships that chug across the ocean,
spewing plumes of pollutants that contribute to acid rain, ozone depletion,
respiratory ailments, and global warming.

The particles produced by these ship emissions can also create brighter
clouds, which in turn can produce a cooling effect via processes that occur
naturally in our atmosphere. What if we could achieve this cooling effect
without simultaneously releasing the greenhouse gases and toxic pollutants
that ships emit? That's the question the *Marine Cloud Brightening (MCB)
Project* <https://faculty.washington.edu/robwood2/wordpress/?page_id=954>
intends
to answer.

Scientists have known for decades that the particulate emissions from ships
can have a dramatic effect on low-lying stratocumulus clouds above the
ocean. In satellite images, parts of the Earth's oceans are streaked with
bright white strips of clouds that correspond to shipping lanes. These
artificially brightened clouds are a result of the tiny particles produced
by the ships, and they reflect more sunlight back to space than unperturbed
clouds do, and much more than the dark blue ocean underneath. Since these
"ship tracks" block some of the sun's energy from reaching Earth's surface,
they prevent some of the warming that would otherwise occur.

The formation of ship tracks is governed by the same basic principles
behind all cloud formation. Clouds naturally appear when the relative
humidity exceeds 100 percent, initiating condensation in the atmosphere.
Individual cloud droplets form around microscopic particles called cloud
condensation nuclei (CCN). Generally speaking, an increase in CCN increases
the number of cloud droplets while reducing their size. Through a
phenomenon known as the *Twomey effect*
<https://atmos.uw.edu/~robwood/teaching/591/ATMS_591_Twomey_1977.pdf>, this
high concentration of droplets boosts the clouds' reflectivity (also called
*albedo* <https://en.wikipedia.org/wiki/Albedo>). Sources of CCN include
aerosols like dust, pollen, soot, and even bacteria, along with man-made
pollution from factories and ships. Over remote parts of the ocean, most
CCN are of natural origin and include sea salt from crashing ocean waves.

[image: Satellite imagery. To the left is white clouds with tracks forming
within. To the left is green and brown land mass.]
Satellite imagery shows "ship tracks" over the ocean: bright clouds that
form because of particles spewed out by ships.JEFF SCHMALTZ/MODIS RAPID
RESPONSE TEAM/GSFC/NASA

The aim of the MCB Project is to consider whether deliberately adding more
sea salt CCN to low marine clouds would cool the planet. The CCN would be
generated by spraying seawater from ships. We expect that the sprayed
seawater would instantly dry in the air and form tiny particles of salt,
which would rise to the cloud layer via convection and act as seeds for
cloud droplets. These generated particles would be much smaller than the
particles from crashing waves, so there would be only a small relative
increase in sea salt mass in the atmosphere. The goal would be to produce
clouds that are slightly brighter (by 5 to 10 percent) and possibly longer
lasting than typical clouds, resulting in more sunlight being reflected
back to space.

*"Solar climate intervention
<https://www.nationalacademies.org/our-work/developing-a-research-agenda-and-research-governance-approaches-for-climate-intervention-strategies-that-reflect-sunlight-to-cool-earth>"*
is
the umbrella term for projects such as ours that involve reflecting
sunlight to reduce global warming and its most dangerous impacts. Other
proposals include sprinkling reflective silicate beads over polar ice
sheets and injecting materials with reflective properties, such as sulfates
or calcium carbonate, into the stratosphere. None of the approaches in this
young field are well understood, and they all carry potentially large
unknown risks.

Solar climate intervention is *not* a replacement for reducing greenhouse
gas emissions, which is imperative. But such reductions won't address
warming from existing greenhouse gases that are already in the atmosphere.
As the effects of climate change intensify and tipping points are reached,
we may need options to prevent the most catastrophic consequences to
ecosystems and human life. And we'll need a clear understanding of both the
efficacy and risks of solar climate intervention technologies so people can
make informed decisions about whether to implement them.

Our team, based at the *University of Washington*
<https://faculty.washington.edu/robwood2/wordpress/?page_id=954>, the *Palo
Alto Research Center*
<https://www.parc.com/about-parc/our-people/kate-murphy/> (PARC), and
the *Pacific
Northwest National Laboratory* <https://www.pnnl.gov/>, comprises experts
in climate modeling, aerosol-cloud interactions, fluid dynamics, and spray
systems. We see several key advantages to marine cloud brightening over
other proposed forms of solar climate intervention. Using seawater to
generate the particles gives us a free, abundant source of environmentally
benign material, most of which would be returned to the ocean through
deposition. Also, MCB could be done from sea level and wouldn't rely on
aircraft, so costs and associated emissions would be relatively low.

The effects of particles on clouds are temporary and localized, so
experiments on MCB could be carried out over small areas and brief time
periods (maybe spraying for a few hours per day over several weeks or
months) without seriously perturbing the environment or global climate.
These small studies would still yield significant information on the
impacts of brightening. What's more, we can quickly halt the use of MCB,
with very rapid cessation of its effects.

Solar climate intervention is the umbrella term for projects that involve
reflecting sunlight to reduce global warming and its most dangerous impacts.

Our project encompasses three critical areas of research. First, we need to
find out if we can reliably and predictably increase reflectivity. To this
end, we'll need to quantify how the addition of generated sea salt
particles changes the number of droplets in these clouds, and study how
clouds behave when they have more droplets. Depending on atmospheric
conditions, MCB could affect things like cloud droplet evaporation rate,
the likelihood of precipitation, and cloud lifetime. Quantifying such
effects will require both simulations and field experiments.

Second, we need more modeling to understand how MCB would affect weather
and climate both locally and globally. It will be crucial to study any
negative unintended consequences using accurate simulations before anyone
considers implementation. Our team is initially focusing on modeling how
clouds respond to additional CCN. At some point we'll have to check our
work with small-scale field studies, which will in turn improve the
regional and global simulations we'll run to understand the potential
impacts of MCB under different climate change scenarios.

The third critical area of research is the development of a spray system
that can produce the size and concentration of particles needed for the
first small-scale field experiments. We'll explain below how we're tackling
that challenge.

*One of the first* *steps* in our project was to identify the clouds most
amenable to brightening. Through modeling and observational studies, we
determined that the best target is *stratocumulus clouds*
<https://en.wikipedia.org/wiki/Stratocumulus_cloud>, which are low altitude
(around 1 to 2 km) and shallow; we're particularly interested in "clean"
stratocumulus, which have low numbers of CCN. The increase in cloud albedo
with the addition of CCN is generally strong in these clouds, whereas in
deeper and more highly convective clouds other processes determine their
brightness. Clouds over the ocean tend to be clean stratocumulus clouds,
which is fortunate, because brightening clouds over dark surfaces, such as
the ocean, will yield the highest albedo change. They're also conveniently
close to the liquid we want to spray.

[image: Two part diagram. Top is labelled Twomey Effect. Two cloud shapes
with droplets, and the left says "lower albedo" "fewer larger drops". The
right says "higher albedo" "more smaller drops". Between says
"macrophysically identical clouds. The bottom is labelled "Cloud
Adjustments". Three more clouds with droplets include left "more smaller
drops", two arrows next to "Macrophysical cloud responses" and the top
arrow points to "higher albedo" "suppressed precipitation" and the bottom
arrow to "lower albedo" "enhanced entrainment"]
In the phenomenon called the Twomey effect, clouds with higher
concentrations of small particles have a higher albedo, meaning they're
more reflective. Such clouds might be less likely to produce rain, and the
retained cloud water would keep albedo high. On the other hand, if dry air
from above the cloud mixes in (entrainment), the cloud may produce rain and
have a lower albedo. The full impact of MCB will be the combination of the
Twomey effect and these cloud adjustments. ROB WOOD

Based on our cloud type, we can estimate the number of particles to
generate to see a measurable change in albedo. Our calculation involves the
typical aerosol concentrations in clean marine stratocumulus clouds and the
increase in CCN concentration needed to optimize the cloud brightening
effect, which we estimate at 300 to 400 per cubic centimeter. We also take
into account the dynamics of this part of the atmosphere, called the marine
boundary layer, considering both the layer's depth and the roughly
three-day lifespan of particles within it. Given all those factors, we
estimate that a single spray system would need to continuously deliver
approximately 3x10 15 particles per second to a cloud layer that covers
about 2,000 square kilometers. Since it's likely that not every particle
will reach the clouds, we should aim for an order or two greater.

We can also determine the ideal particle size based on initial cloud
modeling studies and efficiency considerations. These studies indicate that
the spray system needs to generate seawater droplets that will dry to salt
crystals of just 30–100 nanometers in diameter. Any smaller than that and
the particles will not act as CCN. Particles larger than a couple hundred
nanometers are still effective, but their larger mass means that energy is
wasted in creating them. And particles that are significantly larger than
several hundred nanometers can have a negative effect, since they can
trigger rainfall that results in cloud loss.

We need a clear understanding of both the efficacy and risks of solar
climate intervention technologies so people can make informed decisions
about whether to implement them.

Creating dry salt crystals of the optimal size requires spraying seawater
droplets of 120–400 nm in diameter, which is surprisingly difficult to do
in an energy-efficient way. Conventional spray nozzles, where water is
forced through a narrow orifice, produce mists with diameters from tens of
micrometers to several millimeters. To decrease the droplet size by a
factor of ten, the pressure through the nozzle must increase more than
2,000 times. Other atomizers, like the ultrasonic nebulizers found in home
humidifiers, similarly cannot produce small enough droplets without
extremely high frequencies and power requirements.

Solving this problem required both out-of-the-box thinking and expertise in
the production of small particles. That's where *Armand Neukermans*
<https://www.linkedin.com/in/armand-neukermans-3a284113> came in.

[image: black and white photo of a woman with dark hair and a striped shirt]
Kate Murphy leads the engineering effort for the MCB project at PARC, the
Xerox research lab in Silicon Valley. CHRISTOPHER MICHEL

[image: black and white photo of an older man with white hair wearing
glasses and a striped shirt]
Armand Neukermans brought his expertise in ink jet printers to bear on the
quest to make nozzles that could efficiently and reliably spray tiny
droplets of seawater. CHRISTOPHER MICHEL

*After a distinguished career* at HP and Xerox focused on production of
toner particles and ink jet printers, in 2009 Neukermans was approached by
several eminent climate scientists, who asked him to turn his expertise
toward making seawater droplets. He quickly assembled a cadre of
volunteers—mostly *retired engineers and scientists*
<https://spectrum.ieee.org/view-from-the-valley/energy/environment/tech-industry-vets-fight-effects-of-climate-change>
*. *and over the next decade, these self-designated "Old Salts" tackled the
challenge. They worked in a borrowed Silicon Valley laboratory, using
equipment scrounged from their garages or purchased out of their own
pockets. They explored several ways of producing the desired particle size
distributions with various tradeoffs between particle size, energy
efficiency, technical complexity, reliability, and cost. In 2019 they moved
into a lab space at PARC, where they have access to equipment, materials,
facilities, and more scientists with expertise in aerosols, fluid dynamics,
microfabrication, and electronics.

The three most promising techniques identified by the team were
effervescent spray nozzles, spraying salt water under supercritical
conditions, and electrospraying to form Taylor cones (which we'll explain
later). The first option was deemed the easiest to scale up quickly, so the
team moved forward with it. In an effervescent nozzle, pressurized air and
salt water are pumped into a single channel, where the air flows through
the center and the water swirls around the sides. When the mixture exits
the nozzle, it produces droplets with sizes ranging from tens of nanometers
to a few micrometers, with the overwhelming number of particles in our
desired size range. Effervescent nozzles are used in a range of
applications, including engines, gas turbines, and spray coatings.

The key to this technology lies in the compressibility of air. As a gas
flows through a constricted space, its velocity increases as the ratio of
the upstream to downstream pressures increases. This relationship holds
until the gas velocity reaches the speed of sound. As the compressed air
leaves the nozzle at sonic speeds and enters the environment, which is at
much lower pressure, the air undergoes a rapid radial expansion that
explodes the surrounding ring of water into tiny droplets.

[image: A man and a woman wearing masks stand at a table in a white tent.
In the foreground is silver and blue equipment including a nozzle from
which white spray is emitting.]
Coauthor Gary Cooper and intern Jessica Medrado test the effervescent
nozzle inside the tent. KATE MURPHY

Neukermans and company found that the effervescent nozzle works well enough
for small-scale testing, but the efficiency—the energy required per
correctly sized droplet—still needs to be improved. The two biggest sources
of waste in our system are the large amounts of compressed air needed and
the large fraction of droplets that are too big. Our latest efforts have
focused on redesigning the flow paths in the nozzle to require smaller
volumes of air. We're also working to filter out the large droplets that
could trigger rainfall. And to improve the distribution of droplet size,
we're considering ways to add charge to the droplets; the repulsion between
charged droplets would inhibit coalescence, decreasing the number of
oversized droplets.

*Though we're making* *progress* with the effervescent nozzle, it never
hurts to have a backup plan. And so we're also exploring *electrospray*
<https://en.wikipedia.org/wiki/Electrospray> technology, which could yield
a spray in which almost 100 percent of the droplets are within the desired
size range. In this technique, seawater is fed through an emitter—a narrow
orifice or capillary—while an extractor creates a large electric field. If
the electrical force is of similar magnitude to the surface tension of the
water, the liquid deforms into a cone, typically referred to as a *Taylor
cone* <https://en.wikipedia.org/wiki/Taylor_cone>. Over some threshold
voltage, the cone tip emits a jet that quickly breaks up into highly
charged droplets. The droplets divide until they reach their *Rayleigh
limit* <https://en.wikipedia.org/wiki/Electrospray#History>, the point
where charge repulsion balances the surface tension. Fortuitously, surface
seawater's typical conductivity (4 Siemens per meter) and surface tension
(73 millinewtons per meter) yield droplets in our desired size range. The
final droplet size can even be tuned via the electric field down to tens of
nanometers, with a tighter size distribution than we get from mechanical
nozzles.

[image: Electrospray diagram with a row of black rectagular shapes, then
blue cones over small dots, a blue line and gray boxes, labelled Extractor,
Taylor cone, capillary array (ground), filter, housing and on the bottom,
salt water]
This diagram (not to scale) depicts the electrospray system, which uses an
electric field to create cones of water that break up into tiny droplets. KATE
MURPHY

Electrospray is relatively simple to demonstrate with a single
emitter-extractor pair, but one emitter only produces 10 7–109 droplets per
second, whereas we need 1016–1017 per second. Producing that amount
requires an array of up to 100,000 by 100,000 capillaries. Building such an
array is no small feat. We're relying on techniques more commonly
associated with cloud computing than actual clouds. Using the same
lithography, etch, and deposition techniques used to make integrated
circuits, we can fabricate large arrays of tiny capillaries with aligned
extractors and precisely placed electrodes.

[image: Two micrograph images. Left shows rows of circular nozzles with
darker circular centers. Right is a close-up.]
Images taken by a scanning electron microscope show the capillary emitters
used in the electrospray system. KATE MURPHY

Testing our technologies presents yet another set of challenges. Ideally,
we would like to know the initial size distribution of the saltwater
droplets. In practice, that's nearly impossible to measure. Most of our
droplets are smaller than the wavelength of light, precluding non-contact
measurements based on light scattering. Instead, we must measure particle
sizes downstream, after the plume has evolved. Our primary tool,
called a *scanning
electrical mobility spectrometer*
<https://www.tandfonline.com/doi/abs/10.1080/02786829008959441>, measures
the mobility of charged dry particles in an electrical field to determine
their diameter. But that method is sensitive to factors like the room's
size and air currents and whether the particles collide with objects in the
room.

To address these problems, we built a sealed 425 cubic meter tent, equipped
with dehumidifiers, fans, filters, and an array of connected sensors.
Working in the tent allows us to spray for longer periods of time and with
multiple nozzles, without the particle concentration or humidity becoming
higher than what we would see in the field. We can also study how the spray
plumes from multiple nozzles interact and evolve over time. What's more, we
can more precisely mimic conditions over the ocean and tune parameters such
as air speed and humidity.

[image: 4 people in a large white text looking at equipment on a table]
Part of the team inside the test tent; from left, "Old Salts" Lee Galbraith
and Gary Cooper, Kate Murphy of PARC, and intern Jessica Medrado. KATE
MURPHY

*We'll eventually outgrow the tent* and have to move to a large indoor
space to continue our testing. The next step will be outdoor testing to
study plume behavior in real conditions, though not at a high enough rate
that we would measurably perturb the clouds. We'd like to measure particle
size and concentrations far downstream of our sprayer, from hundreds of
meters to several kilometers, to determine if the particles lift or sink
and how far they spread. Such experiments will help us optimize our
technology, answering such questions as whether we need to add heat to our
system to encourage the particles to rise to the cloud layer.

The data obtained in these preliminary tests will also inform our models.
And if the results of the model studies are promising, we can proceed to
field experiments in which clouds are brightened sufficiently to study key
processes. As discussed above, such experiments would be performed over a
small and short time so that any effects on climate wouldn't be
significant. These experiments would provide a critical check of our
simulations, and therefore of our ability to accurately predict the impacts
of MCB.

It's still unclear whether MCB could help society avoid the worst impacts
of climate change, or whether it's too risky, or not effective enough to be
useful. At this point, we don't know enough to advocate for its
implementation, and we're definitely not suggesting it as an alternative to
reducing emissions. The intent of our research is to provide policymakers
and society with the data needed to assess MCB as one approach to slow
warming, providing information on both its potential and risks. To this
end, we've submitted our experimental plans for review by the *U.S.
National Oceanic and Atmospheric Administration* <https://www.noaa.gov/> and
for open publication as part of a U.S. National Academy of Sciences study
of research in the field of solar climate intervention. We hope that we can
shed light on the feasibility of MCB as a tool to make the planet safer.

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