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動画の字幕をクリックしてすぐ単語の意味を調べられます!
単語帳読み込み中…
字幕の修正報告
I'm here to talk to you about something important that may be new to you.
The governments of the world
are about to conduct an unintentional experiment
on our climate.
In 2020, new rules will require ships to lower their sulfur emissions
by scrubbing their dirty exhaust
or switching to cleaner fuels.
For human health, this is really good,
but sulfur particles in the emission of ships
also have an effect on clouds.
This is a satellite image of marine clouds
off the Pacific West Coast of the United States.
The streaks in the clouds are created by the exhaust from ships.
Ships' emissions include both greenhouse gases,
which trap heat over long periods of time,
and particulates like sulfates that mix with clouds
and temporarily make them brighter.
Brighter clouds reflect more sunlight back to space,
cooling the climate.
So in fact,
humans are currently running two unintentional experiments
on our climate.
In the first one, we're increasing the concentration of greenhouse gases
and gradually warming the earth system.
This works something like a fever in the human body.
If the fever remains low, its effects are mild,
but as the fever rises, damage grows more severe
and eventually devastating.
We're seeing a little of this now.
In our other experiment,
we're planning to remove a layer of particles
that brighten clouds and shield us from some of this warming.
The effect is strongest in ocean clouds like these,
and scientists expect the reduction of sulfur emissions from ships next year
to produce a measurable increase in global warming.
Bit of a shocker?
In fact, most emissions contain sulfates that brighten clouds:
coal, diesel exhaust, forest fires.
Scientists estimate that the total cooling effect from emission particles,
which they call aerosols when they're in the climate,
may be as much as all of the warming we've experienced up until now.
There's a lot of uncertainty around this effect,
and it's one of the major reasons why we have difficulty predicting climate,
but this is cooling that we'll lose as emissions fall.
So to be clear, humans are currently cooling the planet
by dispersing particles into the atmosphere at massive scale.
We just don't know how much, and we're doing it accidentally.
That's worrying,
but it could mean that we have a fast-acting way to reduce warming,
emergency medicine for our climate fever if we needed it,
and it's a medicine with origins in nature.
This is a NASA simulation of earth's atmosphere,
showing clouds and particles moving over the planet.
The brightness is the Sun's light reflecting from particles in clouds,
and this reflective shield is one of the primary ways
that nature keeps the planet cool enough for humans
and all of the life that we know.
In 2015, scientists assessed possibilities for rapidly cooling climate.
They discounted things like mirrors in space,
ping-pong balls in the ocean, plastic sheets on the Arctic,
and they found that the most viable approaches
involved slightly increasing this atmospheric reflectivity.
In fact, it's possible that reflecting just one or two percent more sunlight
from the atmosphere
could offset two degrees Celsius or more of warming.
Now, I'm a technology executive, not a scientist.
About a decade ago, concerned about climate,
I started to talk with scientists about potential countermeasures to warming.
These conversations grew into collaborations
that became the Marine Cloud Brightening Project,
which I'll talk about momentarily,
and the nonprofit policy organization SilverLining, where I am today.
I work with politicians, researchers,
members of the tech industry and others
to talk about some of these ideas.
Early on, I met British atmospheric scientist John Latham,
who proposed cooling the climate the way that the ships do,
but with a natural source of particles:
sea-salt mist from seawater
sprayed from ships into areas of susceptible clouds over the ocean.
The approach became known by the name I gave it then,
"marine cloud brightening."
Early modeling studies suggested that by deploying marine cloud brightening
in just 10 to 20 percent of susceptible ocean clouds,
it might be possible to offset as much as two degrees Celsius's warming.
It might even be possible to brighten clouds in local regions
to reduce the impacts caused by warming ocean surface temperatures.
For example, regions such as the Gulf Atlantic
might be cooled in the months before a hurricane season
to reduce the force of storms.
Or, it might be possible to cool waters flowing onto coral reefs
overwhelmed by heat stress,
like Australia's Great Barrier Reef.
But these ideas are only theoretical,
and brightening marine clouds is not the only way
to increase the reflection of the sunlight from the atmosphere.
Another occurs when large volcanoes release material with enough force
to reach the upper layer of the atmosphere, the stratosphere.
When Mount Pinatubo erupted in 1991,
it released material into the stratosphere,
including sulfates that mix with the atmosphere to reflect sunlight.
This material remained and circulated around the planet.
It was enough to cool the climate by over half a degree Celsius
for about two years.
This cooling led to a striking increase in Arctic ice cover in 1992,
which dropped in subsequent years as the particles fell back to earth.
But the volcanic phenomenon led Nobel Prize winner Paul Crutzen
to propose the idea that dispersing particles into the stratosphere
in a controlled way might be a way to counter global warming.
Now, this has risks that we don't understand,
including things like heating up the stratosphere
or damage to the ozone layer.
Scientists think that there could be safe approaches to this,
but is this really where we are?
Is this really worth considering?
This is a simulation
from the US National Center for Atmospheric Research
global climate model showing, earth surface temperatures through 2100.
The globe on the left visualizes our current trajectory,
and on the right, a world where particles are introduced into the stratosphere
gradually in 2020,
and maintained through 2100.
Intervention keeps surface temperatures near those of today,
while without it, temperatures rise well over three degrees.
This could be the difference between a safe and an unsafe world.
So, if there's even a chance that this could be close to reality,
is this something we should consider seriously?
Today, there are no capabilities,
and scientific knowledge is extremely limited.
We don't know whether these types of interventions are even feasible,
or how to characterize their risks.
Researchers hope to explore some basic questions
that might help us know whether or not these might be real options
or whether we should rule them out.
It requires multiple ways of studying the climate system,
including computer models to forecast changes,
analytic techniques like machine learning,
and many types of observations.
And though it's controversial,
it's also critical that researchers develop core technologies
and perform small-scale, real-world experiments.
There are two research programs proposing experiments like this.
At Harvard, the SCoPEx experiment would release very small amounts
of sulfates, calcium carbonate and water into the stratosphere with a balloon,
to study chemistry and physics effects.
How much material?
Less than the amount released in one minute of flight
from a commercial aircraft.
So this is definitely not dangerous,
and it may not even be scary.
At the University of Washington,
scientists hope to spray a fine mist of salt water into clouds
in a series of land and ocean tests.
If those are successful, this would culminate in experiments
to measurably brighten an area of clouds over the ocean.
The marine cloud brightening effort is the first to develop any technology
for generating aerosols for atmospheric sunlight reflection in this way.
It requires producing very tiny particles --
think about the mist that comes out of an asthma inhaler --
at massive scale -- so think of looking up at a cloud.
It's a tricky engineering problem.
So this one nozzle they developed
generates three trillion particles per second,
80 nanometers in size,
from very corrosive saltwater.
It was developed by a team of retired engineers in Silicon Valley --
here they are --
working full-time for six years, without pay, for their grandchildren.
It will take a few million dollars and another year or two
to develop the full spray system they need to do these experiments.
In other parts of the world, research efforts are emerging,
including small modeling programs at Beijing Normal University in China,
the Indian Institute of Science,
a proposed center for climate repair at Cambridge University in the UK
and the DECIMALS Fund,
which sponsors researchers in global South countries
to study the potential impacts of these sunlight interventions
in their part of the world.
But all of these programs, including the experimental ones,
lack significant funding.
And understanding these interventions is a hard problem.
The earth is a vast, complex system
and we need major investments in climate models, observations
and basic science
to be able to predict climate much better than we can today
and manage both our accidental and any intentional interventions.
And it could be urgent.
Recent scientific reports predict that in the next few decades,
earth's fever is on a path to devastation:
extreme heat and fires,
major loss of ocean life,
collapse of Arctic ice,
displacement and suffering for hundreds of millions of people.
The fever could even reach tipping points where warming takes over
and human efforts are no longer enough
to counter accelerating changes in natural systems.
To prevent this circumstance,
the UN's International Panel on Climate Change predicts
that we need to stop and even reverse emissions by 2050.
How? We have to quickly and radically transform major economic sectors,
including energy, construction, agriculture, transportation and others.
And it is imperative that we do this as fast as we can.
But our fever is now so high
that climate experts say we also have to remove
massive quantities of CO2 from the atmosphere,
possibly 10 times all of the world's annual emissions,
in ways that aren't proven yet.
Right now, we have slow-moving solutions to a fast-moving problem.
Even with the most optimistic assumptions,
our exposure to risk in the next 10 to 30 years
is unacceptably high, in my opinion.
Could interventions like these provide fast-acting medicine if we need it
to reduce the earth's fever while we address its underlying causes?
There are real concerns about this idea.
Some people are very worried that even researching these interventions
could provide an excuse to delay efforts to reduce emissions.
This is also known as a moral hazard.
But, like most medicines,
interventions are more dangerous the more that you do,
so research actually tends to draw out the fact
that we absolutely, positively cannot continue
to fill up the atmosphere with greenhouse gases,
that these kinds of alternatives are risky
and if we were to use them,
we would need to use as little as possible.
But even so,
could we ever learn enough about these interventions
to manage the risk?
Who would make decisions about when and how to intervene?
What if some people are worse off,
or they just think they are?
These are really hard problems.
But what really worries me is that as climate impacts worsen,
leaders will be called on to respond by any means available.
I for one don't want them to act without real information
and much better options.
Scientists think it will take a decade of research
just to assess these interventions,
before we ever were to develop or use them.
Yet today, the global level of investment in these interventions
is effectively zero.
So, we need to move quickly
if we want policymakers to have real information
on this kind of emergency medicine.
There is hope!
The world has solved these kinds of problems before.
In the 1970s, we identified an existential threat
to our protective ozone layer.
In the 1980s, scientists, politicians and industry
came together in a solution to replace the chemicals causing the problem.
They achieved this with the only legally binding environmental agreement
signed by all countries in the world,
the Montreal Protocol.
Still in force today,
it has resulted in a recovery of the ozone layer
and is the most successful environmental protection effort
in human history.
We have a far greater threat now,
but we do have the ability to develop and agree on solutions
to protect people
and restore our climate to health.
This could mean that to remain safe,
we reflect sunlight for a few decades,
while we green our industries and remove CO2.
It definitely means we must work now
to understand our options for this kind of emergency medicine.
Thank you,
(Applause)
コツ:単語をクリックしてすぐ意味を調べられます!

読み込み中…

【TED】Emergency medicine for our climate fever | Kelly Wanser

57 タグ追加 保存
林宜悉 2019 年 9 月 24 日 に公開
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