PDF versions of the udpated "Beginner's Guide
to the UN Framework Convention and its Kyoto Protocol"
are available here in English,
French, and Spanish.
Understanding Climate Change:
A Beginner's Guide to the UN Framework Convention
and its Kyoto Protocol
First act: the Convention
A giant asteroid could hit the earth! Something
else could happen! The global temperature could rise!
Wake up!
The last several decades have been a time of international
soul-searching about the environment. What are we doing
to our planet? More and more, we are realizing that
the Industrial Revolution has changed forever the relationship
between humanity and nature. There is real concern that
by the middle or the end of the 21st century
human activities will have changed the basic conditions
that have allowed life to thrive on earth.
The 1992 United Nations Framework Convention on
Climate Change is one of a series of recent agreements
through which countries around the world are banding
together to meet this challenge. Other treaties deal
with such matters as pollution of the oceans, dryland
degradation, damage to the ozone layer, and the rapid
extinction of plant and animal species. The Climate
Change Convention focuses on something particularly
disturbing: we are changing the way energy from the
sun interacts with and escapes from our planet's atmosphere.
By doing that, we risk altering the global climate.
Among the expected consequences are an increase in the
average temperature of the earth's surface and shifts
in world-wide weather patterns. Other -- unforeseen
-- effects cannot be ruled out.
We have a few problems to face up to.
Problem No. 1 (the big problem): Scientists
see a real risk that the climate will change rapidly
and dramatically over the coming decades and centuries.
Can we handle it?
A giant asteroid did hit the earth -- about 65 million
years ago. Splat. Scientists speculate that the
collision threw so much dust into the atmosphere that
the world was dark for three years. Sunlight was greatly
reduced, so many plants could not grow, temperatures
fell, the food chain collapsed, and many species, including
the largest ever to walk the earth, died off.
That, at least, is the prevailing theory of why the
dinosaurs became extinct. Even those who weren't actually
hit by the asteroid paid the ultimate price.
The catastrophe that befell the dinosaurs is only
one illustration, if dramatic, of how changes in climate
can make or break a species.
According to another theory, human beings evolved
when a drying trend some 10 million years ago was followed
around three million years ago by a sharp drop in world
temperature. The ape-like higher primates in the Great
Rift Valley of Africa were used to sheltering in trees,
but, under this long-term climate shift, the trees were
replaced with grassland. The 'apes' found themselves
on an empty plain much colder and drier than what they
were used to, and extremely vulnerable to predators.
Extinction was a real possibility, and the primates
appear to have responded with two evolutionary jumps
-- first to creatures who could walk upright over long
distances, with hands free for carrying children and
food; and then to creatures with much larger brains,
who used tools and were omnivorous (could eat both plants
and meat). This second, large-brained creature is generally
considered to be the first human.
Shifts in climate have shaped human destiny ever since,
and people have largely responded by adapting, migrating,
and growing smarter. During a later series of ice ages,
sea levels dropped and humans moved across land bridges
from Asia to the Americas and the Pacific islands. Many
subsequent migrations, many innovations, many catastrophes
have followed. Some can be traced to smaller climatic
fluctuations, such as a few decades or centuries of
slightly higher or lower temperatures, or extended droughts.
Best known is the Little Ice Age that struck Europe
in the early Middle Ages, bringing famines, uprisings,
and the withdrawal of northern colonies in Iceland and
Greenland. People have suffered under the whims of climate
for millennia, responding with their wits, unable to
influence these large events.
Until now. Ironically, we humans have been so remarkably
successful as a species that we may have backed ourselves
into a corner. Our numbers have grown to the point where
we have less room for large-scale migration should a
major climate shift call for it. And the products of
our large brains -- our industries, transport, and other
activities -- have led to something unheard of in the
past. Previously the global climate changed human beings.
Now human beings seem to be changing the global climate.
The results are uncertain, but if current predictions
prove correct, the climatic changes over the coming
century will be larger than any since the dawn of human
civilization.
The principal change to date is in the earth's atmosphere.
The giant asteroid that felled the dinosaurs threw large
clouds of dust into the air, but we are causing something
just as profound if more subtle. We have changed, and
are continuing to change, the balance of gases that
form the atmosphere. This is especially true of such
key "greenhouse gases" as carbon dioxide (CO2),
methane (CH4), and nitrous oxide (N2O).
(Water vapour is the most important greenhouse gas,
but human activities do not affect it directly.) These
naturally occurring gases make up less than one tenth
of one per cent of the total atmosphere, which consists
mostly of oxygen (21 per cent) and nitrogen (78 per
cent). But greenhouse gases are vital because they act
like a blanket around the earth. Without this natural
blanket the earth's surface would be some 30°C
colder than it is today.
The problem is that human activity is making the blanket
"thicker". For example, when we burn coal,
oil, and natural gas we spew huge amounts of carbon
dioxide into the air. When we destroy forests the carbon
stored in the trees escapes to the atmosphere. Other
basic activities, such as raising cattle and planting
rice, emit methane, nitrous oxide, and other greenhouse
gases. If emissions continue to grow at current rates,
it is almost certain that atmospheric levels of carbon
dioxide will double from pre-industrial levels during
the 21st century. If no steps are taken to slow greenhouse
gas emissions, it is quite possible that levels will
triple by the year 2100.
The most direct result, says the scientific consensus,
is likely to be a "global warming" of 1 to
3.5°C over the next 100 years. That is in addition
to an apparent temperature increase of around half a
degree Centigrade since the pre-industrial period before
1850, at least some of which may be due to past greenhouse
gas emissions.
Just how this would affect us is hard to predict because
the global climate is a very complicated system. If
one key aspect -- such as the average global temperature
-- is altered, the ramifications ripple outward. Uncertain
effects pile onto uncertain effects. For example, wind
and rainfall patterns that have prevailed for hundreds
or thousands of years, and on which millions of people
depend, may change. Sea-levels may rise and threaten
islands and low-lying coastal areas. In a world that
is increasingly crowded and under stress -- a world
that has enough problems already -- these extra pressures
could lead directly to more famines and other catastrophes.
While scientists are scrambling to understand more
clearly the effects of our greenhouse gas emissions,
countries around the globe have joined together to confront
the problem.
How the Convention responds
-- It recognizes that there is a problem. That's
a significant step. It is not easy for the nations of
the world to agree on a common course of action, especially
one that tackles a problem whose consequences are uncertain
and which will be more important for our grandchildren
than for the present generation. Still, the Convention
was negotiated in a little over two years, and over
175 states have ratified and so are legally bound by
it. The treaty took effect on 21 March 1994.
-- It sets an "ultimate objective" of
stabilizing "greenhouse gas concentrations in the
atmosphere at a level that would prevent dangerous anthropogenic
(human-induced) interference with the climate system."
The objective does not specify what these concentrations
should be, only that they be at a level that is not
dangerous. This acknowledges that there is currently
no scientific certainty about what a dangerous level
would be. Scientists believe it will take about another
decade (and the next generation of supercomputers) before
today's uncertainties (or many of them) are significantly
reduced. The Convention's objective thus remains meaningful
no matter how the science evolves.
-- It directs that "such a level should be
achieved within a time-frame sufficient to allow ecosystems
to adapt naturally to climate change, to ensure that
food production is not threatened and to enable economic
development to proceed in a sustainable manner."
This highlights the main concerns about food production
-- probably the most climate-sensitive human activity
-- and economic development. It also suggests (as most
climatologists believe) that some change is inevitable
and that adaptive as well as preventive measures are
called for.
Again, this leaves room for interpretation in the
light of scientific findings and the trade-offs and
risks that the global community is willing to accept.
Problem No. 2: If the consequences of a problem
are uncertain, do you ignore the problem or do you do
something about it anyway?
Climate change is a threat to mankind. But no one
is certain about its future effects or their severity.
Responding to the threat is expected to be complicated
and difficult. There is even some remaining disagreement
over whether any problem exists at all: while many people
worry that the effects will be extremely serious, others
still argue that scientists cannot prove that what they
suspect will happen will actually happen. In addition,
it is not clear who (in the various regions of the world)
will suffer most. Yet if the nations of the world wait
until the consequences and victims are clear, it will
probably be too late to act. What should we do?
The truth is that in most scientific circles the issue
is no longer whether or not climate change is a potentially
serious problem. Rather, it is how the problem will
develop, what its effects will be, and how these effects
can best be detected. Computer models of something as
complicated as the planet's climate system are not far
enough advanced yet to give clear and unambiguous answers.
Nevertheless, while the when, where, and how remain
uncertain, the big picture painted by these climate
models cries out for attention.
For example:
-- Regional rain patterns may change. At the
global level, the evapo-transpiration cycle is expected
to speed up. This means that it would rain more, but
the rain would evaporate faster, leaving soils drier
during critical parts of the growing season. New or
worsening droughts, especially in poorer countries,
could reduce supplies of clean, fresh water to the point
where there are major threats to public health. Because
they still lack confidence in regional scenarios, scientists
are uncertain about which areas of the world risk becoming
wetter and which drier. But with global water resources
already under severe strain from rapid population growth
and expanding economic activity, the danger is clear.
-- Climate and agricultural zones may shift towards
the poles. In the mid-latitude regions the shift
is expected to be 150 to 550 kilometres for a warming
of 1-3.5°C. Increased summer dryness may reduce
mid-latitude crop yields, and it is possible that today's
leading grain-producing areas (such as the Great Plains
of the United States) would experience more frequent
droughts and heat waves. The poleward edges of the mid-latitude
agricultural zones -- northern Canada, Scandinavia,
Russia, and Japan in the northern hemisphere, and southern
Chile and Argentina in the southern hemisphere -- might
benefit from higher temperatures. However, in some areas
rugged terrain and poor soil would prevent these countries
from compensating for reduced yields in today's more
productive areas.
-- Melting glaciers and the thermal expansion of
sea water may raise sea levels, threatening low-lying
coastal areas and small islands. The global mean
sea level has already risen by around 10 to 15 centimetres
during the past century, and global warming is expected
to cause a further rise of 15 to 95 cm by the year 2100
(with a "best estimate" of 50 cm). The most
vulnerable land would be the unprotected, densely populated
coastal regions of some of the world's poorest countries.
Bangladesh, whose coast is already prone to devastating
floods, would be a likely victim, as would many small
island states such as the Maldives.
These scenarios are alarming enough to raise concern,
but too uncertain for easy decisions by governments.
The picture is fuzzy. Some governments, beleaguered
by other problems and responsibilities and bills to
pay, have understandably been tempted to do nothing
at all. Maybe the threat will go away. Or someone else
will deal with it. Maybe another giant asteroid will
hit the earth. Who knows?
How the Convention responds
-- It establishes a framework and a process for
agreeing to specific actions -- later. The diplomats
who wrote the Framework Convention on Climate Change
saw it as a launching pad for potential further action
in the future. They recognized that it would not be
possible in the year 1992 for the world's governments
to agree on a detailed blueprint for tackling climate
change. But by establishing a framework of general principles
and institutions, and by setting up a process through
which governments meet regularly, they got things started.
A key benefit of this approach is that it allowed
countries to begin discussing the issue even before
they all fully agreed that it is, in fact, a problem.
Even skeptical countries have felt it is worthwhile
participating. (Or, to put it another way, they would
have felt uneasy about being left out.) This created
legitimacy for the issue, and a sort of international
peer pressure to take the subject seriously.
The Convention is designed to allow countries to weaken
or strengthen the treaty in response to new scientific
developments. For example, they can agree to take more
specific actions (such as reducing emissions of greenhouse
gases by a certain amount) by adopting "amendments"
or "protocols" to the Convention. This is
what happened in 1997 with the adoption of the Kyoto
Protocol.
The treaty promotes action in spite of uncertainty
on the basis of a recent development in international
law and diplomacy called the "precautionary principle."
Under traditional international law, an activity generally
has not been restricted or prohibited unless a direct
causal link between the activity and a particular damage
can be shown. But many environmental problems, such
as damage to the ozone layer and pollution of the oceans,
cannot be confronted if final proof of cause and effect
is required. In response, the international community
has gradually come to accept the precautionary principle,
under which activities that threaten serious or irreversible
damage can be restricted or even prohibited before
there is absolute scientific certainty about their effects.
-- The Convention takes preliminary steps that
clearly make sense for the time being. Countries
ratifying the Convention -- called "Parties to
the Convention" in diplomatic jargon -- agree to
take climate change into account in such matters as
agriculture, energy, natural resources, and activities
involving sea-coasts. They agree to develop national
programmes to slow climate change. The Convention encourages
them to share technology and to cooperate in other ways
to reduce greenhouse gas emissions, especially from
energy, transport, industry, agriculture, forestry,
and waste management, which together produce nearly
all greenhouse gas emissions attributable to human activity.
-- The Convention encourages scientific research
on climate change. It calls for data gathering,
research, and climate observation, and it creates a
"subsidiary body" for "scientific and
technological advice" to help governments decide
what to do next. Each country that is a Party to the
Convention must also develop a greenhouse gas "inventory"
listing its national sources (such as factories and
transport) and "sinks" (forests and other
natural ecosystems that absorb greenhouse gases from
the atmosphere). These inventories must be updated regularly
and made public. The information they provide on which
activities emit how much of each gas is essential for
monitoring changes in emissions and determining the
effects of measures taken to control emissions.
Problem No. 3: It's not fair.
If a giant asteroid hits the earth, that's nobody's
fault. The same cannot be said for global warming.
There is a fundamental unfairness to the climate change
problem that chafes at the already uneasy relations
between the rich and poor nations of the world. Countries
with high standards of living are mostly (if unwittingly)
responsible for the rise in greenhouse gases. These
early industrializers -- Europe, North America, Japan,
and a few others -- created their wealth in part by
pumping into the atmosphere vast amounts of greenhouse
gases long before the likely consequences were understood.
Developing countries now fear being told that they should
curtail their own fledgling industrial activities --
that the atmosphere's safety margin is all used up.
Because energy-related emissions are the leading cause
of climate change, there will be growing pressure on
all countries to reduce the amounts of coal and oil
they use. There also will be pressure (and incentives)
to adopt advanced technologies so that less damage is
inflicted in the future. Buying such technologies can
be costly.
Countries in the early stages of industrialization
-- countries struggling hard to give their citizens
better lives -- don't want these additional burdens.
Economic development is difficult enough already. If
they agreed to cut back on burning the fossil fuels
that are the cheapest, most convenient, and most useful
for industry, how could they make any progress?
There are other injustices to the climate change problem.
The countries to suffer the most if the predicted consequences
come about -- if agricultural zones shift or sea levels
rise or rainfall patterns change -- will probably be
in the developing world. These nations simply do not
have the scientific or economic resources, or the social
safety nets, to cope with disruptions in climate. Also,
in many of these countries rapid population growth has
pushed many millions of people onto marginal land --
the sort of land that can change most drastically due
to variations in climate.
How the Convention responds
-- It puts the lion's share of the responsibility
for battling climate change -- and the lion's share
of the bill -- on the rich countries. The Convention
tries to make sure that any sacrifices made in protecting
our shared atmosphere will be shared fairly among countries
-- in accordance with their "common but differentiated
responsibilities and respective capabilities and their
social and economic conditions". It notes that
the largest share of historical and current emissions
originates in developed countries. Its first basic principle
is that these countries should take the lead in combating
climate change and its adverse impacts. Specific commitments
in the treaty relating to financial and technological
transfers apply only to very richest countries, essentially
the members of the Organization for Economic Cooperation
and Development (OECD). They agree to support climate
change activities in developing countries by providing
financial support above and beyond any financial assistance
they already provide to these countries.
Specific commitments concerning efforts to limit greenhouse
gas emissions and enhance natural sinks apply to the
OECD countries as well as to 12 "economies in transition"
(Central and Eastern Europe and the former Soviet Union).
Under the Convention, the OECD and transition countries
are expected to try to return by the year 2000 to the
greenhouse gas emission levels they had in 1990.
-- The Convention recognizes that poorer nations
have a right to economic development. It notes that
the share of global emissions of greenhouse gases originating
in developing countries will grow as these countries
expand their industries to improve social and economic
conditions for their citizens.
-- It acknowledges the vulnerability of poorer
countries to the effects of climate change. One
of the Convention's basic principles is that the specific
needs and circumstances of developing countries should
be given "full consideration" in any actions
taken. This applies in particular to those whose fragile
ecosystems are highly vulnerable to the impacts of climate
change. The Convention also recognizes that states which
depend on income from coal and oil would face difficulties
if energy demand changes.
Problem No. 4: If the whole world starts consuming
more and living the good life, can the planet stand
the strain?
As the human population continues to grow, the demands
human beings place on the environment increase. The
demands are becoming all the greater because these rapidly
increasing numbers of people also want to live better
lives. More and better food, more and cleaner water,
more electricity, refrigerators, automobiles, houses
and apartments, land on which to put houses and apartments
. . .
Already there are severe problems supplying enough
fresh water to the world's billions. Burgeoning populations
are draining the water from rivers and lakes, and vast
underground aquifers are steadily being depleted. What
will people do when these natural "tanks"
are empty? There are also problems growing and distributing
enough food -- widespread hunger in many parts of the
world attests to that. There are other danger signals.
The global fish harvest has declined sharply; as large
as the oceans are, the most valuable species have been
effectively fished out.
Global warming is a particularly ominous example of
humanity's insatiable appetite for natural resources.
During the last century we have dug up and burned massive
stores of coal, oil, and natural gas that took millions
of years to accumulate. Our ability to burn up fossil
fuels at a rate that is much, much faster than the rate
at which they were created has upset the natural balance
of the carbon cycle. The threat of climate change arises
because one of the only ways the atmosphere -- also
a natural resource -- can respond to the vast quantities
of carbon being liberated from beneath the earth's surface
is to warm up.
Meanwhile, human expectations are not tapering off.
They are increasing. The countries of the industrialized
"North" have 20 per cent of the world's people
but use about 80 per cent of the world's resources.
By global standards, they live extremely well. It's
nice living the good life, but if everyone consumed
as much as the North Americans and Western Europeans
consume -- and billions of people aspire to do just
that -- there probably would not be enough clean water
and other vital natural resources to go around. How
will we meet these growing expectations when the world
is already under so much stress?
How the Convention responds
-- It supports the concept of "sustainable
development." Somehow, mankind must learn how
to alleviate poverty for huge and growing numbers of
people without destroying the natural environment on
which all human life depends. Somehow a way has to be
found to develop economically in a fashion that is sustainable
over a long period of time. The buzzword for this challenge
among environmentalists and international bureaucrats
is "sustainable development". The trick will
be to find methods for living well while using critical
natural resources at a rate no faster than that at which
they are replaced. Unfortunately, the international
community is a lot farther along in defining the problems
posed by sustainable development than it is in figuring
out how to solve them.
-- The Convention calls for developing and sharing
environmentally sound technologies and know-how.
Technology will clearly play a major role in dealing
with climate change. If we can find practical ways to
use cleaner sources of energy, such as solar power,
we can reduce the consumption of coal and oil. Technology
can make industrial processes more efficient, water
purification more viable, and agriculture more productive
for the same amount of resources invested. Such technology
must be made widely available -- it must somehow be
shared by richer and more scientifically advanced countries
with poorer countries that have great need of it.
-- The Convention emphasizes the need to educate
people about climate change. Today's children and
future generations must learn to look at the world in
a different way than it was looked at by most people
during the 20th century. This is both an old and a new
idea. Many (but not all!) pre-industrial cultures lived
in balance with nature. Now scientific research is telling
us to do much the same thing. Economic development is
no longer a case of "bigger is better" --
bigger cars, bigger houses, bigger harvests of fish,
bigger doses of oil and coal. We must no longer think
of human progress as a matter of imposing ourselves
on the natural environment. The world -- the climate
and all living things -- is a closed system; what we
do has consequences that eventually come back to affect
us. Tomorrow's children -- and today's adults, for that
matter -- will have to learn to think about the effects
of their actions on the climate. When they make decisions
as members of governments and businesses, and as they
go about their private lives, they will have to take
the climate into account.
In other words, human behaviour will have to change
-- probably the sooner the better. But such things are
difficult to prescribe and predict. People will need
stronger signals and incentives if they are to do more
for the good of the global climate. That leads to...
Second act: the Protocol
The 1992 Convention was a good start. But as the years
passed, and the scientific evidence continued to accumulate,
people naturally asked, "what's next"?
In 1997, governments responded to growing public pressure
by adopting the Kyoto Protocol. A protocol is an international
agreement that stands on its own but is linked to an
existing treaty. This means that the climate protocol
shares the concerns and principles set out in the climate
convention. It then builds on these by adding new commitments
-- which are stronger and far more complex and detailed
than those in the Convention.
This complexity is a reflection of the enormous challenges
posed by the control of greenhouse gas emissions. It
is also a result of the diverse political and economic
interests that had to be balanced in order to reach
an agreement. Billion-dollar industries will be reshaped;
some will profit from the transition to a climate-friendly
economy, others will not.
Because the Kyoto Protocol will affect virtually all
major sectors of the economy, it is considered to be
the most far-reaching agreement on environment and sustainable
development ever adopted. This is a sign that the international
community is willing to face reality and start taking
concrete actions to minimize the risk of climate change.
The Protocol's negotiators were able to take this important
step forward only after facing up to some tough questions.
Problem No 5: Emissions are still growing. Isn't
it time to take some serious action?
Three years after the Climate Change Convention was
adopted at the Rio Earth Summit, the Intergovernmental
Panel on Climate Change (IPCC) published its second
major assessment of climate change research. Written
and reviewed by some 2,000 scientists and experts, the
report was soon famous for concluding that the climate
may have already started responding to past emissions.
It also confirmed the availability of many cost-effective
strategies for reducing greenhouse gas emissions.
Meanwhile, although emissions in some countries stabilized,
emissions levels continued to rise around the world.
More and more people came to accept that only a firm
and binding commitment by developed countries to reduce
greenhouse gases could send a signal strong enough to
convince businesses, communities, and individuals to
change their ways.
Finally, there was the practical matter that the year
2000 was fast approaching, and with it the Convention's
non-binding "aim" for industrialized countries
-- to return emissions to 1990 levels by the year 2000
-- would expire. Clearly, new steps were needed.
How the Protocol responds
-- It sets legally binding targets and timetables
for cutting developed country emissions. The Convention
encouraged these countries to stabilize emissions; the
Protocol will commit them to reducing their collective
emissions by at least 5%. Each country's emissions levels
will be calculated as an average of the years 2008-2012;
these five years are known as the first commitment period.
Governments must make "demonstrable progress"
towards this goal by the year 2005.
These arrangements will be periodically reviewed.
The first review is likely to take place in the middle
of the first decade of the new century. At this time
the Parties will take "appropriate action"
on the basis of the best available scientific, technical,
and socio-economic information. Talks on targets for
the second commitment period must start by 2005.
The Protocol will only become legally binding when
at least 55 countries, including developed countries
accounting for at least 55% of developed countries'
1990 CO2 emissions, have ratified it. This
should happen some time after the year 2000.
-- The Protocol addresses the six main greenhouse
gases. These gases are to be combined in a "basket",
so that reductions in each gas are credited towards
a single target number. This is complicated by the fact
that, for example, a kilo of methane has a stronger
effect on the climate than does a kilo of carbon dioxide.
Cuts in individual gases are therefore translated into
"CO2 equivalents" that can be added
up to produce one figure.
Cuts in the three major gases - carbon dioxide, methane,
and nitrous oxide -- will be measured against a base
year of 1990 (with exceptions for some countries with
economies in transition). Cuts in the three long-lived
industrial gases - hydrofluorocarbons (HFCs), perfluorocarbons
(PFCs), and sulphur hexafluoride (SF6) -
can be measured against either a 1990 or 1995 baseline.
Carbon dioxide is by far the most important gas in
the basket. It accounted for over four fifths of total
greenhouse gas emissions from developed countries in
1995, with fuel combustion representing all but several
percent of this amount. Fortunately, CO2
emissions from fuel are relatively easy to measure and
monitor.
Deforestation is the second largest source of carbon
dioxide emissions in developed countries. Under the
Protocol, targets can be met in part by improving the
ability of forests and other natural sinks to absorb
carbon dioxide from the atmosphere. Calculating the
amount absorbed, however, is methodologically complex.
Governments must still agree on a common approach.
The second most important gas covered by the Protocol
is methane. Methane is released by rice cultivation,
domesticated animals such as cattle, and the disposal
and treatment of garbage and human wastes. Methane emissions
are generally stable or declining in the developed countries
and their control does not seem to pose as great a challenge
as carbon dioxide.
Nitrous oxide is emitted mostly as a result of fertilizer
use. As with methane, emissions from developed countries
are stable or declining. Nitrous oxide and methane emissions
are also similar in being relatively difficult to measure.
One major group of greenhouse gases that the Protocol
does not cover is chlorofluorocarbons. This is
because CFCs are being phased out under the 1987 Montreal
Protocol on Substances that Deplete the Ozone Layer.
Thanks to this agreement, atmospheric concentrations
of many CFCs are stabilizing and expected to decline
over the coming decades.
However, the Protocol does address three long-lived
and potent greenhouse gases that, like CFCs, have been
created by industry for specialized applications. The
use of HFCs and PFCs threatens to go up dramatically
in part because they are being adopted as ozone-safe
replacements for CFCs. Governments are now working to
make sure that the incentives and controls for ozone
depletion and global warming are compatible.
The third man-made gas, sulphur hexafluoride, is used
as an electric insulator, heat conductor, and freezing
agent. Molecule for molecule, its global warming potential
is thought to be 23,900 times greater than that of carbon
dioxide.
-- The Protocol recognizes that emissions cuts
must be credible and verifiable. Ensuring that governments
comply with their targets will be essential to the Protocol's
success. Each country will need an effective national
system for estimating emissions and confirming reductions.
Standardized guidelines must be crafted to make figures
comparable from one country to the next and the whole
process transparent.
The Protocol allows governments that cut emissions
more than they are required to by their national target
to "bank" the "excess" as credits
for future commitment periods. But what happens if a
country's emissions are higher than what is permitted
by its target? Non-compliance provisions still need
to be developed. Clearly, though, the best approach
both politically and environmentally will be to start
by helping governments to comply rather than emphasizing
punitive or confrontational measures.
Problem No 6: How can we make our behavior and
our economies more climate-friendly?
Minimizing greenhouse gas emissions will require policymakers
to take some tough decisions. Every time a subsidy is
added or removed, and every time a regulation or reform
is put in place, somebody says "ouch". Even
though the economy as a whole stands to benefit from
well-designed, market-oriented policies for reducing
emissions, action -- or inaction -- by government always
helps create winners and losers in the marketplace.
The challenge for policymakers is to design policies
that fully engage the energies of civil society. Their
goal must be to open the floodgates of industrial creativity.
Experience shows that companies often respond rapidly
and positively to incentives and pressures. Given the
right policy environment, the business sector will roll
out low-emissions technologies and services faster than
many now believe possible.
Schools, community groups, the media, families, and
consumers also have a crucial role to play. Individuals
can make a real difference by changing their habits
and making thoughtful purchases and investments. If
consumers are convinced that the rules of the game are
changing, they will start taking the myriad small decisions
that, when added together, can have a dramatic impact
on emissions.
If large segments of society are willing to make these
changes, we can expect an early transition to more energy-efficient,
technologically innovative, and environmentally sustainable
societies. The trick is getting started.
How the Protocol responds
-- It highlights effective domestic policies and
measures for reducing emissions. National governments
can build a fiscal and policy framework that discourages
emissions. They can phase out counter-productive subsidies
on carbon-intensive activities, and they can introduce
energy-efficiency and other regulatory standards that
promote the best current and future technologies. Taxes,
tradable emissions permits, information programmes,
and voluntary programmes can all contribute.
Local and urban governments -- which often have direct
responsibility for transport, housing, and other greenhouse
gas-emitting sectors of the economy -- can also play
a role. They can start designing and building better
public transport systems and creating incentives for
people to use them rather than private automobiles.
They can tighten construction codes so that new houses
and office buildings will be heated or cooled with less
fuel.
Meanwhile, industrial companies need to start shifting
to new technologies that use fossil fuels and raw materials
more efficiently. Wherever possible they should switch
to renewable energy sources such as wind and solar power.
They should also redesign products such as refrigerators,
automobiles, cement mixes, and fertilizers so that they
produce lower greenhouse gas emissions. Farmers should
look to technologies and methods that reduce the methane
emitted by livestock and rice fields. Individual citizens,
too, must cut their use of fossil fuels -- take public
transport more often, switch off the lights in empty
rooms -- and be less wasteful of all natural resources.
The Protocol also flags the importance of conducting
research into innovative technologies, limiting methane
emissions from waste management and energy systems,
and protecting forests and other carbon sinks.
-- The Protocol encourages governments to work
together. Policymakers can learn from one
other and share ideas and experiences. They may choose
to go further, coordinating national policies in order
to have more impact in a globalized marketplace. Governments
should also consider the effects of their climate policies
on others, notably developing countries, and seek to
minimize any negative economic consequences.
Problem No 7: How should we divide up the work
-- while sharing the burden fairly?
The Climate Change Convention calls on the rich countries
to take the initiative in controlling emissions. In
line with this, the Kyoto Protocol sets emission targets
for the industrialized countries only -- although it
also recognizes that developing countries have a role
to play.
Agreeing how to share the responsibility for cutting
emissions amongst the 40 or so developed countries was
a major challenge. Lumping all developed countries into
one big group risks ignoring the many differences between
them. Each country is unique, with its own mix of energy
resources and price levels, population density, regulatory
traditions, and political culture.
For example, the countries of Western Europe tend
to have lower per capita emissions than do countries
such as Australia, Canada, and the US. Western Europe's
emissions levels have generally stabilized since 1990
-- the base year for measuring emissions -- while other
developed countries have seen their emissions rise.
Japan made great strides in energy efficiency in the
1980s, while countries such as Norway and New Zealand
have relatively low emissions because they rely on hydropower
or nuclear energy. Meanwhile, the energy-intensive countries
of Central and Eastern Europe and the former Soviet
Union have seen emissions fall dramatically since 1990
due to their transition to market economies. These differing
national profiles make it difficult to agree on a one-size-fits-all
solution.
How the Protocol responds
-- It assigns a national target to each country.
In the end, it was not possible to agree in Kyoto on
a uniform target for all countries. The resulting individual
targets were not based on any rigorous or objective
formula. Rather, they were the outcome of political
negotiation and compromise.
The overall 5% target for developed countries is to
be met through cuts of 8% in the European Union (EU),
Switzerland, and most Central and East European states;
7% in the US; and 6% in Canada, Hungary, Japan, and
Poland. New Zealand, Russia, and Ukraine are to stabilize
their emissions, while Norway may increase emissions
by up to 1%, Australia by up to 8%, and Iceland 10%.
The EU has made its own internal agreement to meet
its 8% target by distributing different rates to its
member states, just as the entire developed group's
5% target was shared out. These targets range from a
28% reduction by Luxembourg and 21% cuts by Denmark
and Germany to a 25% increase by Greece and +27% for
Portugal.
-- The Protocol offers additional flexibility to
the countries with economies in transition. In particular,
they have more leeway in choosing the base year against
which emissions reductions are to be measured. They
also do not share the commitment of the richer developed
countries to provide "new and additional financial
resources" and facilitate technology transfer for
developing country Parties.
-- It also reconfirms the broader commitments of
all countries -- developed and developing. Under
the Convention, both developed and developing countries
agree to take measures to address emissions and adapt
to future climate change impacts; submit information
on their national climate change programmes and emissions
levels; facilitate technology transfer; cooperate on
scientific and technical research; and promote public
awareness, education, and training. These commitments
are reaffirmed in the Protocol, which also sets out
ways of advancing their implementation.
The issue of emissions targets for developing countries,
and the broader question of how commitments should evolve
in the future given continuing growth in global emissions,
has generated a great deal of intense debate. A proposal
that the Protocol should establish a procedure whereby
developing countries could take on voluntary commitments
to limit (that is, reduce the rate of increase in) their
emissions was not accepted in Kyoto. Many developing
countries resist formal commitments, even if voluntary,
that would put an upper limit on their emissions, noting
that their per capita emissions are still low compared
to those of developed countries. Once developed countries
start to convincingly demonstrate that they are taking
effective actions to achieve their emissions targets,
the debate on how new countries might eventually be
brought into the structure of specific commitments may
be revived.
This is in keeping with the step-by-step approach
of the intergovernmental climate regime. The Kyoto Protocol
is not an end result, and can be strengthened and built
on in the future. What's more, although developing countries
are not currently subject to any specific timetables
and targets, they are expected to take measures
to limit the growth rate of their emissions and to report
on actions they are taking to address climate change.
There is a good deal of evidence that many developing
countries are indeed taking steps that should help their
emissions grow at a slower rate than their economic
output. This is particularly true in the field of energy.
Problem No. 8: I don't want to spend more money
on this than is absolutely necessary!
People are keen to combat climate change because they
fear it may be destructive and costly. At the same time,
they naturally want to buy their "climate insurance"
at the lowest price possible.
Fortunately, the costs of climate change policies
can be minimized through "no regrets" strategies.
Such strategies make economic and environmental sense
whether or not the world is moving towards rapid climate
change. For example, boosting energy efficiency not
only reduces greenhouse gas emissions but lowers the
cost of energy, thus making industries and countries
more competitive in international markets; it also eases
the health and environmental costs of urban air pollution.
At the same time, the precautionary principle and the
expected net damages from climate change justify adopting
policies that do entail some costs.
Calculating the costs of climate change policies is
not easy. How quickly power plants and other infrastructure
are replaced by newer and cleaner equipment, how interest
rate trends affect corporate planning and investment,
and the way businesses and consumers respond to climate
change policies are just a few of the variables to consider.
Costs can also vary from place to place. In general,
the costs of improving energy efficiency should be lower
in countries that are the most energy inefficient. Countries
in the early stages of industrialization may offer cheaper
opportunities for installing modern environmentally
friendly technologies than do countries whose industrial
plant is already developed. And so on.
How the Protocol responds
-- The Protocol innovates by giving Parties credit
for reducing emissions in other countries. It establishes
three "mechanisms" for obtaining these credits.
The idea is that countries that find it particularly
expensive to reduce emissions at home can pay for cheaper
emissions cuts elsewhere. The global economic efficiency
of reducing emissions is increased while the overall
5% reduction target is still met. The Protocol stipulates,
however, that credit for making reductions elsewhere
must be supplementary to domestic emissions cuts.
Governments must still decide just how the three mechanisms
for doing this will function. The rules they adopt will
strongly influence the costs of meeting emissions targets.
They will also determine the environmental credibility
of the mechanisms -- that is, their ability to contribute
to the Protocol's aims rather than opening up "loopholes"
in emissions commitments.
-- An emissions trading regime will allow industrialized
countries to buy and sell emissions credits amongst
themselves. Countries that limit or reduce emissions
more than is required by their agreed target will be
able to sell the excess emissions credits to countries
that find it more difficult or more expensive to meet
their own targets. The rules, however, have not yet
been decided on.
Some observers are concerned that the Kyoto targets
of some countries are so low that they can be met them
with minimal effort. These countries could then sell
large quantities of emission credits (known as "hot
air"), reducing pressure on other industrialized
countries to make domestic cuts. Governments are debating
the best way to ensure that emissions trading does not
undermine incentives for countries to cut their own
domestic emissions.
-- Joint implementation (JI) projects will offer
"emissions reduction units" for financing
projects in other developed countries. A
joint implementation project could work like this: Country
A faces high costs for reducing domestic emissions,
so it invests in low-emissions technologies for a new
power plant in Country B (very likely an economy in
transition). Country A gets credit for reducing emissions
(at a lower cost that it could domestically), Country
B receives foreign investment and advanced technologies,
and global greenhouse gas emissions are reduced: a "win-win-win"
scenario.
Not only governments, but businesses and other private
organizations will be able to participate directly in
these projects. Some aspects of this approach have already
been tested under the Convention through a voluntary
programme for "Activities Implemented Jointly".
Reporting rules, a monitoring system, institutions,
and project guidelines must still be adopted. Not only
must this infrastructure establish the system's credibility,
but it must ensure that JI projects transfer appropriate
and current technology, avoid adverse social and environmental
impacts, and avoid distorting the local market.
-- A Clean Development Mechanism will provide credit
for financing emissions-reducing or emissions-avoiding
projects in developing countries. This promises
to be an important new avenue through which governments
and private corporations will transfer clean technologies
and promote sustainable development. Credit will be
earned in the form of "certified emissions reductions".
Whereas joint implementation and emissions trading
merely shift around the pieces of the industrial countries'
overall 5% target, the CDM involves emissions in developing
countries (which do not have targets). This in effect
increases the overall emissions cap. Verification is
therefore particularly important for this mechanism.
The Protocol already details some of the ground rules.
The CDM will be governed by the Parties through an Executive
Board, and reductions will be certified by one or more
independent organizations. To be certified, a deal must
be approved by all involved parties, demonstrate a measurable
and long-term ability to reduce emissions, and promise
reductions that would be additional to any that would
otherwise occur. A share of the proceeds from CDM projects
will be used to cover administrative expenses and to
help the most vulnerable developing countries meet the
costs of adapting to climate change impacts. Again,
the operational guidelines must still be worked out.
Conclusion: The 21st century and
beyond
Climate change would have lasting consequences. One
giant asteroid came along 65 million years ago, and
that was it for the dinosaurs.
In facing up to man-made climate change, human beings
are going to have to think in terms of decades and centuries.
The job is just beginning. Many of the effects of climate
shifts will not be apparent for two or three generations.
In the future, everyone may be hearing about -- and
living with -- this problem.
The Framework Convention takes this into account.
It establishes institutions to support efforts to carry
out long-term commitments and to monitor long-term efforts
to minimize -- and adjust to -- climate change. The
Conference of the Parties, in which all states that
have ratified the treaty are represented, is the Convention's
supreme body. It met for the first time in 1995 and
will continue to meet on a regular basis to promote
and review the implementation of the Convention. The
Conference of the Parties is assisted by two subsidiary
bodies (or committees), one for scientific and technological
advice and the other for implementation. It can establish
other bodies as well, whether temporary or permanent,
to help it with its work.
It can also strengthen the Convention, as it did in
Kyoto in 1997. The Protocol's five per cent cut may
seem a modest start, but given the rise in emissions
that would otherwise be expected -- and remember that
emissions in a number of developed countries have risen
steadily since the 1990 base year -- many countries
are going to have to make a significant effort to meet
their commitment.
The Kyoto Protocol makes an important promise: to
reduce greenhouse gases in developed countries by the
end of the first decade of the new century. It should
be judged a success if it arrests and reverses the 200-year
trend of rising emissions in the industrialized world
and hastens the transition to a climate-friendly global
economy.
Key greenhouse gases affected by human
activities
|
CO2
|
CH4
|
N2O
|
CFC-11
|
HCFC-22
|
CF4
|
SF6
|
|
Pre-industrial level
|
|
~280 ppmv
|
~700 ppbv
|
~275 ppbv
|
zero
|
zero
|
zero
|
zero
|
|
1994 concentration
|
|
358 ppmv
|
1720 ppbv
|
312§ppbv
|
268§pptv
|
110 pptv
|
72§ pptv
|
3-4 pptv
|
|
Rate of increase*
|
|
1.5 ppmv/yr
|
0 ppbv/yr
|
1 0.8 ppbv/yr
|
0 pptv/yr
|
5 pptv/yr
|
1.2 pptv/yr
|
0.2pptv/yr
|
|
0.4%/yr
|
0.6%/yr
|
0.25%/yr
|
0%/yr
|
5%/yr
|
2%/yr
|
~5%/yr
|
|
Lifetime (years)
|
|
50-200¸
|
12¸¸
|
120
|
50
|
12
|
50,000
|
3,200
|
| |
Notes:
CO2 (carbon dioxide),
CH4 (methane),
N2O (nitrous oxide),
SF6 (sulphur hexafluoride), and
CF4 (a perfluorocarbon, or PFC) are covered
by the Kyoto Protocol.
CFC-11 and HCFC-22 (a CFC replacement) are also ozone-depleting
substances and thus addressed under the Montreal Protocol
rather than under the climate change agreements.
1 ppmv = 1 part per million by volume; 1 ppbv = 1 part
per billion by volume; 1 pptv = 1 part per trillion
(million million) by volume.
§ Estimated from 1992-93 data.
* The growth rates of CO2 , CH4
and N2O are averaged over the decade beginning
1984 ; halocarbon growth rates are based on recent years
(1990s).
¸ No single
lifetime for CO2 can be defined because of
the different rates of uptake by different sink processes.
¸¸ This
has been defined as an adjustment time which takes into
account the indirect effect of methane on its own lifetime.
This table adapted from "Climate Change 1995",
IPCC Working Group I, p. 15.
BOX: What is the greenhouse effect?
In the long term, the earth must shed energy into
space at the same rate at which it absorbs energy from
the sun. Solar energy arrives in the form of short-wavelength
radiation. Some of this radiation is reflected away
by the earth's surface and atmosphere. Most of it, however,
passes straight through the atmosphere to warm the earth's
surface. The earth gets rid of this energy (sends it
back out into space) in the form of long- wavelength,
infra-red radiation.
Most of the infra-red radiation emitted upwards by
the earth's surface is absorbed in the atmosphere by
water vapour, carbon dioxide, and the other naturally
occurring "greenhouse gases". These gases
prevent energy from passing directly from the surface
out into space. Instead, many interacting processes
(including radiation, air currents, evaporation, cloud-formation,
and rainfall) transport the energy high into the atmosphere.
From there it can radiate into space. This slower, more
indirect process is fortunate for us, because if the
surface of the earth could radiate energy into space
unhindered, the earth would be a cold, lifeless place
-- a bleak and barren planet rather like Mars.
By increasing the atmosphere's ability to absorb infra-red
energy, our greenhouse gas emissions are disturbing
the way the climate maintains this balance between incoming
and outgoing energy. A doubling of the concentration
of long-lived greenhouse gases (which is projected to
occur early in the next century) would, if nothing else
changed, reduce the rate at which the planet can shed
energy into space by about 2 per cent. Energy cannot
simply accumulate. The climate somehow will have to
adjust to get rid of the extra energy -- and while 2
per cent may not sound like much, over the entire earth
that amounts to trapping the energy content of some
3 million tons of oil every minute.
Scientists point out that we are altering the energy
"engine" that drives the climate system. Something
has to change to absorb the shock.
________
INSIDE FRONT COVER
Published by the United Nations Environment Programme
(UNEP) and the Climate Change Secretariat (UNFCCC) with
the generous support of the Swiss Agency for the Environment,
Forests, and Landscape. Revised in September 1999. This
booklet is intended for public information purposes
only and is not an official document. Permission is
granted to reproduce or translate the contents giving
appropriate credit. For more information, contact UNEP's
Information Unit for Conventions (UNEP/IUC), International
Environment House (Geneva), Box 356, 1219 Châtelaine,
Switzerland, or iuc@unep.ch.
BACK COVER
For more information, please contact:
United Nations Environment Programme
Information Unit for Conventions
International Environment House, Geneva
C.P. 356, 1219 Châtelaine, Switzerland
Tel. +41-22-917-8244/8196
Fax +41-22-797-3464
E-mail: iuc@unep.ch
Web: www.unep.ch/iuc/
Climate Change Secretariat
Haus Carstenjan
PO Box 260124
D-53153 Bonn, Germany
E-mail: secretariat@unfccc.de
Web: www.unfccc.de
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