Research Journal of Recent Sciences ________________________________________________ ISSN 2277 - 2502
Vol. 1(ISC-2011), 388-397 (2012)
Res.J.Recent.Sci.

Review Paper

Carbon Credits – A Step to Sustainable Future of the World
Ravuru Narasimha Reddy and Y. V. N. S. Suvikram
Chemical Engineering Department, Institute of Technology, Nirma University, Ahmedabad, Gujarat, INDIA

Available online at: www.isca.in
(Received 16th September 2011, revised 11th January 2012, accepted 25th January 2012)

Abstract
Clean Development Mechanism (CDM), a flexibility mechanism of Kyoto Protocol, discusses trading and transferring of
emission allowances between developing and developed nations. The shift to renewable energy options and low carbon
technologies, in response to the concerns over energy security and climate change, is proceeding more slowly than many
would like. CDM, a project-based system, aims to accomplish the overarching goals of the Protocol. It aims to encourage
sustainable development in developing nations and intends to reduce the cost of compliance with the Protocol for developed
nations. CDM Projects are designed for reducing greenhouse gases and increasing green cover on earth. It involves projects
like energy efficiency, transport, methane recovery, industrial process changes, cogeneration, agricultural sector etc. CDM
also known as “Carbon Trading” or “Carbon Credits” is the way of reducing carbon emissions and gain ‘Certified
Emission Reductions’ (CERs) for a developing country in return to the technology, funds etc. provided by a developed
country. In this process World Bank (WB) acts as a referee and provides carbon credits to developed countries. Recently
held Carbon Bazaar’10 in New Delhi, India witnessed the presence of huge number of big industrialists and various
government firms across the globe. This shows the concern of the world towards carbon credits. A “Zero Carbon Footprint”
initiative carried out successfully at our college has been included in the paper. It includes the calculations of emissions by
the raw materials used in the manufacture of the paper we use, computer we work on, the packaging of our groceries or the
disposables such as cups, cartons and plastic bags from its production till its disposal, be it in their manufacturing process
which consumes fossil fuel generated electricity or the transportation process which causes more emissions by way of vehicle
exhaust. An equivalent number of plants were planted in the university premises which amounted to the net carbon emitted
during the entire event. Some of the registered projects in India, included in this paper, show the initiation of our nation
towards carbon credits. The emergence of a global carbon credit economy is likely to precede a global regulatory system
governing climate change and will doubtlessly help to stimulate the emergence of such a global system.
Keywords: CDM, Kyoto protocol, project based system, carbon credits, carbon bazaar, zero carbon footprints.

Introduction
What is the clean development mechanism (CDM):
Climate change convention is a United Nations agreement to
stabilize greenhouse gases in the atmosphere, at a level that
would prevent dangerous changes to the climate. The
convention on climate change was agreed at the United
Nations Conference on Environment and Development
(UNCED) in Rio, 1992. To date, 186 countries have ratified
the convention. To put the convention into operation, a
protocol was outlined in Kyoto in 1997. The most important
aspect of the Kyoto Protocol is its legally binding
commitments for 39 developed countries to reduce their
greenhouse gas (GHG) emissions by an average of 5.2%
relative to 1990 levels. These emission reductions must be
achieved by 2008–2012: the so called ‘first commitment
period’.
The developed countries with emission reduction targets are
called the annex 1 countries, whereas those without targets

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are the non-annex 1 countries. The Kyoto protocol allows
developed countries to reach their targets in different ways
through ‘Flexibility Mechanisms’.
These include: Bubble Mechanism: It refers to the European
Union member countries that agreed to have a collective
Quantified Emissions Limitations and Reduction Objectives
(QELROs) of 8%, regardless of the actual individual
countries’ reductions. Emissions Trading: Trading of
emission allowances between developed nations. Joint
Implementation: Transferring emission allowances between
developed nations, linked to specific emission-reduction
projects. Clean Development Mechanism (CDM): The CDM
is the only flexibility mechanism that involves developing
countries. It allows developed nations to achieve part of their
reduction obligations through projects in developing
countries that reduce emissions or ‘fix’ or sequester CO2
from the atmosphere. It provides guidance to people in

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developing countries who are responsible for establishing
enabling policies and regulations in this area, as well as
project developers.
Structure of the CDM: The clean development mechanism
is a project-based system. This means that it accomplishes its
objectives at the relatively fine-grained scale of individual
projects that are validated by designated entities and
registered with the CDM executive board (CDM EB), the
mechanism’s governing body, rather than at an industry or
sector-wide scale. Each project wishing to participate in the
CDM must prepare a Project Design Document (PDD) that
explains in detail how its future emissions reductions will be
real, additional, and not induce leakage. It must also prepare
a monitoring methodology that explains in detail how it will
monitor emissions reductions made by the project. A project
may also utilize a previously approved monitoring
methodology. Real emissions reductions are ones that are
monitored with sufficient care to insure that they actually
occur. Additional emissions reductions are ones that are in
addition to any that would have occurred absent the CDM
subsidy. Leakage of emissions occurs when emissions
reductions that would have occurred within a project absent
the CDM subsidy, instead occur outside it because of the
subsidy.
All three of these concepts require that a hypothetical
baseline of emissions be defined for each project, and in the
case of leakage, the world outside the project. This baseline
represents the timeline of emissions that would have
occurred absent the subsidy provided by the CDM (and thus
absent the emission reduction project). It is an attempt to
represent the counterfactual of business as usual emissions in
a world without CDM. The CDM project baseline is
described in terms that vary by the project type.
Nevertheless, several common variables can be seen in most
PDDs.
Project proponents often describe the regulatory baseline,
that is, the flux of emissions permitted by local law and
regulation. They often describe the financial baseline, that is,
the lack of an adequate return on investment without the
benefit of the CDM subsidy. They often describe typical
technologies applied by the type of project in the PDD and
how the CDM subsidized project exceeds these local
standards. Finally, they sometimes must describe a sectorial
or national baseline for installations of the project type.
Ultimately, the CDM project proponents must quantify the
hypothetical emissions that would have occurred in the future
without the CDM project subsidy. Of course, project
proponents and environmental regulators do not live in a
world without CDM.
They have, given the potential for foreign subsidies, acted
strategically in order to maximize many projects’ baselines

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and so maximize the potential for the generation of certified
emission reductions (CERs). The fact that most industries
involved in CDM projects are already highly regulated
makes this strategy attractive and not difficult to implement.
An environmental regulator faced with the choice of
preventing an emission with a domestically costly regulation
or allowing it to be prevented by domestic polluters being
paid a subsidy from an extra-national entity will have
obvious political incentives for selecting the international
subsidy over new regulation.
The end product of the CDM process is the issuance by the
CDM EB of an emissions offset to the project participants.
This offset can then be sold to an annex 1 nation or a party
within one that has obligations under the Kyoto Protocol.
The offset, called a Certified Emission Reduction (CER),
assuming that certain CDM facilities are established, may be
used be annex 1 countries in lieu of emissions reductions
within their territories for meeting emissions reductions
targets. Private parties that have been assigned emissions
allowances by their governments may also purchase CERs
and use them as permits to emit in excess of their assigned
allocations or as an alternative to purchasing allocations from
other participants in their domestic market.
Goals of the CDM: The clean development mechanism was
created with three goals: It aims to accomplish the
overarching goals of the framework convention. It aims to
encourage sustainable development in non-annex 1 nations.
The CDM is intended to reduce the cost of compliance with
the protocol for annex-1 nations.
The clean development mechanism is intended, according to
the protocol, to help in accomplishing the goal of the
convention of preventing dangerous interference with the
climate system. It aims to do this by assisting developing
countries in reducing their emissions of GHGs. Thus the
CDM is a significant and indeed the only way in which Nonannex 1 signatories to the Kyoto protocol will contribute
towards achieving its goals. A not unrealistic hopes for the
CDM was that by providing non-annex 1 nations with
financial incentives for low-carbon intensity development,
these nations’ development paths might be nudged onto more
climate friendly paths and engaged for the long haul.
The second CDM objective, sustainable development, is left
largely undefined by the protocol or the implementing
directives of later conferences of the parties. To the extent
that the provision has teeth, it is given them by the
requirement under the CDM that the host country of a project
must certify that it meets the Designated National Authority
(DNA)’s standards of sustainability. Although some DNA’s
have prioritized particular types of projects, they have not
rejected other types that would otherwise be capable of
producing CERs.

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The third CDM goal, lowering the cost of compliance for
annex 1 parties, was thought possible for two reasons. The
majority of additional energy capacity to be built up to and
during the first compliance period (2008-2012) would be
located in the developing world where rates of economic
growth were highest and energy infrastructure was least
developed.60 Also, the relative cost of prematurely retiring
high-carbon emission intensity power plants is significantly
higher than building new low- or zero carbon emission
energy capacity. Thus if the CDM could be used to subsidize
the substitution of new clean power capacity in the
developing world for premature retirement of old dirty power
capacity in the developed world, it could substantially lower
the cost of treaty compliance with no change in
environmental outcome since the location at which an
emission reduction of a particular quantity of CO 2 takes
place has no impact on the environmental benefit – lower
atmospheric greenhouse gas concentrations.

Cogeneration: Use of waste heat from electric generation,
such as exhaust from gas turbines, for industrial purposes or
heating (e.g. Distillery-Molasses/ bagasse)
Agricultural sector: Energy efficiency improvements or
switching to less carbon intensive energy sources for water
pumps (irrigation); Methane reductions in rice cultivation;
Reducing animal waste or using produced animal waste for
energy generation and any other changes in an agricultural
practices resulting in reduction of any category of
greenhouse gas emissions.

Carbon Credits

CDM project types: Carbon credits or CERs are sold to
entities in Annex-I countries, like power utilities, who have
emission reduction targets to achieve. Type of projects,
which are being applied for CDM and which can be of
valuable potential, are:
Energy efficiency projects: Increasing building efficiency
(Concept of Green Building/LEED Rating) e.g. Technopolis
Building, Kolkata; Increasing commercial/industrial energy
efficiency (Renovation and Modernization of old power
plants); Fuel switching from more carbon intensive fuels to
less carbon intensive fuels; and also includes re-powering,
upgrading instrumentation, controls, and/or equipment.
Transport: Improvements in vehicle fuel efficiency by the
introduction of new technologies; Changes in vehicles and/or
fuel type, for example, switch to electric cars or fuel cell
vehicles (CNG/Bio fuels); Switch of transport mode, e.g.
changing to less carbon intensive means of transport like
trains (Metro in Delhi); and; Reducing the frequency of the
transport activity.
Methane recovery: Animal waste methane recovery and
utilization; Installing an anaerobic digester and utilizing
methane to produce energy; Coal mine methane recovery;
Collection and utilization of fugitive methane from coal
mining; Capture of biogas; Landfill methane recovery and
utilization; Capture and utilization of fugitive gas from gas
pipelines; Methane collection and utilization from
sewage/industrial waste treatment facilities.
Industrial process changes: Any industrial process change
resulting in the reduction of any category greenhouse gas
emissions.

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Figure-1
Mechanism Carbon Trading
Let us say that India decided to invest in a new power
station, and has decided on a particular technology at the cost
of X crore. An entity from an industrialized country (which
could even be a company) offers to provide India with
slightly better technology, which costs more (say Y crore),
but will result in lower emissions. The industrialized country
will only pay the incremental cost of the project – viz. Y
minus X. In return, the “investing” country will get certified
emission reductions‟ (CERs), or credits, which it can use to
meet its Kyoto commitments.
This is a very good deal indeed – but for the investing
country. Not only do they sell developing countries their
technology, but they also meet their Kyoto commitments
without lifting a finger to reduce their domestic emissions.
Countries like the US can continue to pollute at home, so
long as it makes the reductions elsewhere.
The World Bank has built itself a role in this market as a
referee, broker and macro-manager of international fund
flows. The scheme has been entitled clean development
mechanism, or more commonly, carbon trading.
The carbon market creates transferable rights to dump carbon
in the environment and vegetation far in excess of the
capacity of these systems to hold it. Billions of dollars worth
of these rights are to be awarded free of charge to the biggest

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corporate emitters of greenhouse gases in the electric power,
iron and steel, cement, paper and other sectors in
industrialized nations who have caused the climate crisis and
already exploited these systems most.
India is considered as the largest beneficiary, claiming about
31 per cent of the total world carbon trade through the clean
development mechanism (CDM). It is expected to rake in at
least $5 billion to $10 billion (Rs 22,500 crore to Rs 45,000
crore) over a period of time.
Carbon Bazaar 2010: Growing importance of combating
climate change, May 10-11, 2010, New Delhi, carbon trading
is picking up fast due to growing importance of combating
climate change. The programme was one of a kind, providing
a platform for major stakeholders in the carbon markets to
discuss the way forward of this burgeoning market. Shri
J.M.Mauskar, Additional Secretary, Ministry of Environment
and Forests (MoEF), Govt. of India; Mr. Thomas Matussek,
German Ambassador to India; Mr. Franzjosef. Schafhausen,
Deputy Director General ‘Environment and Energy’ – BMU
and Mr. Stefan Helming, Country Director, GTZ, India
inaugurated the conference.
While the conference brainstormed on the new and pertinent
issues like: Nationally appropriate Mitigation Actions: The
German and India Perspective; Programme of Activities:
Challenges and Opportunities; Experiences and Nightmares
in Carbon Transaction; Small and Medium Enterprises:
Potential Untapped; Existing and Emerging Sectors

Expressing interest in India as a partner for CDM projects
German Ambassador Thomas Matussek, inaugurating a twoday event 'Carbon Bazaar 2010', said: “India has a huge
potential for CDM projects. Along with China, India has
been a leading destination for CDM projects globally since
the inception of the mechanism. India is also one of the
leading countries with the highest number of registered
protects until February 2010”.
Stressing the pro-active role of the Indian government in
facilitating international conventions, Deputy General of the
German Ministry of Environment Franzjosef Schafhausen
said: “The Ministry of Environment and Forest, Government
of India, and the German Federal Ministry for the
Environment have launched the CDM initiative in India to
boost the market mechanisms and CER (Certified Emission
Reduction) trading in India and also provide a meeting
ground for the disparate market players”.
The focus of this initiative is to facilitate the participation of
the Indian CDM projects in the European Union's Emission
Trading Scheme, thereby also becoming a part of the Global
Carbon Market," he added. Additional Secretary of the
environment and forests ministry Jairam Mauskar said:
“India's CDM potential represents a significant component of
the global CDM market”.
“As on May 7 2010, 505 out of a total of 2,194 projects
registered with the CDM executive board are from India. If
all these projects get registered, they have a potential to
generate 639 million CERs by the year 2012."

Future of Carbon Market: Post Kyoto 121 B2B (business
to business) meetings took place for direct business
negotiations between buyers/ investors/ technology
transferors from European nations mainly from Germany and
the CDM project proponents from India. High level one to
one meetings provided an insight to climate change issues
and policies in Indian context and India’s stand on these
issues beyond 2012. Future areas of cooperation and core
climate change issues pertaining to energy and environment
in India were also discussed.

Figure-3
CFL Lighting Scheme - Bachat Lamp Yojana (BLY)

Figure-2
India A Leading Player in Carbon Bazaar

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CDM’s Best Example in India: CFL-for-bulbs to be
world’s biggest carbon credit project will shut out 40M
tonnes of carbon from atmosphere annually. The project,
which will allow the government, investors, discoms and
CFL manufacturers to sell CFLs at Rs 15 each, instead of the

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Rs 100 they currently cost on average, has been approved by
the UN.
India had bagged the world’s largest carbon credit project
that will help replace 400 million incandescent light bulbs
with energy saving CFL bulbs at dirt-cheap prices in a year
while preventing 40 million tonnes of carbon from entering
the atmosphere annually. The project, which will allow the
government, investors, discoms and CFL manufacturers to
sell CFLs at Rs 15 each, instead of the Rs 100 they currently
cost on average, has been approved by the UN under the
global carbon credit scheme called clean development
mechanism.
The mammoth size of the project can be gauged from the fact
that the world’s second largest CDM project earns only about
1.5 million credits a year in comparison.
Almost half the households in India will immediately benefit
from the scheme and as other areas get electrified; those
villages will get added on. There are roughly 400 million
light points at present in the country that we will provide the
subsidized CFL bulbs for, said Ajay Mathur, director general
of the Bureau of Energy Efficiency, which is the nodal
agency for the grand project.
The scheme-called Bachat Lamp Yojna-works like this. The
discom in a state decides to implement the scheme. It picks
up a financial investor, which lends the upfront finance to
buy the CFL bulbs at market price to replace the bulbs in the
discom’s area. The discom then distributes the bulb to its
consumers at Rs 15 apiece and collects the regular bulbs,
which it then destroys. For every ten bulbs that consumers
use for a year, a tonne of carbon is prevented from escaping
into the atmosphere as CFL bulbs use substantially less
power than incandescent ones. For every tonne of carbon
saved, the Bureau of energy efficiency, acting as the anchor,
gets a carbon certificate from the UN, which it then hands
over to the investor. The investor sells the carbon credit in
the international market where buyers —such as
manufacturers and power producers in Europe — buy the
certificates to meet the greenhouse gas emission reduction
targets the countries have set for them. At present, each
certificate sells at around 10-12 Euros in the international
spot market. BEE estimates that investors will be able to
recover the rest of the Rs 85 per bulb by 5-6 years and by the
7th year, earn some on the top. BEE has in its scheme
ensured that the CFL bulbs are of a standard that they last
that long.
Several states and cities have been ready to take advantage of
the scheme the moment it becomes operational. Kerala is one
such state. It has already found investors and tied up with
manufacturers to distribute roughly 1.5 crore bulbs in the
state. In anticipation of the project clearance, it has begun
distribution of the energy saving bulbs to consumers.

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Figure-4
Failures of this CFL Lamp Yojna not being subsidized yet
are: Average income of an Indian is not enough that he can
buy a CFL lamp at Rs. 100 on average even during the trial
phase. Government did not ensure that trial phase took place
properly. On the contrary it focused on one class of people
for trial phase. Manufacturers were not ready to manufacture
CFL lamps at a MRP less than Rs.100.
Failures of CDM: The CDM is neither functioning well as a
market for emissions reductions nor is it a successful
subsidy. As a result, it is creating skewed but powerful
political institutions and interest groups whose interests are
not aligned with the ultimate goals of either the UNFCCC or
the Kyoto Protocol. Given the relatively poor performance, at
least initially, of other markets for atmospheric pollution, this
result is perhaps not entirely surprising nor should it be seen
as a reason to abandon the CDM.
The CDM fails as a market because it has animated
accounting tricks that allow participants to manufacture
CERs at little or no cost. It fails as a subsidy because the
developed world has had to purchase these emissions
reductions at an extremely high premium that bears no
relation to their cost. The CDM, even as it is supplying CERs
to developed world parties to the Kyoto Protocol at prices
that are less than they would otherwise have to pay, is an
excessive subsidy that represents a massive waste of
developed world resources. It is probably too late to change
the structure of the CDM in order to address its shortcomings
prior to the end of the first commitment period.

Issues and Concerns over CDM
The Steps to Sustainable Change in the World: Ensuring a
continued acceptance of CDM by developing countries
requires taking fully into account these countries’ concerns in
the climate negotiations — or any international negotiation
for that matter. There are at least five major philosophical
concerns that underlie all of developing countries negotiating
positions, and are the bases for their acceptance of any

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international agreement. The concerns are protected
sovereignty, trust, sustained and non-compromised
development, transfer of resources and technology, and
promotion of equity.
Sovereignty: Most of the developing countries are young
countries, many of which obtained their independence from
their Western colonizers in the 1950s. The legacy of
colonialism renders them to be particularly sensitive to
foreign influences. For them, sovereignty means not only in
territorial terms, but also in terms of development, politics,
and policy planning. Thus, the developing country
governments seek some degree of supervision of the CDM
process. The notion of “national sovereignty” has been
applied to environmental concerns since the 1972 World
Conference on Environment and Development in Stockholm,
and reaffirmed in the FCCC and Principle 2 of the Rio
Declaration.
Trust: Developing countries are reluctant to embark on a
deal if they feel that the real motives are strikingly different
from the stated ones, if the alleged real motives might hurt
them, and if they feel that they might be betrayed in the
future. The loss of trust that has occurred in the climate
negotiations means that support for CDM cannot be taken for
granted if it seems that others are benefiting more. In the
climate change negotiations, distrust was enhanced by the
US insistence for “meaningful participation from “key”
developing countries. This call for developing country
participation disregards the Climate Convention and the
Berlin Mandate, agreements that the US actively participated
in shaping. An overwhelming majority of developing
countries reject any limitation of their future emissions.
Exemption of developing countries from provisions to limit
emissions is already included in the Convention, and was
reaffirmed by the Berlin Mandate. This call broke developing
countries’ trust in the negotiating process. Even though CDM
is officially accepted, this distrust is still effectively there,
and could undermine the acceptance of CDM.
Sustained Development: Most developing countries are
struggling to get out of poverty, which they view as caused
partly by colonial exploitation. Alleviation of poverty and
ensuring the availability of basic needs to their population
are currently the main focus of their development process.
This process is in no way to be compromised by foreign
environmental interests. If CDM does not make its expected
contribution to sustainable development, support for it is
likely to erode.
Transfer of Resources: In pursuing development,
developing countries need as much resources and technology
as possible. Many developing countries expect substantial
transfer of resources through CDM as a realization of support
for sustainable development.

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Equity: In dealing with more advanced, industrialized, and
rich countries, developing countries are cautious. They tend
to ask questions such as: Who will benefit more from this
deal? Developing countries argue that if QELROs of annex 1
countries were assigned equitably (such as on a per capita
basis), then the overall QELROs would be much deeper than
the ones currently stipulated in the Protocol. More stringent
QELROs would lead to more demand for flexibility
mechanisms, including the use of CDM, to meet them. In
turn, more demand upon CDM would induce more flow of
resources from Annex I to developing countries.
For CDM to be fully accepted, there also needs to be an
equitable geographical distribution of projects. CDM is
understood to some extent as a vehicle for private
investment: there is concern that projects will go where
investors see the best opportunity for investment. Usually,
these are countries where there is already a significant
amount of Foreign Direct Investment (FDI). Africa, for
example, only receives 3 percent of the world’s FDI, and is
thus expected to receive the least interest from investors.
While CDM is accepted in principle, much still needs to be
done to ensure its workability as a mechanism to serve its
dual goals of emissions reduction and sustainable
development.
The following points summarize the issues that need
attention:
Credibility of CERs: The viability and credibility of CERs
is determined by the credibility of the baseline, the
calculation of additionality, and the soundness of the project
itself. A non credible process of certifying the emissions
reduction will threaten the CDM.
Determining a Baseline: The emissions reduction credited
to CDM projects should be measured from hypothetical
emissions that would have otherwise occurred without such
projects. Given the dynamic of the developing economies,
establishing a credible baseline is a great challenge.
Additionality: It is necessary to establish a fair and
reasonable objective method to judge whether the
investments in the projects would not have happened anyway
without CDM.
New and Additional Funds under CDM: While CDM is
claimed to be able to foster technology and resource transfer
from annex 1 to developing countries, there is a potential
conflict between the annex 1 and developing countries’
interests. Annex I countries have incentives to channel these
transfers as much as possible through CDM, as it will
provide CER. Developing countries want to ensure that
CDM provides transfers that are additional to normal foreign

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direct investment (for private sector) and traditional
development assistance (for public funds), and that their
development priorities don’t get short-changed.
Addressing Sustainable Development: Support for
sustainable development has been repetitively asserted by the
developing countries as the most important element of CDM.
Yet, how CDM should provide for sustainable development
needs to be clarified.
The Inclusion of Adaptation: The inclusion of an
adaptation levy in CDM will increase the price of CER
generated through CDM relative to ET and JI (One possible
way to collect the adaptation levy is to put a “tax” on the
price of CERs per ton). For this reason, developing countries
propose to harmonize the three mechanisms — ET, JI, and
CDM — so that each of them includes levy on the proceeds
to cover adaptation.
Banking of Emissions Reduction: CERs from CDM after
2000 can be used towards meeting annex 1 countries’
QELROs in the period between 2008 and 2012. This banking
option is designed to encourage early action and does not
exist in the other flexibility mechanisms.
The Inclusion of Forest Projects in CDM: Nowhere under
the Article on CDM is forestry mentioned as a way to
mitigate climate change. Already, however, a number of
developing countries are prepared to offer CERs through
forestry projects.
Involvement of Private Sector of Developing Countries:
Article on CDM allows for private entities to be directly
involved in CDM projects. Especially in developing
countries where the private sector is yet to be adequately
developed, the role of the private entities needs to be
supported.
The Role of Developing Country Governments: Given the
expectation that CDM will attract resource transfers between
the private sectors, the role of the government needs to be
defined. Developing country governments expect to play the
oversight role, and will need to build criteria for project
acceptance.
Bilateral or Multilateral Arrangement: It is not clear
whether CDM will be undertaken on a bilateral or
multilateral basis. Each of these options has its merits. While
a multilateral approach may avoid unequal negotiating
position between annex 1 and developing countries, a
bilateral approach may greatly simplify the mechanism and
in turn reduce transaction costs.

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The Need for Capacity Building: Developing countries
frequently express their concerns over their lack of capacity
in assessing, evaluating, implementing, and monitoring CDM
projects. They also express deep concerns on the limited
awareness of these countries’ major stakeholders on the
whole issue of climate change and its implications. They
assert that capacity building and information dissemination
should be an important aspect of the implementation of
CDM.

Some Registered CDM Projects
Rehabilitating Degraded Areas: Face Foundation in
Malaysia: The Innoprise - FACE Foundation Rainforest
Rehabilitation Project (INFAPRO) was the first large-scale
forestry-based carbon offset project in the world. Its
objective was to rehabilitate degraded areas by enrichment
planting and forest reclamation, using indigenous tree species
such as dipterocarps, fast growing pioneers, and forest fruit
trees. It is a co-operative venture between the Sabah
Foundation, a semi-government forestry organization in the
state of Sabah, Malaysia, and the FACE Foundation of the
Netherlands.
The total investment committed by the FACE Foundation
amounts to US$ 15 million. It was expected that the project
will sequester at least 4.25 million tonnes of carbon (15.6
million tonnes CO2) during its lifetime at an average cost of
US$ 3.52 per ton of carbon (US$ 0.95 per t CO2).
The planting phase will last for 25 years and the forests will
be maintained for 99 years. The long-term nature of the
project should enable the maintenance and silvicultural
treatments required to sustain growth rates during the
project's life. It is expected that at the end of the first 60-year
growth cycle, these forests will be exploited for timber,
which belongs to the Sabah Foundation. However, timber
harvesting will have to be done in a careful way, so that a
healthy residual stand can again regenerate a well-stocked
forest in order to maintain a carbon pool for the FACE
Foundation, which has the exclusive rights to the carbon
sequestered through the 99 years of the project.
As well as sequestered carbon, the project will produce over
4 million m3 of sawn hardwood timber over the project
lifetime. As the Foundation is a semi-government
organization with the mandate of improving people's welfare
in the state of Sabah, it is expected that the project will also
generate considerable social benefits: it is expected to
generate 230 jobs per year in the planting phase, as well as
substantial research and training of Malaysian students.
This case study illustrates how the Kyoto Protocol's
definitions of forestry could affect the eligibility of projects.
If the current definition of afforestation and reforestation

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Vol. 1(ISC-2011), 388-397 (2012)
Res.J.Recent.Sci
used for activities in developed countries is strictly applied,
this project may not be eligible under the Kyoto Protocol,
since the areas to be rehabilitated have a dense canopy cover
and would already be classed as 'forest'. Appropriate
definitions of forestry would have to be adopted to enable the
inclusion of a wider range of projects.
Scolel Té and the Plan Vivo system: In 1994 a group of
researchers from the University of Edinburgh and El Colegio
de la Frontera Sur in Mexico, undertook a study to ascertain
whether sales of carbon services could improve rural
livelihoods among indigenous farmers in Chiapas, southern
Mexico. The study identified the need for a flexible but
structured administrative framework to aggregate the carbon
benefits from many small-scale activities. Individual farmers
wanted the right to choose how and when to participate, and
it was assumed that purchasers and regulatory authorities
would require effective monitoring and verification
procedures. Over the next 3 years, funding from UK DFID’s
Forestry Research Programme was used to develop an
integrated planning, administration and monitoring system,
based upon the requirements identified in the study. The
system became known as Plan Vivo.
In 1997, the collaborating organizations secured the interest
of a purchaser of carbon services. The pilot project, known as
Scolel Té (‘the tree that grows’) began with an agreement to
provide 18,000 tCO2 ‘prototype carbon credits’ per year, at a
price of US$ 2.7 per CO2 t(US$10 per tC) to the International
Automobile Federation. These funds were used to provide
farmers with carbon payments to cover the costs of
establishing agro forestry systems, small-scale plantations
and communal reforestation activities.
The Scolel Té project is now run by a trust fund – the Fondo
BioClimatico – which has become a financially viable
organization, whose income is derived from the sale of
carbon services. There are currently over 400 individual
participants from about 30 communities, representing four
different ethnic groups and a wide range of agro-ecosystems.
The Plan Vivo system is now also being used in an agro
forestry and bioenergy project in southern India, run by an
NGO called ‘Women for Sustainable Development’.
There are some Industrial Projects from India like the few
given below:
Switching of Fuel from Naptha to Natural Gas in the
Caustic Concentration Plant at Dahej Complex of M/s
Gujarat Alkalies and Chemical Limited: The natural gas will
be transported from the Gujarat State petroleum Corporation
Ltd, Hazira Gas Field to GACL through pipeline. The
generated power will be cater the requirements of Dahej

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Complex and the remaining will be wheeled through the state
grid to the GACL Vadodara complex. The power plant has 2
Nos. of dual firing system equipped with GE designed
turbines having rated capacity of 39.2MW.
Switching of Fuel from Natural Gas to Hydrogen in the
CCU-II at Dahej Complex of M/s Gujarat Alkalies and
Chemical Limited: GACL produces commercial caustic soda
as Lye and Solid Flakes. In GACL Dahej complex
membrane cell technology is deployed. The caustic soda lye
is concentrated in the caustic concentration unit (CCU) to
produce caustic soda flake and this activity is highly energy
intensive. GACL installed CCU-II with dual firing burner
which can run on either hydrogen or natural Gas. The
hydrogen gas available from the caustic soda production
process is fired in the burner by replacing the Natural Gas
with an objective of reducing GHG emissions from the
caustic concentration process.

Zero Carbon Footprint” at Nirma University
Audited by CED India: Carbon footprint refers to the
emission of greenhouse gases such as carbon dioxide into
atmosphere that we generate directly or indirectly. Carbon
footprint is not only limited to the vehicle exhaust, but it
involves almost everything we do, be it the paper we use, the
computers we work on, the packaging of our groceries, or the
disposables such as cups, cartons, and plastic bags that are so
much a part of our life. Carbon footprint not only includes
emission by the raw materials used in the manufacturing of
these goods but also the whole emission starting from its
production till its disposal, be it in their manufacturing
process which consumes fossil-fuel generated electricity, or
the transportation process which causes more emissions by
way of vehicle exhausts. Technically carbon footprint is a
measurement of all greenhouse gases we individually
produce. It is measured in units of tonnes (or kg) of carbon
dioxide equivalent. A carbon footprint is made up of the sum
of two parts, the primary footprint and the secondary
footprint. The primary footprint is a measure of our direct
emissions of CO2, from the burning of fossil fuels including
domestic energy consumption and transportation (e.g. car,
buses, plane, etc.). We have direct control over these.
The Secondary Footprint is a measure of the indirect CO 2
emissions from the whole lifecycle of products we use –
those associated with their manufacture and eventual
breakdown. To put it very simply the more we buy the more
emissions will be caused on our behalf. Our decisions on the
following add up to our secondary footprint:
We eat vegetarian food or non-vegetarian food. We buy /
grow organic food or not, We use mostly seasonal food or
not, We buy local food and goods or not, We buy second
hand clothes or new, We think of packaging while buying

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Vol. 1(ISC-2011), 388-397 (2012)
Res.J.Recent.Sci
things or not, We buy new furniture and appliances or second
hand, The things we use get recycled or composted or not,
we try to avoid burning of fuel on transportation or not. We
try to avoid use common vehicles for travel or not, We bring
a bag when we go shopping or require a plastic bag from
each shop. The direct consequence of increased carbon
footprint is global warming and climate change.
Table-1
Individual primary footprint of the most common
consumptions
Sr.
Particulars
Consumption
Amount of
No.
Amount
CO2 release in
the
atmosphere
(kg)
1
Use of Electricity 1KWh
0.94
2
Kerosene
1 liters
2.52
3
LPG
1 liters
1.5
4
Travelling by car 1000 liters
1500
(LPG)
5
Travelling by car 1000 liters
2320
(Petrol)
6
Travelling by car 1000 liters
2630
(Diesel)
7
Travelling
by 1000 km
60
train by 1 person
Over the past two decades the effects have become more
marked. Considerable evidence exists that most of this
warming has been caused by human activities. We have
altered the chemical composition of the atmosphere through
a buildup of greenhouse gases primarily carbon dioxide,
methane, and nitrous oxide. This means that a ‘cloud’ is
building up around the earth under which heat is
accumulating instead of dispersing in the atmosphere.
If any considerable step is not taken then rising global
temperatures will cause sea level to rise and alter local
climate conditions, affecting forests, crop yields, and water
supplies. It may also affect human health, animals and many
types of ecosystems. Deserts may expand and some of our
countryside may be permanently altered. Therefore, we need
to recognize our personal impact on global warming.
Calculation of ‘Carbon Footprint’ helps us to minimize our
impact and show us how to make the right product choices in
the future.

Calculation
Calculation has been done keeping in mind the footprint
generated due to the whole organization of the event as well
as on the event days. Organization has been considered from
1st January – 31st March, 2010 (90 days).

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Table-2
Electricity calculations: Energy consumptions per day
Appliance
Fan
Tube Light
Computer
Laptops
AC
Miscellaneous
Total

Units
5
20
5
5
2
1

Ratings
(Watt)
60
40
80
50
1000
300

Consumption
(hrs)
6
6
4
10
4
6

KWh
1.8
4.8
1.6
2.5
1.8
1.8
20.5

Table-3
Energy Consumption on the event day (26, 27 March,
2010)
Appliance Units Rating Consumption
K
(Watt)
(hrs)
Wh
Fan
100
60
6
36
Tube Light
200
40
6
48
Computer
20
80
4
6.4
Laptops
100
50
10
50
AC
25
1000
4
10
0
Miscellaneous
5
100
6
3
Total
243.4
Electricity Calculation
88 x 20.5 = 1804
2 x 243.4 = 486.8
Total = 2290.8 which is roughly equivalent to 2300,
Therefore, Carbon footprint generated due to electricity,
2300 (KWh) x 0.94 kgs of CO2 = 2.162 tonnes of CO2,
(Assumed 1 KWh generates 0.94 kgs of CO2),
(Source:http://www.cedindia.org/2009/07/carbon-footprintmapping/)

Transportation Calculation
Flights: 0.43 tonnes of CO2, Assumed 5 flights from
Mumbai
to
Ahmedabad,
(Source:http://www.carbon
footprint.com/businesscalculator.aspx?t=b)
Cars/Bikes: 7.83 tonnes of CO2, Assumptions: Team of 50
people travelling 30 km each on a vehicle with an
approximate mileage of 40 km/liter. Therefore, liters of
petrol consumed = (30 x 50 x 90 days)/40 = 3375 liters of
petrol. Therefore, carbon footprint: 3375 x (2320/1000) =
7.83 tonnes of CO2 (Assume petrol car)
Trains: 12 tonnes of CO2, Approximate number of people
(outside Ahmedabad) travelling by train: 500. Average km
travelled (to and fro): 400 kms. Therefore, carbon footprint:

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Research Journal of Recent Sciences ____________________________________________________________ ISSN 2277 - 2502
Vol. 1(ISC-2011), 388-397 (2012)
Res.J.Recent.Sci
(500 x 400) x 0.06 = 12 tonnes of CO2. Therefore, carbon
footprint generated due to transportation: 0.45 + 7.83 + 12 =
20.28 tonnes of CO2. (Source:http://www.cedindia.org
/2009/07/carbon-footprint-mapping/)
Energy usage by cooking: 0.6 tonnes of CO 2: Taking into
account the meals for two days (lunch and dinner), amount
of LPG consumed that will be around 20 commercial
cylinders (20 liter each). Emission of CO2 per liters = 1.5 kg
of CO2. Therefore, carbon footprint: (400 x 1.5) = 0.6 tonnes
of CO2. (Source:http://www.cedindia.org/2009/07/carbonfootprint-mapping/)
Table-4
The total carbon footprint generated in the span of 3
months
Categories
Amount of CO2
emitted (tonnes)
Electricity
2.162
Transportation
20.28
Food
0.6
Miscellaneous (Assuming
7.68
25% of total)
Total
30.722
The 30.722 tonnes of CO2 emitted during the span of 3
months was equivalent to 2000 plants that would nullify
the effect of the above said carbon emissions. The
plantation was done in the campus itself.

References
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http://cdmindia.nic.in/cdm_india.htm

2.

The
Kyoto
Protocol,
http://unfccc.int/kyoto_protocol/items/2830.php

3.

http://carbonfinance.org/Router.cfm?Page=FAQ&ItemI
D=24677#2
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11. http://unfccc.int/kyoto_protocol/mechanisms/clean_dev
elopment_mechanism/items/2718.php

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12. http://www.articlesbase.com/environment-articles/thepower-of-carbon-trading-in-india-893696.html
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lan_vivo_popup.html
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in_decided_popup.html
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in.htm
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in.htm#c
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32. http://www.gtz.de/en/weltweit/asien-pazifik/31162.htm
33. http://www.ieta.org/ieta/www/pages/index.php?IdSiteP
age=959
34. http://www.indiaenvironmentportal.org.in/category/thes
aurus/climate-change/emissions-trading/cleandevelopment-mechanism-cdm
35. http://www.teriin.org/ee/cdm/cdm.htm

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