Studies regarding the C[O.sub.2] recovery from the atmosphere.
Tokar, Adriana ; Negoitescu, Arina ; Mihon, Liviu 等
1. INTRODUCTION
The sun is the Earth's primary energy source, providing heat
from over 150 million km away. Its rays enter our atmosphere and shower
upon on our planet. About one third of this solar energy is reflected
back into the universe by shimmering glaciers, water and other bright
surfaces. Two thirds, however, are absorbed by the Earth, warming the
land, oceans, and atmosphere. Much of this heat radiates back out into
space, but some of it is stored in the atmosphere, process called the
greenhouse effect. Without it, the Earth's average temperature
would be a chilling -18 C[degrees], even despite the sun's constant
energy supply.
Studies indicate that until some billion years ago, there was so
much carbon dioxide (C[O.sub.2]) and methane in our atmosphere that
average temperatures on Earth were as high as 70 C[degrees]. But
bacteria and plants slowly turned C[O.sub.2] into oxygen and the
concentration of C[O.sub.2] in our current atmosphere dropped to just
about 383 parts per million (ppm), a unit of measurement used for very
low concentrations of gases that has become a kind of currency in
climate change debates (Easterling, 1997).
2. SOLUTIONS FOR C[O.sub.2] REDUCTION
Investments in research on global warming have resulted in
different solutions on neutralization of C[O.sub.2] emissions. Each
inhabitant of the planet can contribute financially to the projects
development for C[O.sub.2] emissions reduction. Drivers and air flights
passengers can help to neutralize carbon emissions by paying a fee for
each ton of C[O.sub.2] emitted depending on the mileage. The largest
sources are vehicles and non-nuclear power stations--that burn coal, oil
or gas, otherwise known as fossil fuels. In Figure 1 are presented the
main sectors which generate C[O.sub.2]. Natural gas vehicles are one
alternative mode of transportation that is helping to reduce C[O.sub.2]
emissions, protect public health and the environment as is presented in
Figure 2.
World C[O.sub.2] emissions are expected to increase by 1.9%
annually between 2001 - 2025. Developing countries emissions are
expected to grow above the world average at 2.7% annually between 2001 -
2025 and surpass emissions of industrialized countries around 2018 as it
is shown in Figure 3.
Hybrid Cars, are helping to bridge the gap between conventional
gasoline engines and the cleaner hydrogen vehicles of the future.
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Hybrids clearly cut fuel consumption, particularly in city traffic.
With only a few hundred thousand vehicles, the proportion of hybrid
vehicles in the global market is still quite small. By 2015, hybrids
could account for up to 2 percent of all cars in Europe-rapid growth
from a modest starting point (www.knowlidge.allianz.com, 2003).
3. METHODS FOR C[O.sub.2] REDUCTION AND STORAGE
To prevent the carbon dioxide building up in the atmosphere
(possibly causing global warming and definitely causing ocean
acidification), we can catch the C[O.sub.2], and store it. The best
place to capture CO2 is at the major sources of emissions.
The power-plant emissions, called flue gases, are typically only
10% to 15% CO2 in a coal-burning plant and about 5% when natural gas is
the fuel. For the CO2 to be stored efficiently, it first has to be
separated from the other flue gases.
There are three strategies: separate the CO2 after combustion,
extract carbon of the fuel before combustion so that only hydrogen burns
and produce only water, burn fossil fuels in oxygen rather than air,
resulting in concentrated C[O.sub.2] (http://eia.doe.gov, 2005).
Chemical solutions can be used to dissolve the CO2 while passing
the other gases to the atmosphere. The technique most widely used today
employs a group of compounds called amines. They absorb CO2by forming
chemical bonds, particularly at high pressure and low temperature. The
resulting chemical solution is later heated and the pressure reduced,
releasing concentrated CO2. Other solvents are used to dissolve CO2
without chemical bonding. In this physical absorption process the CO2
dissolves under pressure and is later removed from the solvent by
reducing the pressure. The solvent may then be reused. Another strategy
for capturing CO2 is to cool the flue gases to the point where the CO2
becomes liquid. This process requires considerable energy for
refrigeration. An advantage is that the liquid can be easily transported
by truck or ship. It is also possible to separate gases by using thin
films called membranes. Some gases will pass through a membrane faster
than others. This allows the different gases to be separated from one
another.
Getting the Carbon Out before Combustion. Methane in natural gas
produces by burning both C[O.sub.2] and water ([H.sub.2]O). If carbon
can be taken out before combustion it will result hydrogen, which
produces only water during burning. So, carbon monoxide (CO) and
hydrogen will result from fuel with oxygen and/or steam reaction. Than
the carbon monoxide reacts with more steam to produce C[O.sub.2] and
more hydrogen. Finally, the C[O.sub.2] is separated and the hydrogen is
used as fuel in a gas turbine (http://co2capturestorage.inf, 2009).
Once concentrated C[O.sub.2] has been captured, the next step is to
store it somewhere, Figure 2. The options are as it follows:
--Geological Formations. Storage in geological formations is
currently the most promising solution for widespread, long-term
sequestration of CO2. Some projects are already under way. In order to
reduce greenhouse gases and global warming, stored CO2 must be kept out
of the atmosphere for hundreds or thousands of years. Oil and
natural-gas reservoirs, deep saltwater aquifers, and coal seams have
existed for millions of years with only very gradual changes. There is
strong evidence that if properly managed, these formations could provide
for long-term storage of CO2.
--Depleted Oil and Natural-Gas Reservoirs. Oil and natural gas are
found these in permeable and porous rocks such as sandstone. These rocks
contain microscopic spaces, called pores, which fill with fluids. The
fluids may be water, oil, or natural gas. An oil or natural-gas
reservoir is more like a sponge than a bottle. Once an oil or
natural-gas field has been productive for a period of time, a good
portion of the hydrocarbons has been removed. There is space available
to store CO2. The porous and permeable rock layer that contains these
fluids is covered by an impermeable cap rock that does not let them pass
through. Normally, oil and natural gas will tend to migrate upward
through permeable rock because they are lighter than the water that is
also found in such rock formations. The cap rock traps them. Since oil
and natural gas have been sequestered in such formations for millions of
years, there is good reason to believe that CO2 will remain there as
well.
--Enhanced Oil Recovery. Much of the technology needed to store
C[O.sub.2] in oil fields is already being used for a process known as
enhanced oil recovery (EOR).
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When a reservoir is newly tapped, the oil is typically under
pressure and flows freely to the surface. As oil is removed, pressure
drops and pumping is needed to recover more.
At some point recovery becomes uneconomical and is stopped, or
additional techniques are used to extract more oil. One approach is to
pump C[O.sub.2] into the reservoir. This increases pressure so the oil
flows more readily. Also, the C[O.sub.2] dissolves in the oil and causes
it to become less viscous and flow more easily. It expands in volume as
well, further increasing pressure. C[O.sub.2] is pumped into the
reservoir through an "injection well." This forces the oil
toward a "production well," where it rises to the surface
(Aresta, 2003).
4. CONCLUSION
While we are still far from seeing major concentrations of
C[O.sub.2] in our atmosphere, slight changes already alter the way our
celestial heating system works. Measurements of carbon dioxide amounts
show that C[O.sub.2] has increased from about 313 ppm in 1960 to about
383 ppm at present. That means for every million particles in our
atmosphere, there are now 70 C[O.sub.2] particles more than in 1960.
Even if this does not seem like much, scientists say this increase, most
probably caused by human activities, is mainly responsible for rising
global temperatures throughout the last decades. Figure 5 shows that at
the end of the century, temperatures would increase by up to 3
[degrees]C in Europe.
Three different types of technologies for capturing C[O.sub.2]
exist: post-combustion, pre-combustion, and oxyfuel combustion. These
can be applied to large point sources, such as large fossil fuel or
biomass energy facilities, major C[O.sub.2] emitting industries, natural
gas production, synthetic fuel plants and fossil fuel-based hydrogen
production plants. Although in Romania there is no industrial applicable
system for reducing and capturing the C[O.sub.2] emissions yet, romanian
researchers must become interested in these technologies implementation
and development.
5. REFERENCES
Aresta, M. (2003). Carbon Dioxide Recovery and Utilization, Kluwer
Academic Publishers, ISBN 1-4020-1409-0, Netherland
Easterling, D.R., et al. (1997). Maximum and minimum temperature
trends for the globe. Science, 277, pp. 364-367
*** (2009) http://co2capturestorage.inf--IEA Greenhouse Gas R&D
Programme, Accesed on: 2009-04-13
*** (2005) http://eia.doe.gov--Energy Information Administration
(EIA), Accesed on: 2009-02-14
*** (2003) www.knowlidge.allianz.com--Allianz Center for Technology
in Germany, Accesed on: 2009-03-24
Fig. 1. Global Carbon Dioxide Production by Sector
Industry 22%
Transport 23%
Electricity Generation 39%
Agriculture 2%
Other 4%
Residential 10%
Source: Energy Information Ad
http://eia.doe.gov
Note: Table made from pie chart.
