Spelling suggestions: "subject:"carbon dioxide (mitigation)"" "subject:"charbon dioxide (mitigation)""
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Public attitudes toward geological disposal of carbon dioxide in Canada /Sharp, Jacqueline. January 2005 (has links)
Research Project (M.R.M.) - Simon Fraser University, 2005. / Research Project (School of Resource and Environmental Management) / Simon Fraser University.
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A strategy for prevention of sequestered CO₂ seepage from CBM formationsTovar Torrealba, Miguel Angel. January 1900 (has links)
Thesis (M.S.)--West Virginia University, 2006. / Title from document title page. Document formatted into pages; contains xii, 87 p. : ill. (some col.), col. map. Includes abstract. Includes bibliographical references (p. 48-51).
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Carbon capture and storage optimisation in solid oxides : understanding surface-fluid interactionsMutch, Greg Alexander January 2016 (has links)
To decrease carbon dioxide emissions into the atmosphere for climate change mitigation it is necessary to modify existing practices in processes where greenhouse gases are emitted. Due to the extremely large volumes of carbon dioxide produced globally, it is generally accepted that although carbon dioxide conversion and utilisation will contribute in the long term, in the short to medium term it will be necessary to capture and store carbon dioxide emissions to progress towards a low carbon future. Current industrial capture processes incur large energy and thus economic penalties. Storage in geological formations requires robust confidence in storage security to be publically accepted. Therefore the objective of this work was to study carbon dioxide capture and storage in processes directly confronting these two major challenges. Carbon dioxide adsorption on oxide materials for advanced carbon capture processes with lower energetic and economic penalties was investigated. Water was shown to play a crucial role in determining the presence of reactive sites, the speciation of carbonates formed and increased sorbent utilisation. A high surface area oxide with specifically exposed facets was prepared and the impact of these facets on carbon dioxide uptake performance was assessed. Volumetric gas adsorption and isotherm modelling supported the presence of two distinct adsorption sites. To enhance confidence in storage security it is necessary to understand storage processes that result in stable products. An apparatus capable of obtaining geological storage conditions was developed and carbonate formation and surface hydration at high pressure was investigated. By locating individual reactive cations on the surface of silica, silicate mineral analogues were prepared. It was shown that carbonate speciation was dependent on the reactive cation and the presence or absence of water.
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Carbon dioxide capture methods for industrial sources.Osman, Khalid. January 2010 (has links)
In order to reduce the rate of climate change, particularly global warming, it is imperative that
industries reduce their carbon dioxide (CO2) emissions.
A promising solution of CO2 emission reduction is Carbon dioxide Capture and Storage (CCS)
by sequestration, which involves isolating and extracting CO2 from the flue gases of various
industrial processes, and thereafter burying the CO2 underground.
The capture of CO2 proved to be the most challenging aspect of CCS. Thus, the objective of this
research was to identify the most promising solution to capture CO2 from industrial processes.
The study focussed on capturing CO2 emitted by coal power plants, coal-to-liquids (CTL) and
gas-to-liquids (GTL) industries, which are common CO2 emitters in South Africa.
This thesis consists firstly of an extensive literature review detailing the above mentioned
processes, the modes of CO2 capture, and the various CO2 capture methods that are currently
being investigated around the world, together with their benefits and drawbacks in terms of
energy penalty, CO2 loading, absorption rate, capture efficiency, investment costs, and operating
costs. Modelling, simulation, and pilot plant efforts are also described.
The study reviewed many CO2 capture techniques including solvent absorption, sorbent capture,
membrane usage, hydrate formation, and newly emerging capture techniques such as enzyme
based systems, ionic liquids, low temperature cryogenics, CO2 anti-sublimation, artificial
photosynthesis, integrated gasification steam cycle (IGSC), and chemical looping combustion
The technique of solvent absorption was found to be the most promising for South African
industries. Vapour-liquid-equilibrium (VLE) measurements of solvent absorption using amine
blends were undertaken, using blends of methyl-diethanol amine (MDEA), diethanol amine
(DEA) and water (H2O) with composition ratios of 25: 25: 50 wt% and 30: 20: 50 wt%
respectively, and with CO2 and N2 gases at CO2 partial pressures of 0.5 to 10.5 bar. Experiments
were conducted under system pressures of 5 to 15 bar and temperatures of 363.15 and 413.15 K,
using a static analytic apparatus. CO2 liquid loading results were analysed and discussed.
The experimental data were regressed in Matlab (R2009b) using the Posey-Tapperson-Rochelle
model and the Deshmukh-Mather model. The Matlab programmes are presented along with the
regressed binary interaction and model parameters. The accuracy of model predictions are
discussed.
Thereafter an Electrolyte-NRTL model regression and simulation of the absorption process was
conducted using Aspen Plus V 7.1. for flue gas compositions, solvent compositions,
temperature, and pressure conditions similar to that of process operating conditions. CO2
loading, design factors, CO2 recovery, and CO2 purity results were analysed and compared where appropriate, with experimental results. Finally a general preliminary energy efficiency
and cost analysis was conducted based on the simulation results.
The main conclusions reached are that the amine solvent blend containing 25:25:50 wt% of
MDEA:DEA:H2O, produced higher CO2 loadings for its respective system conditions than other
solvents studied and those found in literature. However, absorption of CO2 was found to be
highly dependent on system temperature and pressure.
The Deshmukh-Mather model provided higher accuracy than the Posey-Tapperson-Rochelle
model, producing CO2 loading predictions with a relative error not exceeding 0.04%, in 1.5 to 3
minutes using a dual core processor.
Aspen absorption simulations provided significantly lower CO2 loading results than those
experimentally obtained, due to the low contact time achieved and higher temperature
dependence in the proposed absorption process. Process improvements were highlighted and
implemented to increase CO2 recovery and purity. Energy penalty values were found to be
higher than those found in literature, but room for process and design improvement was
identified and recommendations were given. Investment cost estimates were found to be
justifiable and within reason. Limitations of the simulation were also identified and discussed. / Thesis (M.Sc.Eng.)-University of KwaZulu-Natal, Durban, 2010.
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Synthesis and performance evaluation of nanocomposite ceramic-sodalite membranes for pre-combustion CO2 captureOloye, Olawale January 2017 (has links)
A dissertation submitted to the Faculty of Engineering and the Built Environment, University of the Witwatersrand, Johannesburg, in fulfillment of the requirements for the degree of Master of Science in Engineering.
9 February, 2017 / Global climate change and other environmental disasters have been attributed to continuous anthropogenic carbon dioxide (CO2) emission into the atmosphere. Today, researchers are constantly seeking measures to reduce anthropogenic CO2 emission. Traditionally, absorption technology with use of monoethanolamine (MEA) is used for separating / capturing of anthropogenic CO2. However, the use of MEA is associated with numerous shortcomings, including inefficient energy usage, high operating and capital cost, amine degradation, solvent loss and excessive equipment corrosion. Alternatively, zeolite based membrane systems are promising technique that prove handy and useful than the traditional processes (absorption with monoethanolamine). However, zeolitic membranes with zeolite coating on the supports (i.e. thin-film supported zeolite membranes) are susceptible to abrasion and thermal shock at elevated temperatures due to temperature mismatch between the supports and the membranes, making them to lose selectivity at early stages. On the contrary, nanocomposite architecture membranes, synthesized via pore-plugging hydrothermal route, are more thermally stable and membrane defects are controlled. Nanocomposite zeolite (sodalite) membranes have been proposed for gas separations, most importantly in the separation of H2/CO2, a major component in pre-combustion carbon capture. In addition, sodalite, a porous crystalline zeolite made up of cubic array of β-cages as primary building block having cage aperture in the range of 0.26 and 0.29 nm, is a potential candidate for the separation/purification of light molecules such as hydrogen which has a cage aperture of 0.27 nm under certain process conditions.
In this work, nanocomposite architecture hydroxy sodalite membrane with sodalite crystals embedded within α-alumina tubes were successfully synthesized using the pore-plugging hydrothermal synthesis technique and characterized using techniques such as scanning electron microscopy (SEM) and X-ray diffraction (XRD). The morphology of the synthesized membranes shows that sodalite crystals were indeed grown within the porous structures of the support. Furthermore, Basic Desorption Quality Test (BDQT) and gas separation measurement were conducted to evaluate the
quality of the as-synthesized membrane in industrial gas separation applications. The effects of operating variables such as pressure at 1.1 bar, 2.0 bar and 3.0 bar. Also, the effects of temperature were conducted on the nanocomposite membrane at 373 K, 423 K and 473 K. Finally, the gases permeation results were fitted with the well-known Maxwell-Stefan model.
Results indicated that, the nanocomposite sodalite / ceramic membrane is a potential candidate for removal of H2 from H2/CO2 mixture. The gas permeation measurement from the one-stage nanocomposite membrane shows that the membrane displayed H2 and CO2 permeance of 3.9 x 10-7 mols-1m-2Pa-1 and 8.4 x 10-8 mols-1m-2Pa-1, respectively. However, the morphology of two-stage nanocomposite membrane shows that the support was more plugged with sodalite crystals and the permeance of H2 and CO2 were 7.4 x 10-8 mol.s-1.m-2.Pa-1 and 1.1 x 10-8 mol.s-1.m-2.Pa-1, respectively. Consequently, the H2/CO2 ideal selectivity for the one-stage nanocomposite membrane improved from 4.6 to 6.5 in the two-stage nanocomposite membrane.
In conclusion, the two-stage synthesized membrane shows better improvement. The porous support was well plugged and separation performance was evaluated. However, occluded organic matters present in the cages of hydroxy sodalite could have adverse effect on the gas permeation performance of the membrane. It is expected that an organic-free sodalite supported membrane (such as silica sodalite supported membrane) could out-perform the hydroxy sodalite supported membrane reported in this work in term of membrane flux because there will be enough pore space for gas permeation. / MT2017
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Options for achieving a 50% reduction in steel industry CO₂ emissions by 2050Waugh, Rachel Louise January 2013 (has links)
No description available.
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An evaluation of mineral carbonation as a method for sequestration of carbon dioxideRock, Robert. January 2007 (has links) (PDF)
Thesis (M.E.S.)--The Evergreen State College, 2007. / Title from title screen viewed (2/14/2008). Includes bibliographical references (leaves 34-40).
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Biological sequestration of carbon dioxideBagga, Rajinder S. January 2000 (has links)
Thesis (M.S.)--Ohio University, August, 2000. / Title from PDF t.p.
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The politics of counting carbon lessons from the California Climate Action Registry /Mazurek, Jan, January 2008 (has links)
Thesis (Ph. D.)--UCLA, 2008. / Vita. Includes bibliographical references (leaves 197-198).
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Artificial neural networks for reservoir level detection of CO₂ seepage location using permanent down-hole pressure dataJalali, Jalal. January 2010 (has links)
Thesis (Ph. D.)--West Virginia University, 2010. / Title from document title page. Document formatted into pages; contains xii, 140 p. : ill. (some col.), col. maps. Includes abstract. Includes bibliographical references (p. 99-104).
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