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Which is most abundantly found green house gas? 

Thermal decomposition
Artinite
Dypingite
Carbonate minerals
Carbonate

Answers from top 9 papers

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Papers (9)Insight
Open accessJournal ArticleDOI
Refrigerants and their Environmental Impact Substitution of Hydro Chlorofluorocarbon HCFC and HFC Hydro Fluorocarbon. Search for an Adequate Refrigerant
Samira Benhadid-Dib, Ahmed Benzaoui 
01 Jan 2012-Energy Procedia
85 Citations
The solution to the environmental impacts of refrigerant gases would therefore pass by a gas which contains no chlorine no fluorine and does not reject any CO2 emissions in the atmosphere, in brief a green gas!
Open accessJournal ArticleDOI
Building envelope performance with different insulating materials – An exergy approach
Y. Anand, Sanjeev Anand, A. Gupta, S. K. Tyagi 
01 Apr 2015-Journal of Thermal Engineering
10 Citations
Buildings have now a days become the largest producer of green house gases, thus making them a potential option for analysis.
Open accessJournal ArticleDOI
Thermal stability of artinite, dypingite and brugnatellite—Implications for the geosequestration of green house gases
Ray L. Frost, Silmarilly Bahfenne, Jessica E. Graham, Wayde N. Martens 
15 Sep 2008-Thermochimica Acta
57 Citations
The approach to remove green house gases by pumping liquefied carbon dioxide several kilometres below the ground implies that many carbonate containing minerals will be formed.
Journal ArticleDOI
Comparison of organic matter occurrence and organic nanopore structure within marine and terrestrial shale
han Zhang, Yanming Zhu, Yang Wang, Wei Kang, Shangbin Chen 
01 May 2016-Journal of Natural Gas Science and Engineering
19 Citations
are most promising for gas accumulation.
Open accessJournal ArticleDOI
The structure of selected magnesium carbonate minerals – A near infrared and mid-infrared spectroscopic study
Ray L. Frost, Silmarilly Bahfenne, Jessica E. Graham, B. Jagannadha Reddy 
26 Jun 2008-Polyhedron
24 Citations
The approach to remove green house gases by pumping liquid CO2 several kilometres below the ground implies that many carbonate containing minerals will be formed.
Book ChapterDOI
Spectroscopic and Chromatographic Characterization of the Composition of Organic Matter in Arid Salt-Affected Soils Under Different Vegetation Cover, Southeastern Tunisia (Gabes and Medenine)
Zohra Omar, Abdelhakim Bouajila, Jalloul Bouajila, Rami Rahmani, Houda Besser, Younes Hamed 
12 Nov 2018
5 Citations
It consolidates the soil’s potential to store the green house gases.
Journal ArticleDOI
Iron catalyzed hydrogenation and electrochemical reduction of CO2: The role of functional ligands
Arne Glüer, Sven Schneider 
15 Apr 2018-Journal of Organometallic Chemistry
21 Citations
The reduction of CO2 is an attractive route to utilize the green-house gas as a C1 building block.
Journal ArticleDOI
Measurement of particulate phase polycyclic aromatic hydrocarbon (PAHs) around a petroleum refinery.
Padma S. Rao, M. Faiyaz. Ansari, P. Pipalatkar, Anupama Kumar, P. Nema, Sukumar Devotta 
01 Feb 2008-Environmental Monitoring and Assessment
29 Citations
Also, since it acts as precursor to green house gas, the data would be useful for climate change assessments.
Open accessJournal ArticleDOI
Thermal stability of artinite, dypingite and brugnatellite—Implications for the geosequestration of green house gases
Ray L. Frost, Silmarilly Bahfenne, Jessica E. Graham, Wayde N. Martens 
15 Sep 2008-Thermochimica Acta
57 Citations
It is concluded that pumping liquefied green house gases into magnesium bearing mineral deposits is feasible providing a temperature of 350-355 degrees Celsius is not exceeded to prevent escape of CO2 towards the surface.

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