Carbon dioxide is ever – more a green-natured agent when applied in a growing number of industries. Further, it is often difficult to think of carbon dioxide as a green chemical or gas, when at first blush, CO2 is indeed the greatest… greenhouse gas by volume; not the worst of all heat trapping gases, but the greatest (by volume) when emitted. All of this is relevant to the industries which produce a CO2 by-product or flue gas; as well as those gas companies which recover, refine, and sell the product to the merchant markets.
By many accounts, CO2 atmospheric levels are near 400 ppm, a record by modern standards, while noting CO2 levels have steadily risen since the beginning of the industrial revolution; however accelerated during the last number of years and decades. In the end, it is clear to see the often dire effects which climate change can take, as evidenced by melting glaciers and the shrinking artic ice.
Perhaps the most daunting image happens to be the drowning of, and unlikely relocation of polar bears. Then, it is important to note since the 1960s, over some 40 years, CO2 atmospheric content has increased by a factor of 20%. This is indeed, truly unsustainable.
However, there is hope to turn the tide, or at least arrest the accelerated growth of carbon emissions, via many small steps; and major steps toward CO2 emissions reduction schemes. This can start with green CO2 applications from planting more green life, trees, and even more commercial greenhouse crops; to large ventures such as enhanced oil recovery (EOR) projects, which can truly sequester & recycle CO2.
Many green CO2 applications are essentially well proven and are now essentially old technologies, which continue to work well. Ahead we go toward developing additional green and environmentally friendly carbon dioxide uses in industry; as well as improved methods of sequestering the product.
Changes in the perception of applications – if even for economic reasons v. perceived green results are the motivating factor
The problem with CO2 sequestration and carbon reduction schemes is the lack of economic return for many purely sequestration projects, unless government funding or subsidies are guaranteed. Then, the challenge is to find projects which are truly green from a sequestration perspective, while they weather the test of economic returns. With this in mind, EOR may be on the top of the list, in terms of receiving potential and real economic returns from the application of carbon dioxide which achieves carbon sequestration as well. This represents incremental returns from the rater long – term investment in EOR, often running from years to many decades in duration. Otherwise unobtainable oil is recovered, plus CO2 is actually sequestered in the geological formations. Therefore, in some ways, CO2 emissions are essentially ‘taken off the table’.
Then we also have the ongoing arguments surrounding absolute removal of carbon by-product into various modes of sequestration v. only displacing the CO2 into various markets via a wide range of uses in industry. Sequestration v. displacement of CO2 via applications is perhaps a matter of perception; however some of this is rather clear. It is truly clear to see applications which replace harmful, carcinogenic, and toxic agents such as various halogenated hydrocarbon compounds (such as ‘perc’ in dry cleaning environments) v. carbon dioxide, which is an excellent solvent, without the terrible legacy associated with dry cleaning operators developing cancer; which is common in the industry.
When thinking in terms of economic gains received via certain green applications, the greatest example of this, perhaps, would be EOR applications, which have proven to be effective in recovery of oil as well as sequestering CO2; all dependent upon the geology of the well. Below, I am reviewing a number of common and proven green applications used in industry.
All of this is important to the readers of this article, particularly to the gas company professional; where markets can be enhanced by more use of the ‘green – related’ CO2 applications; both in terms of gaining more CO2 market share, and increasing revenues. Further, many of these new developments in industry essentially create new CO2 business from otherwise applications of solvents and chemicals of a noxious nature.
Green applications typical for carbon dioxide in industry
CO2 as a solvent – Supercritical extraction: Essential oil extraction, decaffeination of coffee and tea – Of course supercritical extraction of essential oils has both food – related and for cosmetic applications. Flavoring agents, essential oils, and of course caffeine removal from coffee and tea are among the major applications for supercritical extraction. This has the benefit of eliminating sometimes hydrocarbon – based solvents from the process in lieu of a food grade CO2 which has no residue, and is harmless to the consumer. Products of this process can then be labeled ‘natural’.
Dry cleaning industry: It has been said many of the dry cleaning industry’s long term workers who have used ‘perc’ for years, often end up with a variety of diseases including cancer and organ damage; however when applied in specially designed machines, CO2 is an excellent solvent, for a truly healthy dry cleaning environment, which also yields outstanding cleaning results from the process.
Further, the application can be sought to help reduce calcium carbonate scale within the distribution system, where literally calcium scale can fully plug up the water lines. Then, the application is an environmentally friendly alternative to mineral acids (hydrochloric, sulfuric, and nitric), where CO2 by-products are benign carbonates and bicarbonates v. sulfur compounds from sulfuric, for example.
In the end, this application should be explored fully in all industries which have effluent, or a need to reduce the Ph, which are otherwise being treated by other agents, such as mineral acids, and of course evaluate opportunities in municipal treatment systems. How much greener can we get than naturally purifying and reducing the Ph in the water we drink?
CO2 in a gaseous form for agricultural uses: Perhaps another very ‘natural’ form of CO2 usage in a ‘literally’ green (flower and plant growing) format would be the application of CO2 for greenhouse plant growth enrichment. In this context, of course, photosynthesis is enhanced with the CO2 content elevated from our current levels near or at 400 ppm to 1,000 ppm; and the plant growth factor is estimated to be enhanced up to 50% with this treatment. Overnight, the application occurs, and in the years and decades past, greenhouses often used fossil fuel combustion flue gas to obtain some boost in CO2 content; but not very concentrated; with a noxious mix of gases v. pure CO2. Then, various projects worldwide have evaluated the use of CO2 by-product streams from traditional source production, such as ethanol. Also, during the high development days of US cogeneration projects, greenhouses served as a ‘thermal sink’ for the cogeneration flue gas.
Insect fumigation : In lieu of using various chemical agents for insect control in grain storage facilities, CO2 maintained at about 50% by volume in the atmosphere, for 4-7 days, generally in warmer climates over 60 degrees F, is an excellent means of eliminating chemical agent, and controlling insects; in a very green way. This application would be particularly interesting to buyers of grain products which are labeled ‘natural’ or language relating to being processed in a ‘green’ manner.
Algae farms: As algae is an area with is being embraced more readily for applications in biodiesel, such as extraction of algae oil for biodiesel projects, CO2 is of course one of the raw ingredients required for algae growth. Everything from power project flue gas to merchant CO2 deliveries have been used in algae projects, which remain in early stages of development; when thinking of commercialization for large biodiesel projects.
As a small usage requirement, CO2 is used from micro-bulk storage for algae growth; and algae can serve as a foodstuff for shrimp and seafood farms; then this seafood or their prodigy end up on our dinner tables. This is green CO2 usage found in an everyday food industry context.
Dry ice blasting: This of course has been promoted for some years as the logical, clean, and safe alternative to various forms of cleaning, from a menu of solvents, to sand, for example. Dry ice blasting inquiries from independent gas producers in developing countries continue to grow, where this has been the basis of new CO2 producer start-ups in some cases. Even though this represents a small percent of total CO2 sales, it is a means of selling and supplying a greater service which entails the use of the CO2. It represents far more than the price of the commodity as a unique and clean form of removing a wide variety of materials from many surfaces. The lack of leaving behind a mess is perhaps the greatest advantage found.
Enhanced fossil fuel yield: Under this heading, the most obvious, perhaps, is EOR, which achieves various tasks, primarily enhanced recovery and revenues from oil; and secondly, a viable form of sequestration. EOR project interest has literally exploded in North America. Numerous ethanol projects in the US have their CO2 by-product delivered to EOR projects by pipeline; and many more such projects are under evaluation for possible development.
Since oil and gas production in North America is significantly on the rise, plus the potential and true need to recover as much oil from otherwise depleted wells is now fostered more than ever, and since there is pressure to sequester ever – more CO2 due to climate change, as well as some industry and political influence in favor of EOR is underway, more EOR developments will occur.
One such project of interest in Saskatchewan is Sask Power, which will take and sequester over 1 million metric tons of CO2 from a coal fired power plant, their 140 MW unit 3. The ultimate goal is to expand the currently operating Weyburn oil field, which will deliver through a 40-mile pipeline the CO2 recovered via MEA technology. The pipeline is being built by Cenovus Energy, which is the oil company expanding the EOR project. This represents real change from a greenhouse gas emitted from power production, both to enhance oil recovery and achieve CO2 sequestration all in one.
Then, when looking at this, as well as other applications, isn’t all of this representative of changes for the greater good, and in favor of a green economy and environment; while using a gas which, by volume, has been the greatest offender? It is important for the gas companies to focus on green technologies, some of which will take business from ‘competing’ chemical agents used in industry v. only using CO2, and expand markets. This is more than perception alone; it is truly green in nature.
View original article at: Can CO2 be a green chemical? Yes, when derived from biofuels and other sources