Chemistry Nobel Laureate writes a monograph on the methanol economy.

Synthetic oil is feasible, its production having been proven feasible from coal or natural gas via synthesis-gas, a mixture of carbon monoxide and hydrogen obtained from the incomplete combustion of coal or natural gas (which are themselves non-renewable). Coal conversion was used in Germany during World War II and in South Africa during the boycott years of the Apartheid era. Nevertheless, the size of these operations hardly amounted to 0.3% of the present United States consumption. This route – the so-called Fischer–Tropsch synthesis – is also highly energy consuming, giving complex, unsatisfactory product mixtures, and can hardly be seen as the technology of the future. To utilize still-existing large natural gas reserves, their conversion to liquid fuels through syn-gas is presently developed for example on a large scale in Qatar, where major oil companies including ExxonMobil, Shell or ChevronTexaco, have recently committed over $20 billion to the construction of gas-to-liquid (GTL) facilities, mainly to produce sulfur-free diesel
fuel. However, when completed, this will provide a daily total of some 100 000 t compared with present world use of transportation fuels in excess of 6 Mt per day...

...CO2 can, as mentioned earlier, even now be readily recovered from flue gas emissions of power plants burning carbonaceous fuels (coal, oil, and natural gas), from fermentation processes, and from the calcination of limestone (cement production), production of steel, or other industrial sources. As these plants emit very large amounts of CO2 they contribute to the so-called “greenhouse warming effect” of our planet, which is causing grave environmental concern. The relationship between the atmospheric CO2 content and temperature was first studied scientifically by Arrhenius as early as 1898. The warming trend of our Earth can be evaluated only over longer time periods, but there is clearly a relationship between the CO2 content in the atmosphere and Earth’s temperature. Recycling CO2 into methanol (or dimethyl ether) and, through this into useful fuels and synthetic hydrocarbons and products, will not only help to alleviate the question of our diminishing fossil fuel resources, but at the same time help to mitigate global warming caused at least in part by man-made greenhouse gases. One highly efficient method of producing electricity directly from fuels is achieved in fuel cells via their catalytic electrochemical oxidation, primarily that of hydrogen.

"Our report answers several key questions," said Bob Perlack, a member of ORNL's Environmental Sciences Division and a co-author of the report. "We wanted to know how large a role biomass could play, whether the United States has the land resources and whether such a plan would be economically viable."
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Looking at just forestland and agricultural land, the two largest potential biomass sources, the study found potential exceeding 1.3 billion dry tons per year. That amount is enough to produce biofuels to meet more than one-third of the current demand for transportation fuels, according to the report.

Such an amount, which would represent a six-fold increase in production from the amount of biomass produced today, could be achieved with only relatively modest changes in land use and agricultural and forestry practices.

"One of the main points of the report is that the United States can produce nearly 1 billion dry tons of biomass annually from agricultural lands and still continue to meet food, feed and export demands," said Robin Graham, leader for Ecosystem and Plant Sciences in ORNL's Environmental Sciences Division.

The benefits of an increased focus on biomass include increased energy security as the U.S. would become less dependent on foreign oil, a potential 10 percent reduction in greenhouse gas emissions and an improved rural economic picture.

Current production of ethanol is about 3.4 billion gallons per year, but that total could reach 80 billion gallons or more under the scenario outlined in this report.

Ph.D., Resource Economics, 1978, University of Massachusetts, Amherst
Over 25 years experience in energy/environmental economic assessment, global climate change analysis, and policy analysis

1980 to present Oak Ridge National Laboratory, Oak Ridge, TN
      Environmental Sciences Division, Bioenergy Systems Group
      • Providing economic and technical analysis and management to a variety of projects for the U.S. Department of Energy, the U.S. Federal      Energy Regulatory Commission, and the U.S. Agency for International Development.

      • Recent activities: economic and policy analysis of bioenergy systems; adaptation responses to climate change; strategic environmental and economic assessments in developing countries; water policy studies involving conflicts between off-stream and in-stream uses; analysis of benefits at federal headwater dams; evaluation and development of performance metrics; and analysis of land use management strategies for greenhouse gas mitigation.