2. Methanol from catalytic hydrogen

2. Methanol from catalytic hydrogenation
of CO2
Much effort is now being put on CO2 conversion to methanol
(see Eq.(3)). This method is a useful strategy of CO2 utilization
and a practical approach to sustainable development (Song,
2006). It is technically competitive with the industrial production of methanol from syngas (Aresta and Dibenedetto,
2007). The production of methanol and its derivatives by alternative routes and their use as fuels and chemicals is the
core of the methanol economy, a concept earlier proposed
by Olah and co-workers (seeOlah, 2005; Olah et al., 2009a,b,
2011). In this conception, CO2is captured from any natural or
industrial source, human activities or air by absorption and
chemically transformed into methanol, dimethyl ether and
varied products including synthetic hydrocarbons. According
to Olah (2005), methanol production from CO2 is advantageous owing to the usage of non-fossil fuel sources (unlike
syngas), avoidance of CO2 sequestration (which is expensive)
and the opportunity for mitigation of the Greenhouse effect
(by effective recycling of CO2).Olah et al. (2009a)emphasized
that the chemical recycling of CO2 to methanol (and dimethyl
ether) provides a renewable, carbon-neutral, unlimited source
for efficient transportation fuels, for storing and transporting
energy, as well as convenient feedstock for producing ethylene
and propylene and from them, synthetic hydrocarbons and
their products. Thus, it essentially substitutes petroleum oil
and natural gas. It allows the lasting use of carbon-containing
fuels and materials and avoids excessive CO2emissions causing global warming (Olah et al., 2009b).
The methanol economy concept is based on the chemical
anthropogenic carbon cycle proposed byOlah et al. (2011).It
combines carbon capture and storage with chemical recycling.
While renewable feedstock such as water and CO2 are available in plenty, the energy required for the synthetic carbon
cycle can come from any alternative energy source such as
solar, wind, geothermal, and nuclear energy. According to
Olah et al. (2011), this cycle supplements the natural carbon
cycle and offers a way of assuring a sustainable future for
humankind when fossil fuels become scarce.
Interestingly, CO2 is non-toxic, non-corrosive and nonflammable and it can be easily stored in liquid form under
mild pressure. Therefore, the problem of process safety does
not appear in the case of CO2 application. Besides, the process can be easily integrated in existing syngas conversion
plants without any significant modification (Arakawa, 1998).
Feedstock CO2 is inexpensive and abundant. Existing and
proposed plants for carbon sequestration and storage (CSS)
are candidate sources of CO2. Other resources are flue gas
from coal-fired and natural gas-fired electric power plants,
gaseous streams in several industrial processes (such as
ammonia and hydrogen manufacturing, coal gasification,
WGS units, cement factories, aluminium production and fermentation plants) and CO2 accompanying natural gas and
geothermal energy producing wells. After effective separation from air (e.g., by membrane separation or selective
absorption technique), excess atmospheric CO2 offers another feasible alternative. When the appropriate conditions are
used, methanol synthesis by hydrogenation of atmospheric
CO2 is regarded as the most economic way after oil and gas
(Olah, 2005).
Even so, the sustainable and cost-effective production and
utilization of H2 is a major challenge (Raudaskoski et al.,
2009). Today, H2 is commercially produced by steam methane
reforming, coal gasification and partial oxidation of light oil
residues. As a result, fossil fuels are depleted and net atmospheric CO2 emissions are increased. Methanol production
from H2and CO2will be deemed as environmentally benign
only if this process utilizes CO2 more than that produced in H2
manufacturing.Raudaskoski et al. (2009)discussed other candidate methods for H2 production such as dry reforming and
electrolysis of water using renewable electrical energy. Clearly,
they have their limitations, e.g., high CO content of the syngas in dry reforming process and high electricity cost. Biomass
gasification together with WGS and biomass fast pyrolysis
coupled with steam reforming of the resulting bio-oil represent further renewable routes for producing H2. Yet another
potential route for H2 production is a thermo-chemical route
where the energy required for the splitting of water is supplied
by atomic energy or solar energy. Some representative reaction
schemes, namely, sulfur–iodine process and copper–chlorine
process are shown in Table 1. It is worthy of note that no carbon source, either from fossil- or biomass-origin, is used in the
thermoขchemical route. Even so, more work is essential before
one can deduce the best possible route for H2 production.