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Seven chemical separations to change the world
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The
separation of mixtures of chemicals into their components is amongst the most
significant processes carried out in the petroleum, refining and
petrochemical industries. Distillation – the most widely used of separation
technologies – is an energy-intensive operation making use of differences in
the boiling points of the components of a mixture in its most simplistic
version. As per some estimates, it accounts for anywhere between 10-15% of
global energy consumption.
It
is obvious that improvements to energy efficiency of distillation and/or the
use of alternative separation techniques that can do the job just as
effectively, if not better, while using less energy will have major implications
– both economic and environmental. In a world concerned about global warming
and its poorly understood impacts, reducing the carbon footprint of
separations has urgency like never before.
A
paper with the title ‘Seven chemical separations to change the world’
authored by two academicians – David Scholl and Ryan Lively from the Georgia
Institute of Technology (Nature, Vol 532, April 28, 2017, pp 435-437)
– provides a fascinating account of seven areas where alternate separation
technologies could have significant impacts.
Hydrocarbons
from crude oil
The
global refining industry processes around 9-mbpd (million barrels per day) of
crude oil, and atmospheric distillation is by far the most widely used
process in these plants. Globally, the industry consumes 230-GW of energy
annually for distillation – equal to the total energy consumption of the UK
in 2014.
Crude
oil is a complex mixture of hydrocarbons, compounds of sulphur &
nitrogen, and even metals. Importantly, not all oils are the same, and vary
in their physical and chemical properties. It is therefore for good reason
that distillation is the most favoured separation technology for carving out
crude oil into fractions that find use as fuel and chemical feedstock.
Finding
alternative technologies for separating crude oil into fractions is not easy.
Membrane-based separations offer the lure of lower energy consumption, but
little has so far been done to innovate materials that can separate many
families of molecules at the same time and at the high temperatures needed to
keep oil flowing. But the rewards of success can be huge!
Uranium from
seawater
Nuclear
power is widely seen as an important component of any strategy to decarbonise
energy production, despite legitimate concerns over its safety. While
geological reserves of uranium – the main fuel for nuclear reactors – is
limited to about 4.5-mt (enough to last about a century at current
consumption levels), the oceans are known to have more than 4-bn tonnes, but
at a concentration of a few parts per billion.
The
capture of uranium from seawater has been attempted by using porous polymers
containing amidoxime groups, but these also capture other metals like
vanadium, cobalt, nickel etc., and these need to be removed. The technologies
that can do this separation have been proven at a small scale but need to be
scaled up several times over to make an impact. Importantly, they can also be
used to capture other strategic materials such as lithium (increasingly used
in batteries).
Alkenes from
alkanes
The
separation of alkenes (e.g. ethylene, propylene, butenes etc.), more commonly
known as olefins, from alkanes – the saturated forms that are the main
constituents of natural gas – assumes importance for the sheer size of their
production. Global output of ethylene and propylene – the two simplest
alkenes – exceeds 200-mt each and they are the fundamental building blocks on
which a very large petrochemical industry is based. Alkenes are separated
from alkanes by high-pressure cryogenic distillation at low temperatures
(-160°C), and purification of just ethylene and propylene is estimated to
account for 0.3% of global energy use – roughly the same as that consumed
annually in Singapore.
Alternatives
being investigated include using porous carbon membranes that can carry out
the separation in the gas phase – avoiding energy-intensive liquefaction –
and at mild pressures (less than 10-bar). The challenge that still needs to
be overcome is that the purity of the alkenes so produced does not exceed
99.9% – the level needed for making polyolefins. An intermediate approach
could be a combo-system wherein membranes do the first stage of separation
and cryogenic distillation does the ‘polishing’ to take purity of the alkene
stream to the desired level. The impacts of even these will be very
significant: a reduction in energy consumption by a factor of two or three. A
major hurdle, however, is the scaling up of membranes – industrial
requirements could be as high as 1-mn square metres of membrane surface area!
This will call for whole new technologies to prepare these membranes.
Greenhouse gases
from dilute emissions
The
anthropogenic emissions of carbon dioxide (CO2) and other
greenhouse gases (such as methane) are significant contributors to climate
change. CO2 is commercially captured from dilute gaseous
streams by absorbing it in liquids such monoethanolamine, but the process of
recovery of the pure CO2 requires heat and is therefore not
economically viable for power plants – one of the major sources of CO2.
If every power plant in the US, for example, were to use this technique,
their incremental cost would be 30% of the growth in that country’s GDP –
clearly impractical. What is needed is a simpler, less energy-intensive way
of capturing CO2 and other hydrocarbons.
But
even if such a technology were to be developed there remains the challenge of
gainful utilisation of the captured CO2. Existing applications –
conversion to carbonates, urea, polyols etc. or use for enhanced oil recovery
– can absorb just a tiny fraction and the only practical option seems to be
to sequester CO2 in underground reservoirs, which raises its
own set of issues.
Rare earth
metals from ores
The
rare earths – the 15 elements that constitute the lanthanide series – have
become commercially very important due their indispensible use in magnets,
for renewable energy and as catalysts in petroleum refining. They are not
rare – indeed they are more plentiful in the earth’s crust than silver, gold,
platinum and mercury – but their isolation from ores is economically and
environmentally challenging. The current technologies are a combination of
mechanical (e.g. magnetic separation) and chemical (e.g. froth floatation)
processes, but these are inefficient, and produce large amounts of waste (some
of which is radioactive).
Recycling
techniques are needed to recover rare earths from products after their useful
life, but the low dosage in which they are present poses technical
challenges.
Benzene
derivatives from each other
Benzene
and its derivatives – xylenes, toluene and ethylbenzene (in decreasing order
of importance) – are the starting raw material for many polymers, fibres,
solvents and fuel additives. These aromatics are today separated by
distillation, and the combined energy consumption for this task is estimated
at about 50-GW – enough to power 40-mn homes.
Of
particular importance is the separation of xylenes into its isomers – ortho, para and meta xylene. para-Xylene
is the key raw material for making polyesters that finds use as fibre, film
and bottle. The separation of the mixed xylenes into its constituents by
distillation is challenging – the isomers have the same molecular weights and
their boiling points are close. Membrane separation or use of sorbents have
been touted as alternatives, but they will need to be demonstrated on a much
larger scale to find broad industrial acceptance.
Trace
contamination from water
Supplying
pure water for industrial or potable use is a multi-billion dollar business
worldwide, but the technological options to desalinate water are limited to
two: thermal desalination by distillation and membrane separation.
Distillation uses 50 times more energy than dictated by thermodynamics. In
contrast, reverse osmosis – that applies pressure across a membrane to salty
water to produce pure water – uses just 25% more energy than the
thermodynamic limit. But RO technologies are limited in the rate at which
they can produce water, which means that a considerable flow of water can
only be obtained by a significant scale-up (which adds to capex).
Pre-treatment of the water is also needed, lest the impurities present damage
the membranes.
The
key innovations needed are more resilient membranes – ones that do not foul
and do not have to be replaced as often as is now the case.
Change in training and emphasis
The
authors contend that tackling the above separation challenges will need
changes in the training of chemists and chemical engineers. The current
emphasis on distillation in academic training needs to be broadened to
include other options such as adsorption, crystallisation and membranes to
develop a more broadly skilled workforce.
They
also urge an early consideration of the scale at which eventual deployment of
any new technology is likely to be and a comprehensive evaluation of
economics and sustainability early in technology development.
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Ravi
Raghavan CHWKLY 3OCT17
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