New record for carbon dioxide capture
Researchers
from Monash University and the CSIRO have set a record for carbon dioxide
capture and storage (CCS) using technology that resembles a sponge filled with
tiny magnets.
Using a
Metal Organic Frameworks (MOFs) nanocomposite that can be regenerated with
remarkable speed and low energy cost, researchers have developed sponge-like
technology that can capture carbon dioxide from a number of sources, even
directly from air.
The
magnetic sponge is used to remove carbon dioxide using the same techniques as
induction cooktops using one-third of the energy than any other reported
method.
Associate
Professor Matthew Hill (CSIRO and Department of Chemical Engineering, Monash
University) and Dr Muhammad Munir Sadiq (Department of Chemical Engineering,
Monash University) led this research.
In the
study, published in Cell Reports Physical Science, researchers designed
a unique adsorbent material called M-74 CPT@PTMSP that delivered a record low
energy cost of just 1.29 MJ kg-1CO2 , 45 per cent below
commercially deployed materials, and the best CCS efficiency recorded.
MOFs are
a class of compounds consisting of metal ions that form a crystalline material
with the largest surface area of any material known. In fact, MOFs are so
porous that they can fit the entire surface of a football field in a teaspoon.
This
technology makes it possible to store, separate, release or protect valuable
commodities, enabling companies to develop high value products.
"Global
concerns on the rising level of greenhouse gas emissions and the associated
environmental impact has led to renewed calls for emissions reduction and the
development of green and renewable alternative energy sources," Associate
Professor Hill said.
"However,
existing commercial carbon capture technologies use amines like
monoethanolamine, which is highly corrosive, energy intensive and captures a
limited amount of carbon from the atmosphere.
"Our
research shows the lowest reported regeneration energy calculated for any solid
porous adsorbent, including monoethanolamine, piperazine and other amines. This
makes it a cheap method that can be paired with renewable solar energy to
capture excess carbon dioxide from the atmosphere.
"Essentially,
we can capture CO2 from anywhere. Our current focus is for
capture directly from the air in what are known as negative emissions
technologies."
For MOFs
to be used in CCS applications, it is essential to have materials that can be
easily fabricated with good stability and performance.
The
stability of M-74 CPT@PTMSP was evaluated by estimating the amount of CO2 and
H2O captured and released via the researchers' magnetic induction
swing adsorption (MISA) process over 20 consecutive cycles.
The
regeneration energy calculated for M-74 CPT@PTMSP is the lowest reported for
any solid porous adsorbent. At magnetic fields of 14 and 15 mT, the
regeneration energy calculated for M-74 CPT was 1.29 and 1.44 MJ kg CO2-1.
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