Using seaweed extracts to improve battery performance
An extract from brown algae could give rechargeable lithium-ion
batteries a boost by allowing silicon nanopowder to be used as a
high-capacity alternative to graphite electrodes.
Lithium-ion
batteries are ubiquitous in portable gadgets, such as laptops and mobile
phones because they are relatively lightweight and recharge rapidly.
However, energy-storage capacity and cycle-life are limited. As such,
researchers have experimented with alternatives to graphite, such as
silicon, for the anode, as their capacity could be an order of magnitude
higher.
Polymer binders might act as stabilisers, especially if they contain
multiple carboxy groups. Gleb Yushin of Georgia Institute of Technology,
US, points out that these polymers require conductive carbon additives
and have to be used in very large quantities. 'This lowers the
attractiveness of this technology,' he adds.
Now, Yushin and
colleagues have demonstrated that a natural polysaccharide, extracted
from oceanic brown algae - seaweed - can be mixed with a silicon
nanopowder to form a stable battery anode. The algal anode has a
reversible charging capacity eight times greater than even the best
available graphite-based anodes. The alginate binder improves electrode
integrity and protects the surface of silicon particles from
degradation.
'Water-soluble alginates are uniquely qualified for
this job,' says Yushin. 'So, we were quite surprised not to find any
reports of their use as electrode binders for batteries.' He adds that
inexpensive alginates are widely used in the pharmaceutical, biotech and
food industries and so are readily available. Yushin says it may be
possible to engineer a system to incorporate electrochemically active
nanoparticles into algae, or other aquatic plants, to directly grow
stable battery electrodes.
Tests on the new anode material showed
promise. 'Charge-discharge cycling performed with lithium insertion
capacity limited to 1200mAh per gram of silicon showed stable anode
performance for over 1300 cycles,' the researchers say.
John Owen
of the University of Southampton says this work should be viewed in the
context of other efforts to 'decorate' silicon for anodes. 'There are
many reports of silicon nanopowders cycling well with carboxymethyl
cellulose (CMC) as a binder,' he says, 'so I see nothing special about
algae.'
Mino Green of Imperial College London points out that
battery energy density, the capacity per unit weight or volume, remains
an important issue in enhancing lithium-ion batteries. 'Improving the
anode capacity alone only gives a limited battery capacity improvement,
because there is still the unimproved cathode that is heavy and bulky,'
he says. Significantly, such an improvement 'does not address the
important matter of cycle life, especially where binders are concerned.'
David Bradley
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