Lithium-Ion Battery
+___________________________
Nano-technology
An Overview of the battery technology that powers our
mobile society.
Name: H IZHAN AHMED
Reg. No: 21BCB0007
Battery History and Basics
The modern battery was developed by Italian physicist
Alessandro Volta in 1800.
Ingredients: Zinc, Saltwater paper, and Silver
An electrochemical reaction.
The “Voltaic Pile”
The Voltaic Pile
Battery Chemistry 101
Electrochemical reaction - a chemical reaction
between elements which creates electrons.
Oxidation occurs on the metals (“electrodes”), which
creates the electrons.
Electrons are transferred down the pile via the
saltwater paper (the “electrolyte”).
A charge is introduced at one pole, which builds as it
moves down the pile.
Primary vs. Secondary
Batteries
Primary batteries are disposable because their
electrochemical reaction cannot be reversed.
Secondary batteries are rechargeable, because
their electrochemical reaction can be reversed by
applying a certain voltage to the battery in the
opposite direction of the discharge.
Standard Modern Batteries
Zinc-Carbon: used in all inexpensive AA, C and D dry-cell
batteries. The electrodes are zinc and carbon, with an
acidic paste between them that serves as the electrolyte.
(disposable)
Alkaline: used in common Duracell and Energizer
batteries, the electrodes are zinc and manganese-oxide,
with an alkaline electrolyte. (disposable)
Lead-Acid: used in cars, the electrodes are lead and leadoxide, with an acidic electrolyte. (rechargeable)
Battery types (cont’d)
Nickel-cadmium: (NiCd)
✓
rechargeable,
✓
“memory effect”
Nickel-metal hydride: (NiMH)
✓
rechargeable
✓
no “memory effect”
Lithium-Ion: (Li-Ion)
✓
rechargeable
✓
no “memory effect”
Recharge-ability & the
“memory effect”
Recharge-ability: basically, when the direction of
electron discharge (negative to positive) is
reversed, restoring power.
the Memory Effect: (generally) When a battery is
repeatedly recharged before it has discharged
more than half of its power, it will “forget” its
original power capacity.
Cadmium crystals are the culprit! (NiCd)
Lithium
Periodic Table Symbol: Li
Atomic Weight: 3 (light!)
Like sodium and potassium, an alkali metal.
(Group 1 – #s 1 through 7)
Highly reactive, with a high energy density.
Used to treat manic-depression because it is
particularly effective at calming a person in a
“manic” state.
The Periodic Table
➔➔
Lithium (Ion) Battery
Development
In the 1970’s, Lithium metal was used but its
instability rendered it unsafe and impractical.
Lithium-cobalt oxide and graphite are now used
as the lithium-Ion-moving electrodes.
The Lithium-Ion battery has a slightly lower energy
density than Lithium metal, but is much safer.
Introduced by Sony in 1991.
Advantages of Using
Li-Ion Batteries
POWER – High energy density means greater power in a
smaller package.
160% greater than NiMH
220% greater than NiCd
HIGHER VOLTAGE – a strong current allows it to power
complex mechanical devices.
LONG SHELF-LIFE – only 5% discharge loss per month.
✓
10% for NiMH, 20% for NiCd
Disadvantages of Li-Ion
EXPENSIVE -- 40% more than NiCd.
DELICATE -- battery temp must be monitored from
within (which raises the price), and sealed
particularly well.
REGULATIONS -- when shipping Li-Ion batteries in
bulk (which also raises the price).
Class 9 miscellaneous hazardous material
UN Manual of Tests and Criteria (III, 38.3)
Environmental Impact of
Li-Ion Batteries
Rechargeable batteries are often recyclable.
Oxidized Lithium is non-toxic, and can be
extracted from the battery, neutralized, and used
as feedstock for new Li-Ion batteries.
The Intersection
“In terms of weight and size, batteries have become one of
the limiting factors in the development of electronic devices.”
http://www.nanowerk.com/spotlight/spotid=5210.php
“The problem with...lithium batteries is that none of the
existing electrode materials alone can deliver all the required
performance characteristics including high capacity, higher
operating voltage, and long cycle life. Consequently,
researchers are trying to optimize available electrode
materials by designing new composite structures on the
nanoscale.”
“Nano”-Science and
-Technology
The attempt to manufacture and control objects
at the atomic and molecular level (i.e. 100
nanometers or smaller).
1 nanometer = 1 billionth of a meter (10-9)
1 nanometer : 1 meter :: 1 marble : Earth
1 sheet of paper = 100,000 nanometers
Nano S & T (cont’d)
Nano-science: research of the differing
behavioral properties of elements on the nano
scale.
Conductivity (electric/thermal), strength,
magnetism, reflectivity.... Sometimes these
properties differ on the nanoscale.
Carbon is particularly strong on the nano
scale.
C60 = “Fullerene,” a.k.a “buckyball”
Nano S & T (cont’d)
Nano-technology: the use of nanoscale materials in
critical dimensions of mechanical devices.
Nanotubes -- carbon molecules have greater
mechanical strength at less weight per volume.
Nanotransistors -- the computer industry’s best
technology features microchips with transistors as
small as 45nm.
Batteries with nanoscale materials deliver more power
quickly with less heat.
Environmental Impacts and
Use of Nanotechnology
Smaller scale technology means less resources
used and less waste.
The EPA recently issued research grants to use
nanotechnology to develop new methods of
detecting toxins in water.
An example of the
intersection...
From graphite to metallic tin (electrodes), but metallic
tin isn’t great either…yet.
“...the biggest challenge for employing metallic tin...is
that it suffers from huge volume variation during the
lithium insertion/extraction cycle, which leads to
pulverization of the electrode and very rapid capacity
decay."
But nanotechnology could offer a solution...
The Director of the Institute of Chemistry at the
Chinese Academy of Sciences published a paper in
February describing the novel carbon
nanocomposite above as “a promising [electrode]
material for lithium-ion batteries.”
Another example...
“The storage capacity of a Li-Ion battery is limited
by how much lithium can be held in the battery's
anode, which is typically made of carbon. Silicon
has a much higher capacity than carbon, but also
has a drawback.”
“Silicon placed in a battery swells as it absorbs
positively charged lithium atoms during charging,
then shrinks during use as the lithium ion is drawn
out of the silicon. This cycle typically causes the
silicon to pulverize, degrading the performance of
the battery.”
The Nano-technology
solution...
“The lithium is stored in a forest of tiny silicon
nanowires, each with a diameter one onethousandth the thickness of a sheet of paper. The
nanowires inflate to four times their normal size as
they soak up lithium but, unlike other silicon
shapes, they do not fracture.”
See next slide…
•
Photos taken by a scanning electron microscope of silicon
nanowires before (left) and after (right) absorbing lithium. Both
photos were taken at the same magnification. The work is
described in “High-performance lithium battery anodes using
silicon nanowires,” published online Dec. 16 in Nature
Nanotechnology.
The Potential of Li-Ion
Batteries
Electrodes that don’t deteriorate
metallic tin with carbon hollow spheres
silicon nanowires
2D & 3D battery design
“Forested” rods on a thin film electrode
“Stacked” rods in a truck bed
Nano + Li-Ion = ?
Nanotechnology and Li-Ion applications in the
commercial sector are apparent...
lighter, more powerful batteries increase user
mobility and equipment life.
DeWalt 36volt cordless power tools
Nanotechnology & Li-Ion applications in the
residential sector are not so obvious...
HVAC system batteries? Micro-generated
energy storage?
Micro-Generated
Energy Storage
Li-Ion batteries’ high energy density allows
batteries them to power complex machinery.
Li-Ion batteries recharge quickly and hold their
charge longer, which provides flexibility to the
micro-generator.
particularly helpful for wind and solar
generators!
Lightness, and power per volume allow for storage
and design flexibility.
Finally, an interesting idea...
Background:
battery research results in annual capacity
gains of approximately 6%
Moore’s Law: The number of transistors on a
computer microchip will double every two
years. (40 years of proof!)
Idea: If battery technology had developed at the
same rate, a heavy duty car battery would be the
size of a penny.
Links to References
http://electronics.howstuffworks.com/battery.htm
http://everything2.com/e2node/Lithium%2520ion%2520battery
http://www.batteryuniversity.com
http://news-service.stanford.edu/news/2008/january9/nanowire010908.html
http://www.nano.gov/html/research/industry.html
http://en.wikipedia.org/wiki/Buckminster_Fuller
http://www.nanowerk.com/spotlight/spotid=5210.php