Secondary Cells (DP IB Chemistry)
Revision Note
Secondary Cells
Secondary Cells
Secondary / rechargeable cells employ chemical reactions which can be reversed by applying a voltage greater than the cell voltage, causing electrons to push in the opposite direction
There are many types of rechargeable cells, but common ones include:
Lead-acid batteries,
Nickel-cadmium / NiCad cells
Lithium cells
Lead-acid batteries
Lead-acid batteries consist of six cells joined together in series
The cells use lead metal as the negative electrode and lead(IV) oxide as the positive electrode
The electrolyte is sulfuric acid
A lead-acid battery
A lead acid battery is made by placing negative lead and positive lead dioxide electrodes into the sulfuric acid electrolyte
The half-cell reactions are
Pb (s) + SO42- (aq) → PbSO4 (s) + 2e- Eθ = -0.36 V
PbO2 (s) + 4H+ (aq) + SO42- (aq) + 2e- → PbSO4 (s) + 2H2O (l) Eθ = +1.70 V
The cell generates an EMF of about 2 V and the overall reaction is
PbO2 (s) + 4H+ (aq) + 2SO42- (aq) + Pb (s) → 2PbSO4 (s) + 2H2O (l) Eθcell = +2.06 V
In a commercial car battery, the six cells in series give a combined voltage of about 12 V
When the car is in motion, the generator provides a push of electrons that reverses the reaction and regenerates lead and lead(IV) oxide
Lead-acid batteries are designed to produce a high current for a short period of time, hence their use in powering a starter motor in car engines
The disadvantage of lead-acid batteries is that:
They are very heavy
They contain toxic materials: lead and lead(IV) oxide
The sulfuric acid electrolyte is very corrosive
This presents challenges of disposal when lead-acid batteries come to the end of their useful life
NiCad cells
Nickel-cadmium cells are available in many standard sizes and voltages so they can replace almost any application of traditional zinc-carbon cells
Although they are more expensive cells, the fact they can be recharged hundreds of times means they are commercially viable
The negative electrode consists of cadmium and the positive electrode is made of a nickel(II) hydroxide-oxide system
The half-cell reactions are
Cd (s) + 2OH- (aq) → Cd(OH)2 (s) + 2e- Eθ = -0.82 V
NiO(OH) (s) + H2O (l) + e- → Ni(OH)2 (s) + OH- (aq) Eθ = +0.38 V
The overall reaction in the cell is
2NiO(OH) (s) + 2H2O (l) + Cd (s) → 2Ni(OH)2 (s) + Cd(OH)2 (s) Eθ = +1.2 V
Cadmium is a toxic metal so the disposal of old NiCad cells is also an environmental issue
Lithium-ion cell
Lithium ion cells power the laptop or mobile device you are probably reading this on
The Noble Prize for Chemistry in 2019 was awarded to John B. Goodenough, M. Stanley Whittingham and Akira Yoshino for their work on lithium ion cells that have revolutionised portable electronics
Lithium is used because it has a very low density and relatively high electrode potential
The cell consists of:
A positive lithium cobalt oxide electrode
A negative carbon electrode
A porous polymer membrane electrolyte
The polymer electrolyte cannot leak since it is not a liquid or paste, which presents advantages over other types of cells
Lithium-ion cell
The lithium-ion cell consists of a positive lithium cobalt oxide electrode and a negative carbon electrode
The cell consists of a sandwich of different layers of lithium cobalt oxide and carbon
When the cell is charged and discharged the lithium ions flow between the negative and the positive through the solid electrolyte
The half-cell reactions on discharge are:
Li (s) → Li+ (s) + e– Eθ = -3 V
Li+ (s) + CoO2 (s) + e– → Li + (CoO2) – (s) Eθ = +1 V
The cell generates an EMF of between 3.5 V and 4.0 V and the overall reaction is
Li (s) + CoO2 (s) → Li + (CoO2) – (s) Eθcell ~ +3.5
NiCad cells have a problem called the memory effect in which they gradually begin to lose their charge after repeated charge cycles when the cell is not fully discharged. The cells appear to 'remember' their lower state of charge
Lithium-ion cells do not have this problem so can be topped up without any loss of charge
Some of the problems with lithium-ion cells:
A global shortage of lithium is likely to make lithium-ion cells unsustainable as the current demand for lithium exceeds the supply
If cells are not recycled but thrown away in landfills, then a huge amount of lithium becomes lost to future generations
Reports of lithium-ion cell fires have raised concern about the safety of these batteries in electronic devices; it is a reminder to us that lithium is a very reactive element in Group 1 of the periodic table, which is why it has a high electrode potential
Summary of primary and secondary cells
Type of cell | Advantages | Disadvantages | |
|---|---|---|---|
Primary | General | Inexpensive Lightweight Long shelf life | Single-use which increases landfill and causes environmental impacts Only delivers small currents |
Fuel cell | Reduced pollution if hydrogen used as fuel Hydrogen has a low density More efficient than combustion as more chemical energy converted to electrical energy | Safety issues with hydrogen gas Hydrogen must be transported using heavy containers Expensive Only delivers small currents Technical issues due to catalytic failures, leaks and corrosion | |
Rechargeable / secondary | General | Materials can be regenerated Can deliver high current |
|
Lead-acid | Can deliver large amounts of energy over short periods | Heavy mass Lead and sulfuric acid could cause pollution | |
Cadmium-nickel | Longer life than lead-acid batteries | Cadmium is very toxic Produces a low voltage Expensive | |
Lithium-ion | Low density of lithium No toxic heavy metals High voltage | Limited life span Expensive | |
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