Material and electrolyte
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Transcript of Material and electrolyte
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Material and electrolyte for pseudocapacitor
Faridah Hanum Bt Hj Anuar SA10069
Rabiatul Adawiyah Bt Muslim SA10079
Nurul Ain Bt Ahmad Zamri SA10097Izzati Bt Ahmad Fuad SA10045Nurul Najwa Bt Mustafa
SA10100
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SILVER-DOPED MANGANESE OXIDE PSEUDOCAPACITOR
ELECTRODES
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SPECIALITY OF MnO2
More practical
Inexpensive Pseudocapacitive
Material
Exhibits theoretical specific
capacitance of approximately
1,100 Fg through stochiometric
reduction of MnO2 to MnOOH in a
potential window of 1V
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BUT!!
The capacitance for thick MnO2
film is ultimately limited by the
poor electrical conductivity of
MnO2
The stability of EC in the thin
MnO2 film configuration is
restricted because of low mass
loading
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How To Overcome The Problems?
To overcome the electrical resistance of
MnO2, Silver (Ag) was incorparate into
MnO2 thin films.
Why?
Ag mass loading was accomplished
using cathodic eletrodeposition which
lead to higher specific capacitance
compare to pure MnO2 films
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EXPERIMENTAL
1. CHEMICALS AND MATERIALS
2. ELECTRODEPOSITION
3. STRUCTURAL AND MORPHOLOGICAL CHARACTERIZATION
4. ELECTROCHEMICAL EVALUATION
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CHEMICAL STRUCTURE OF Ag-Doped MnO2
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1. CYCLIC VOLTAMETRY
ELECTROCHEMICAL EVALUATION
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2.ELECTROCHEMICAL IMPENDANCE SPECTROSCOPY
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MATERIAL 2Ruthenium
Oxides Materials
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Ruthenium Oxides Materials
About :
High theoretical specific capacitance : 1358 F g-1
High electrical conductivity : 3Å~102 Ω-1 cm‑1
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Ruthenium Oxides Materials Amorphous hydrous RuO2 prepared
by sol-gel methods with Specific capacitance of 720 F g-1 High capacitance is attributed to
hydrous surface layers that enable facile transport of electrons and protons
The capacitance decreased rapidly at higher rates due to proton depletion and over-saturation in the electrolyte during charge-discharge cycling
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A two-dimensionally controlled RuO2 nano-sheet was invented for better electronproton transport
How to improve the rate performance?
Small particles of hydrous RuO2 can combine with carbon materials, such as with activated carbons,12-15 carbon black (CB),16 and CNTs.
Improve the rate capability of hydrous RuO2.
Ruthenium Oxides Materials
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Ruthenium Oxides Materials
Figure 1 : Proposed pseudocapacitor materials in the literature.
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Ruthenium Oxides MaterialsConclusion
ECs based on RuO2 and other oxides including MnO2 and NiO are better configured in aqueous media and some of them are being investigated for miniaturized devices because of their cost effectiveness.
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SOLID ELECTROLYTE Composed of RbAg4I5
increase energy storage without causing dendrite growth
serves as an ionic conductor for the ionic part of the current
within
solid - state cell
Conductivity Range = 10-3 S/cm <σ< 10 S/cm
Ions carry the current
Conductivity decreases exponentially as temperature
decreases
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GENERAL CHARACTERISTICS : SOLID ELECTROLYTES1. A large number of the ions of one species should be mobile. This
requires a large number of empty sites, either vacancies or accessible interstitial sites. Empty sites are needed for ions to move through the lattice.
2. The empty and occupied sites should have similar potential energies with a low activation energy barrier for jumping between neighboring sites. High activation energy decreases carrier mobility, very stable sites (deep potential energy wells) lead to carrier localization.
3. The structure should have solid framework, preferable 3D, permeated by open channels. The migrating ion lattice should be “molten”, so that a solid framework of the other ions is needed in order to prevent the entire material from melting.
4. The framework ions (usually anions) should be highly polarizable. Such ions can deform to stabilize transition state geometries of the migrating ion through covalent interactions.
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OTHER SOLID ELECTROLYTE MATERIALSNAFION ®
Tetra methylammonium penta hydrate (also known
as hydrated TMAH5 )Li+ Ion Conductors
LiCoO2, LiNiO2
LiMnO2
Lithium aluminium oxide (Li5AlO4) F- Ion Conductors
PbF2 & AF2 (A = Ba, Sr, Ca)
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SOLID ELECTROLYTE ADVANTAGES
- Freedom from fluid leakage
- Low ionic conductivities- Feasibility of small layer
thickness- Can be deeply discharged
many times- Long lifetime : high or low
temperature
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LIQUID ELECTROLYTE BATTERY
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INTRODUCTION
A battery containing a liquid solution of acid and water.
Other names are flooded cell and wet cell battery
2 different types:i.primary battery-non
rechargeableii.secondary battery-
rechargeable
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Example: Lead acid battery
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An electrical storage device that uses a reversible chemical reaction to store energy.
It uses a combination of lead plates or grids and an electrolyte consisting of a diluted sulphuric acid to convert electrical energy into potential chemical energy and back again.
The electrolyte of lead-acid batteries is hazardous to our health and may produce burns and other permanent damage if we come into contact with it.
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DISCHARGEThe discharge process is driven by the
conduction of electrons from the negative plate back into the cell at the positive plate in the external circuit.
Negative plate reaction: Pb(s) + HSO−4(aq) → PbSO4(s) + H+
(aq) + 2-e Positive plate reaction:
PbO2(s) + HSO−4(aq) + 3H+(aq) + 2-e → PbSO4(s) + 2H2O(l) The total reaction can be written:
Pb(s) + PbO2(s) + 2H2SO4(aq) → 2PbSO4(s) + 2H2O(l)
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Charging
The charging process is driven by the forcible removal of electrons from the positive plate and the forcible introduction of them to the negative plate by the charging source.
Negative plate reaction: PbSO4(s) + H+(aq) + 2-e → Pb(s) + HSO−4(aq)
Positive plate reaction: PbSO4(s) + 2H2O(l) → PbO2(s) + HSO−4(aq) + 3H+(aq) + 2-e
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ADVANTAGE
Low cost. Reliable. Over 140 years of
development.Robust. Tolerant to abuse.Tolerant to overcharging. Low internal impedance.Can deliver very high currents. Indefinite shelf life if stored without
electrolyte. Can be left on trickle or float charge for
prolonged periods. Wide range of sizes and capacities
available.Mature secondary batteriesGlobally manufactured
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DISADVANTAGES
Very heavy and bulky.
Danger of overheating during
charging
Not suitable for fast charging
low energy density
Cause environmental damage,
which is environmentally
unfriendly.
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Ionic Liquid
ELECTROLYTE
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Ionic liquidDefined as salts consisting entirely of ions
i) melting points lower than 100 °C - ionic conductivity is very high.
ii) very low vapor pressures- are not flammable, even if they consist of organic compounds.
Two class of ionic liquid :i) aprotic or conventionalii) protic ionic liquids (PILs).
- generally prepared by a neutralization reaction of an organic base like amine and an acid.
- If both are strong enough, proton transfer from the acid to the base occurs.
- Depending on the strength of the acid and base the degree of proton transfer changes.
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Ionic liquid ElectrolyteMost common cation classes of ionic
liquids are i. Quaternary ammoniumii. Imidazolium, iii. Pyridiniumiv. Phosphonium
Physico-chemical propertiesi. Viscosityii. solubility propertiesiii. densityiv. acidity/basicityv. coordination propertiesvi. stereochemistry
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Importance of ionic liquid
Melt at ambient temperature
Because ionic liquids are composed of only
ions, they show very high ionic conductivity,
non-volatility, and non-flammability.
The non-flammability and non-volatility
inherent in ion conductive liquids open new
possibilities in other fields as well.
multi-purpose materials, so there should be
considerable
(and unexpected) applications.
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Viscosity physico – chemical propertiesViscosity of Imidazolium-Based Ionic Liquids
at Elevated Pressures : Cation and Anion
Effects by Azita Ahosseini and Aaron M.
Scurto
Ionic liquid used : Imidazolium – based
Common cation classes and anions used with ionic liquids.
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Schematic diagram to test the viscosity using viscometer
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(c) Modified TiO2 nanoparticles. (d) Diffusion of I3-through a matrix of (A) modified
and (B) unmodified TiO2 nanoparticles.
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Proposed process for the extraction of cesium from aqueous tank waste using n-Bu3MeNNTf2
- + BOBCalixC6.
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Advantages of ionic liquid It is possible to “engineer” the
physicochemical properties of RTILs by the
choice of the ionic constituents.
use of these liquids as electrolytes for Li
batteries and low-temperature fuel cells.
The non-volatile electrolyte solution will
change the performance of electronic and
ionic devices.
will be composed of organic ions, and these
organic compounds will have unlimited
structural variations because of the easy
preparation of many components.
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Disadvantage of ionic liquidThe benefits of replacing the volatile
organic solvent component far
outweigh this disadvantage.
Low electrolytic conductivity
Need of tight closure to isolate from
atmospheric moisture
High environmental impact
High cost