Download Topic 0991 Electrochemical Units Electric Current The SI base

yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the work of artificial intelligence, which forms the content of this project

Document related concepts

Maxwell's equations wikipedia, lookup

History of electromagnetic theory wikipedia, lookup

Electric charge wikipedia, lookup

Electrical resistivity and conductivity wikipedia, lookup

Electrostatics wikipedia, lookup

Electrical resistance and conductance wikipedia, lookup

Topic 0991
Electrochemical Units
Electric Current
The SI base electrical unit is the AMPERE which is that constant electric current
which if maintained in two straight parallel conductors of infinite length and of
negligible circular cross section and placed a metre apart in a vacuum would produce
between these conductors a force equal to 2 x 10-7 newton per metre length. It is
interesting to note that definition of the Ampere involves a derived SI unit, the
newton. Except in certain specialised applications, electric currents of the order
‘amperes’ are rare. Starter motors in cars require for a short time a current of several
When a current of one ampere passes through a wire about 6.2 x 1018 electrons pass
a given point in one second [1,2].
The coulomb (symbol C) is the electric charge which passes through an electrical
conductor when an electric current of one A flows for one second.
Thus [C] = [A s]
Electric Potential
In order to pass an electric current thorough an electrical conductor a difference in
electric potential must exist across the electrical conductor. If the energy expended by
a flow of one ampere for one second equals one Joule the electric potential difference
across the electrical conductor is one volt [3].
Electrical Resistance and Conductance
If the electric potential difference across an electrical conductor is one volt when the
electrical current is one ampere, the electrical resistance is one ohm, symbol Ω [4].
The inverse of electrical resistance , the conductance, is measured using the unit
siemens, symbol [S]. [4]
Ohm’s Law
This famous phenomenological law describes the ability of a system to conduct
electrical charge. This law describes the relationship between three properties of an
electrical conductor; e.g. a salt solution. The three properties are (i) electric current I
described using the SI unit , ampere, symbol A; (ii) electric potential difference V
across the electrical conductor using the SI unit , volt, symbol V; and (iii) electrical
resistance R measured using the SI unit, ohm, symbol Ω.
Thus V = I ⋅ R
Ohm’s Law is a phenomenological law in that it describes the phenomenon of
electrical conductivity. Unlike the laws of thermodynamics, there are exceptions to
Ohm’s law for very high voltages and high frequency alternating electric currents.
The (electrical) conductance G of a system is given by the inverse of its resistance
R. The conductivity κ ( ≡ σ) of a system is given by equation (c) [5].
j = κ⋅E
Here j is the electric current density and E is the electric field strength. Chemists
prefer to think in terms the charge carrying properties of a given system; i.e. the
conductance G (=1/R) using the unit siemens, symbol S [5].
An interesting contrast often emerges between chemists and physicists, the latter
seem to emphasise the property of ‘resistance’ whereas chemists are more interested
in how systems transport electrical charge. Certainly the classic subject in chemistry
concerns the electrical conductivities of salt solutions where the charge carriers are
ions. The subject is complicated by the fact that there are two types of charge carriers
in a given solution, cations and anions. Moreover the subject is further complicated by
the fact that these charge carriers move in opposite directions with different velocities.
In a solution containing a single salt the fraction of electric current carried by the
cations and anions are called transport numbers; i.e. t+ and t- respectively for cations
and anions where t + + t − = 1 .
Ionic Mobility
A given aqueous salt solution, volume V, is prepared using n1 moles of water and nj
moles of a salt j. A pair of electrodes is placed in the solution, d metres apart. An
electric potential, V volts, is applied across the solution and an electric current I is
recorded. An electric charge Q coulombs (= [A s]) is passed through the solution.
The electric current (unit [A]) is the rate of transport of charge, dQ/dt.
The speed of ion i through the solution vi is given by the ratio of the distance
travelled to the time taken. Thus vi is a measure of the distance travelled in one
second; v = (a / t ) [m s -1 ]. A more interesting property is the velocity of ion i in an
electric field gradient measured using the ratio, volt/metre (Or, V/m). Thus electric
mobility ui has the unit, [m s-1/V m-1] = [ v i E -1 ] = [m 2 s -1 V -1 ]
The molar conductivity Λ of a salt solution is given by the ratio,
( κ / c j ) {= [S m 2 mol -1 ]} . In fact the majority of research publications describe the
dependence of Λ on the concentration of salt in a specified solvent at defined T and
p. For salt solutions both cations and anions contribute to Λ ; the transport number of
an ion j describes the fraction of current carried by the j ion.
Thus t j = z j ⋅ c j ⋅ v j / ∑ z i ⋅ c i ⋅ v i
An electric current (i.e. a flow of electric charge) through a system is impeded by the
electrical resistance. The ohm (symbol Ω) is the unit of electrical resistance being the
ratio of electric potential (unit = volt) to electric current (unit = ampere)
Then, ohm = volt/ampere
In other words,
Electrical resistance/ohm=[electric potential gradient /volt]/[electric current/ampere] .
From equation (c)
ohm (symbol Ω) = V A-1 = m2 kg s-3 A-2
The property (electrical) resistance is a measure of the impedance to the flow of
electric charge. This somewhat negative outlook is not consistent with the attitude of
chemists who are interested in the ‘mechanism’ by which a system conducts
electrical charge. Chemists prefer to discuss the property of electric conductance
rather than resistance. The conductance is measured using the unit siemen, symbol S
[6]. A key component of electrical circuits is the electrical capacitance measured
using the unit farad, symbol F [7].
If the composition of an electrical conductor is uniform, the electrical resistance is
directly proportional to its length l and inversely proportional to its cross sectional
area, a. The material forming the conductor is characterised by its resistivity, ρ.
Thus[8] resistance, R = ρ ⋅ l / a
[1] The electric charge on an electron = 1.602 x 10-19 C = 1.602 x 10-19 A s
A given single wire carries a current of 1 ampere.
Then in one second, the electric charge carried by that wire = 1.602 x 10-19 C
For one coulomb to pass a given point,
the number of electrons passing =
1.602 x10 −19
In other words 6.24 x 1018 electrons pass by.
[2] P.W. Atkins and L. Jones, Chemistry; Molecules, Matter and Change,
W. H. Freeman, New York, 1997,p.658.
[3] [V] ≡ [kg m 2 s -3 A -1 ] = [J A -1 s -1 ]
[Ω] = [V A -1 ] = [S −1 ]
κ = [S m -1 ]
[A m -2 ] = κ ⋅ [V m -1 ]
[6] S = Ω −1
[7] F = A 2 s 4 kg -1 m -2 = A s V -1 = C V -1
[8] [S] ≡ [Ω -1 ] ≡ [A V -1 ] ≡ [m -2 kg -1 s 3 A 2 ]
[Ω] = [Ω m] ⋅ [m] ⋅ [m]-2