Equations (NOT IN DATA BOOK)

Question 1

equation for a dipole moment

Answer 1

μ = qr
(vector)

Question 2

give the two equations for polarisation (dipole moments and charge)

Answer 2

P = n μ
P = Q/A
(vector)

Question 3

give the 2 equations for resultant charge density (displacement fields)

Answer 3

D = εo E + P
(E = electric field, P = polarisation)

D = ε E = k εo P

Question 4

give the equation for the change in voltage due to stress on a piezoelectric material

Answer 4

ΔV = dσL /ε = dσL / k*εo

d = piezoelectric constant

Question 5

give the equation for the change in voltage due to a change in temperature for a pyroelectric material

Answer 5

ΔV = ΔQL / kεoA = pΔT L / k εo

p = pyroelectric constant

Question 6

give the Goldschmidt tolerance factor, what should it equal

Answer 6

t = (rA + ro) / (sqrt(2)*(rB + ro))

it should equal 1

Question 7

give the equation for the number of diffusing ions in an electric field (Boltzmann stats)

Answer 7

n = no exp(-qv/kt)

k = Boltzmann constant
q = charge on ion
V = voltage
T = temp

Question 8

give the equation derived from the number of diffusing ions in an electric fields for the conc. gradient

Answer 8

dn/dx = -qn/KT dv/dx = qn/KT E

Question 9

give the thin lens equation for optical microscopes

Answer 9

1/f = 1/u + 1/v

Question 10

give the equation for maxima spacing from a double slit

Answer 10

x = lλ/d

l = distance to slits from screen
λ = wavelength
d = slit spacing

Question 11

give the general equation for the phase difference from scattering from the nth atom in a structure (in terms of its coords)

Answer 11

ϕn = 2π (h xn + k yn + l zn)

(xn,yn,zn) are the coords of the nth atom

Question 12

give the equation for the multiplicity of a plane (hkl)

Answer 12

M(hkl) = (3!)(2^A) / (n!)

A = number of non-zero indices
n = number of repeated indices

Question 13

give the equation for the intensity of a peak intensity for a plane (hkl)

Answer 13

I(hkl) α M(hkl) |F(hkl)|^2 g(θ)

where g(θ) increases with θ

Question 14

give the equation for the distance between two points representing planes in reciprocal space in terms of the real spacing of the planes

Answer 14

|d(hkl)*| = 1/|d(hkl)|

Question 15

give the equation for determining the planar spacing from a diffraction pattern from a TEM

Answer 15

d(hkl) = λL/R

λ = wavelength of electrons
L = distance from specimen to detector
R = distance on detector from origin to spot

Question 16

give the equation for internal energy (differential in three forms, one at constant volume)

Answer 16

dU = δq + δw
dU = CdT - pdV

at const, vol
dU = C(v)dT

Question 17

give the equation for absolute internal energy at a given temperature

Answer 17

U = Uo + ∫CvdT (0 to T1) + Σli (on i)

where li is the ith latent heat of transition

Question 18

give the non differential AND differential forms of enthalpy, H

give the equation for enthalpy at a constant pressure

Answer 18

H = U +PV
dH = δq + Vdp

dH = δq = C(p) dT
at a const. pressure

Question 19

give the equation for absolute enthalpy at a given temperature

Answer 19

H = Ho + ∫CpdT (0 to T1) + Σli (on i)

where li is the ith latent heat of transition

Question 20

give the non-differential form for G

Answer 20

G = H - TS

Question 21

give the starting equation for ΔHmix

Answer 21

ΔHmix = Hs - Hmm

Hs = enthalpy of the solution
Hmm = enthalpy of the mechanical mixture

Question 22

give the equation for the enthalpy of a solution of one mole of atoms

Answer 22

Hs = (NA*Z / 2) ( XA^2 EAA + XB^2 EBB + 2 XA XB EAB)

Question 23

give the equation for the enthalpy of a mechanical mixture

Answer 23

Hmm = (NA*Z / 2) (XA EAA + XB EBB)

Question 24

using the equations for Hmm and Hs give the final equation for ΔHmix

Answer 24

ΔHmix = Hs - Hmm = (NA*Z /2) XA XB (2EAB - EAA - EBB) = XA XB ψ

Question 25

give the defining equation for entropy

Answer 25

S = k ln(w)

Question 26

what are the equations for the number of distinguishable ways to arrange NA particles in a mechanical mixture and a solution

Answer 26

Ωmm = 1
(A atoms on A sites, B atoms on B)

Ωs = NA! / ((XANA)! ((1-XA)NA)!)

Question 27

give the expression for ΔSmix and give the final equation for ΔSmix, roughly explain how to get from one to the other

Answer 27

ΔSmix = kln(Ωs) - kln(Ωmm) = kln(Ωs)

once the Stirling approximation has been used this gives

ΔSmix = -R(XA ln(XA) + XB ln(XB))

Question 28

by combining the two expressions for ΔSmix and ΔHmix, give the overall equation for ΔGmix

Answer 28

ΔGmix = ΔHmix - TΔSmix

= XA XB ψ + RT(XA ln(XA) + XB ln(XB))

Question 29

give Ficks second law, when is it used

Answer 29

∂C/∂t = D ∂^2C/ ∂x^2

where D = diffusivity
C = conc.

Question 30

give the equation for the driving force/change in free energy
for the nucleation of a new phase

Answer 30

ΔG = ΔS(Te - T)
where Te is the equil. temp

Question 31

give the expression for the work of nucleation (assuming the nucleus that forms is a sphere) and the work of nucleation if we include a strain term

Answer 31

Wn = (4/3)πr^3 ΔGv + 4π r^2 γ
excluding strain

Wn = (4/3)πr^3 (ΔGv + U) + 4π r^2 γ
where U is the strain energy per unit vol.

Question 32

from the equations for work done in nucleation what are the equations for critical nucleus radius and critical work done

Answer 32

r* = -2γ / ΔGv

Wn* = (16π/3) (γ^3 / (ΔGv)^2)

Question 33

when considering homogeneous nucleation, what are the two terms that we must consider, give the equations that each of these are given by and hence the equation for nucleation frequency, I

Answer 33

1) population of critical nuclei
prop. to exp(-(Wn*/ kT))

2) rate at which particles can add to make nuclei post-critical
prop. to exp(-(Q/kT))

overall
I = Cn exp( - ((Wn*+Q)/kT) )

Question 34

give the relationship between critical work done for heterogenous nucleation and critical work done for homogenous nucleation

Answer 34

Wnhetero = Wnhomo((2+cosθ)(1-cosθ)^2) /4)

Question 35

give the equation for the growth rate of a new phase

Answer 35

• the growth rate of a new phase is given by

ν = Cg exp(-Q/KT)(1 - exp(VaΔGv / KT))

Cg = const.
Q = activation energy
K = Boltz. const.
T = temp
Va = vol of atom
ΔGv = driving force per unit vol.

Question 36

give the equation (relating to TTT diagrams) for the critical rate of cooling to NOT form the phase in question for the TTT diagram

Answer 36

critical rate of T = ΔT(nose)/t(nose)

t(nose) = time at nose of 0% curve

Question 37

give the equation for engineering stress

Answer 37

σ(eng) = F/Ao

Ao = init. cross-sectional area

Question 38

give the equation for engineering strain

Answer 38

ε(eng) = li/lo - 1
li = final length
lo = init. length

Question 39

give the equation for shear stress

Answer 39

τ = F/Ao

Question 40

give the equation for shear strain

Answer 40

γ = ΔYo/xo = tanφ

i.e. distance the side length has shifted

Question 41

give the equation/definition for poisson’s ratio

Answer 41

for normal stress on z
εx = εy = -v εz

v = poisson’s ratio

Question 42

give the equation linking E and G using poisson’s ratio

Answer 42

E = 2G(1+v)

Question 43

give the equation for how to approximate E using U (potential energy curve) and interatomic spacing, ro

Answer 43

E = (1/ro) (d^2U/dr^2)|r=ro

Question 44

using the block slab model, give the expression for axial modulus of a composite, Ec, in terms of the moduli of the matrix, Em and fibres, Ef

Answer 44

Ec = EfVf + Em(1-Vf)

Question 45

using the block slab model, give the expression for transverse modulus of a composite, Ec, in terms of the moduli of the matrix, Em and fibres, Ef

Answer 45

Ec = (EfEm) / (EmVf + Ef(1-Vf))

Question 46

give the equation for expansion due to temperature using the coefficient of thermal expansion, α

Answer 46

εt = α ΔT

Question 47

give the equation for how we define radius when considering bending of beams

Answer 47

R = l / θ

Question 48

give the equation for the deflection at any point on a rectangular beam and hence the max deflection

Answer 48

y = (Fx^2/6EI)(3L-x)

δ = FL^3 / 3EI

Question 49

give the expression for the Peierls-Nabarro stress

Answer 49

τ = 3G exp(-2πw/ b)

w = dislocation width
G = shear modulus
b = |b|

Question 50

give the expression for the glide ‘force’ (per unit length) of a dislocation

Answer 50

F = τb
b = burgers !vector!

Question 51

give two expressions for the work done in moving a dislocation

Answer 51

W = FLd
d = dislocation distance
F = glide force (per unit length)
L = length of line of dislocation

W = τbLd

Question 52

give the equation for the critical resolved shear stress

Answer 52

τ(crit) = σy cos(φ) cos(λ)

φ = angle of slip plane normal to tensile axis
λ = angle of slip direction to tensile axis

Question 53

what is the Schmid factor

Answer 53

cos(φ) cos(λ)

Question 54

what is the equation we should consider when thinking about how the tensile axis rotated towards the slip direction on maintained slip

Answer 54

TA = TA(orig.) + n [slip direction]

Question 55

when two dislocations combine, what is the new burgers vector

Answer 55

b3 = b1+b2

Question 56

what is franks rule, when is dislocation combination favourable

Answer 56

(b3)^2 < (b1)^2 + (b2)^2

Question 57

give the equation for dislocation density

Answer 57

ρ = 1/L^2

L = avr. spacing of dislocations on an area

Question 58

Give the Hall-Petch relationship regarding grain size and yield stress

Answer 58

σy = σo + k/sqrt(d)

σy = yield stress
σo = Peierls-Nabarro stress
k = const.
d = avr. grain diameter

Question 59

give the relationship for the increase in shear stress due to precipitate cutting

Answer 59

Δτ prop. to sqrt(r)

Question 60

Give the griffith criterion

Answer 60

G = π(σo^2)(c) / E

G >= Gc = 2γ

Question 61

Give the griffith criterion for ductile materials

Answer 61

G >= Gc = 2(γ + γp)

Question 62

give the equation for the stress intensity paramater

Answer 62

K = σo sqrt(pi*c)

Question 63

give the equation for viscous liquid flow

Answer 63

τ = -η dγ/dt

Question 64

Give the equation for the critical undercooling for ice formation on an Ice nucleating agents

Answer 64

ΔT(crit) = -2γ/ ΔSv R

Question 65

give the Clausius-Clapeyron eq.

Answer 65

dp/dt = ΔS/ΔV

Question 66

give the inequality which explains why surface melting generally occurs

Answer 66

γsv > γls + γlv

Question 67

give the equation for strain rate due to creep (generally)

Answer 67

dε/dt = Aσ^n

Question 68

give the equation for strain rate due to diffusion (coble) creep

Answer 68

dε/dt = (B’σ / d^2) exp(-Q/RT)

Question 69

give the equation for strain rate due to dislocation creep

Answer 69

dε/dt = (A’ σ^n) exp(-Q/RT)

Question 70

give the general equations for the efficiency of the carnot and brayton cycles for jet engines

Answer 70

Carnot
Efficiency = 1 - Tc/Th

Brayton
Efficiency = 1- T2/T1

Question 71

give the eq.’s for the max and average transferable energy in radiation damage and define the coeffecient

Answer 71

Max. transferable energy = ζ En
Av. transferable energy = ζ En /2

ζ = 4A / (1+A)^2
A = atomic mass number