Since the lock-in amplifier measures the ac signal of the same frequency with its reference signal, the frequency of the piezoelectric tube oscillation, the frequency of the... cantilev[r]
Trang 1Theoretical Question 3: Scanning Probe Microscope
1 Answers
(a)
2 2 2 2 2 0 2
0
)
m
F A
+
−
) (
0
0 ω ω
ω φ
−
=
m
b
At ω =ω0,
0
0 ω
b
F
and
2
π
φ =
(b) A non-vanishing dc component exists only when ω =ωi
In this case the amplitude of the dc signal will be V i V R cosφi
2
1
0
(c)
0
2
0
2
1
2 bω
V
c
at the resonance frequency ω0
(d) ∆m=1.7×10− 18 kg
(e)
2 / 1
2 0
3 0
−
=
ω ω
ω
m
c
(f)
3 / 1
0 0
∆
=
ω ω
m
qQ k
=
0
d 41 nm
Trang 22 Solutions
(a) [1.5 points]
Substituting z(t)= Asin(ωt−φ) in the equation m z F t
dt
dz b dt
z d
0 2
2
= +
+ yields,
t A
F t
m t
b t
mω sin(ω φ) ωcos(ω φ) ω 2sin(ω φ) 0sinω
0
Collecting terms proportional to sinωt and cosωt, one obtains
{ ( )sin cos }cos 0 sin
sin cos
)
0 0
2
2
A
F b
Zeroing the each curly square bracket produces
) (
0 ω ω
ω φ
−
=
m
b
2 2 2 2 2 0 2
0
)
m
F A
+
−
At ω =ω0,
0
0 ω
b
F
2
π
(b) [1 point]
The multiplied signal is
}]
) cos{(
} ) [cos{(
2 1
) sin(
) sin(
0 0
0 0
i i
i i
R i
R i i i
t t
V V
t V
t V
φ ω ω φ
ω ω
ω φ
ω
− +
−
−
−
=
−
(b1)
A non-vanishing dc component exists only when ω=ωi In this case the amplitude of
the dc signal will be
i R
i V
V cosφ
2
1
0
(c) [1.5 points]
Since the lock-in amplifier measures the ac signal of the same frequency with its
reference signal, the frequency of the piezoelectric tube oscillation, the frequency of the
Trang 3cantilever, and the frequency of the photodiode detector should be same The magnitude of the input signal at the resonance is
0
0 2 1 0
0 2
V c c b
F c
Then, since the phase of the input signal is 0
2
at the resonance, φi =0 and the lock-in amplifier signal is
0
2 0 2 1 0
0
2 0 cos 2
1
ω
b
V c c V
R
(d) [2 points]
The original resonance frequency
m
k
= 0
ω is shifted to
− ∆
=
− ∆
≅
+ ∆
=
∆ +
−
m
m m
m m
k m
m m
k m m
k
2
1 1 2
1 1
1
Thus
m
m
∆
−
=
2
1ω
Near the resonance, by substituting φ→π +∆φ
2 and ω0 →ω0 +∆ω0 in Eq (a3), the change of the phase due to the small change of ω0 (not the change of ω) is
0 2 tan
1 2
tan
ω φ
φ
π
∆
=
∆
−
=
+∆
m
b
Therefore,
b
2
φ ≈ ∆ =− ∆
From Eqs (d2) and (d4),
18 18
6
12 3
0
10 7 1 10 8 1 1800 10
10
×
=
=
⋅
=
∆
=
ω
b
(e) [1.5 points]
In the presence of interaction, the equation of motion near the new equilibrium position 0
h becomes
Trang 4t F z c z m dt
dz b dt
z d
0 2
2
=
− +
where we used f(h)≈ f(h0)+c3z with z=h−h0 being the displacement from the
new equilibrium position h Note that the constant term 0 f(h0) is cancelled at the
new equilibrium position
Thus the original resonance frequency
m
k
= 0
ω will be shifted to
2 0
3 0
3
2 0 3
'
ω ω
ω ω
m
c m
c m m
c
Hence the resonance frequency shift is given by
−
−
=
0
3 0
ω
m
c
(f) [2.5 points]
The maximum shift occurs when the cantilever is on top of the charge, where the
interacting force is given by
2
) (
h
qQ k h
From this,
3 0
qQ k dh
df
d h
−
=
=
=
(f2)
Since ∆ω0 <<ω0, we can approximate Eq (e4) as
0
3
0 2 ω
ω
m
c
−
≈
From Eqs (f2) and (f3), we have
3 0 0
3 0 0
2
1
d m
qQ k d
qQ k
−
−
=
Here q = e=−1.6×10− 19 Coulomb and Q = e6 =−9.6×10− 19 Coulomb Using the values provided,
Trang 58 3
/ 1
0 0
0 =4.1×10−
∆
=
ω ω
m
qQ k
Thus the trapped electron is 41 nm from the cantilever
Trang 63 Mark Distribution
No Total
Pt
Partial
0.7 Equations for A and φ (substitution and manipulation) 0.4 Correct answers forA and φ
(a) 1.5
0.4 A and φ at ω0 0.4 Equation for the multiplied signal 0.3 Condition for the non-vanishing dc output (b) 1.0
0.3 Correct answer for the dc output 0.6 Relation between V i and V R
0.4 Condition for the maximum dc output (c) 1.5
0.5 Correct answer for the magnitude of dc output 0.5 Relation between ∆m and ∆ω0
1.0 Relations between ∆ω0 (or ∆m) and ∆φ (d) 2.0
0.5 Correct answer (Partial credit of 0.2 for the wrong sign.) 1.0 Modification of the equation with f (h) and use of a proper
approximation for the equation (e) 1.5
0.5 Use of a correct formula of Coulomb force 0.3 Evaluation of c3
0.6 Use of the result in (e) for either ∆ω0 or ω'20−ω02 0.6 Expression for d0
(f) 2.5