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Transcript
The Classical Hall effect
Page 1
Reminder: The Lorentz Force
F = q[E + (v  B)]
Page 2
Lorentz Force: Review
• Velocity Filter
Undeflected trajectories in crossed E & B fields: v = (E/B)
• Cyclotron Motion
FB = mar  qvB = (mv2/r)
• Orbit Radius
A Momentum Filter!!
r = [(mv)/(|q|B)] = [p/(q|B|])
• Orbit Frequency
A Mass Measurement Method!
ω = 2πf = (|q|B)/m
• Orbit Energy
K = (½)mv2 = (q2B2R2)/2m
Page 3
Standard Hall Effect Experiment Setup
e- v
Current from the
applied E-field
e+ v
Lorentz force from the magnetic
field on a moving electron or hole
E field
Top view: Electrons
drift from back to front
e- leaves + & – charge on
the back & front surfaces
Hall Voltage
The sign is reversed for holes
Page 4
Electrons Flowing With
No Magnetic Field
Semiconductor Slice
t
_
+
d
I
I
Page 5
When the Magnetic Field
is Turned On ..
I
qBv
B-Field
Page 6
As time goes by...
High
Potential
qE
I
qBv = qE
Low
Potential
Page 7
Finally...
VH
I
B-Field
Page 8
The Classical Hall Effect
1400
ly
Hall Resistance
Rxy (Ohms)
1200
1000
Slope Related to RH &
Sample Dimensions
800
600
400
200
Ax
0
0
2
4
6
8
10
Magnetic Field (Tesla)
ly is the transverse width of the sample
Ax is the transverse cross sectional area
The Lorentz Force tends to deflect jx. However, this sets up
an E-field which balances that Lorentz Force. Balance occurs when
Ey = vxBz = Vy/ly. But jx = nevx (or ix = nevxAx). So
Rxy = Vy / ix = RH Bz × (ly/Ax) where RH = 1/ne
Page 9
Semiconductors: Charge Carrier Density via Hall Effect
• Why is the Hall Effect useful? It can determine the carrier type
(electron vs. hole) & the carrier density n for a semiconductor.
• How? Place the semiconductor into external B field, push
current along one axis, & measure the induced Hall voltage VH
along the perpendicular axis. The following can be derived:
• Derived from the Lorentz force FE = qE = FB = (qvB).
n = [(IB)/(qwVH)]
Hole
+ charge
FB  qv  B
Electron
– charge
Page 10
The 2D Hall Effect
The surface current density is sx = vxσ q, where σ is the
surface charge density. Again, RH = 1/σe. However,
now: Rxy = Vy / ix = RH Bz. since sx = ix /ly & Ey = Vy /ly.
So, Rxy does NOT depend on the shape of the sample.
This is a very important aspect of
the Quantum Hall Effect
Page 11
The Integer Quantum Hall Effect
Very important:
For a 2D electron
system only
First observed in 1980 by
Klaus von Klitzing
Awarded 1985 Nobel Prize.
Hall Conductance is quantized in units of e2/h, or
Hall Resistance Rxy = h/ie2, where i is an integer.
The quantum of conductance h/e2
is now known as the "Klitzing“!!
Has been measured to 1 part in 108
Page 12
The Fractional Quantum Hall Effect
The Royal Swedish Academy of Sciences awarded The 1998 Nobel
Prize in Physics jointly to Robert B. Laughlin (Stanford), Horst L.
Störmer (Columbia & Bell Labs) & Daniel C. Tsui, (Princeton)
• The researchers were awarded the Nobel Prize for discovering that electrons
acting together in strong magnetic fields can form new types of "particles", with
charges that are fractions of electron charges.
Citation: “For their discovery of a new form of quantum fluid
with fractionally charged excitations”
• Störmer & Tsui made the discovery in 1982 in an experiment using extremely
powerful magnetic fields & low temperatures. Within a year of the discovery
Laughlin had succeeded in explaining their result. His theory showed that
electrons in a powerful magnetic field can condense to form a kind of quantum
fluid related to the quantum fluids that occur in superconductivity & liquid
helium. What makes these fluids particularly important is that events in a drop
of quantum fluid can afford more profound insights into the general inner
structure dynamics of matter. The contributions of the three laureates have thus
led to yet another breakthrough in our understanding of quantum physics & to
the development of new theoretical concepts of significance in many branches
of modern physics.
Page 13