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| United States Patent |
4,488,164
|
|
Kazarinov
, et al.
|
December 11, 1984
|
Quantized Hall effect switching devices
Abstract
A switching element (e.g., 30) is furnished by an inversion layer (e.g.,
55) in a zero resistance state under the influence of a quantizing
magnetic field, the inversion layer having a ring geometry. Voltage (e.g.,
V.sub.o) applied across a pair of localized spaced apart terminals (e.g.,
37, 38)--one on a portion of the inner edge of the ring, the other on the
outer edge--produces a percolating current in the inversion layer, that
is, a current circulating around the ring in a zero resistance state. This
percolating current suddenly vanishes when a control voltage is applied to
an auxiliary (gate) electrode (e.g., 51), whereby an output voltage (e.g.,
V.sub.out) previously developed across another pair of localized spaced
apart terminals (e.g., 47, 48) on either edge of the ring suddenly also
vanishes.
| Inventors:
|
Kazarinov; Rudolf F. (Martinsville, NJ);
Luryi; Sergey (New Providence, NJ)
|
| Assignee:
|
AT&T Bell Laboratories (Murray Hill, NJ)
|
| Appl. No.:
|
387227 |
| Filed:
|
June 10, 1982 |
| Current U.S. Class: |
257/194; 257/421; 257/468; 326/101; 326/104; 327/511; 505/860 |
| Intern'l Class: |
H01L 027/22; H01L 025/04; H01L 045/00; H01L 029/82 |
| Field of Search: |
357/83,27,2,4
307/309
|
References Cited [Referenced By]
U.S. Patent Documents
Other References
P. W. Shackle, "Measurement of the Hall Coefficient in Liquid Metals by the
Corbino Method," Phil. Mag., Ser. 8, vol. 21, 1970, pp. 987-1002.
D. C. Tsui et al., "Zero-Resistance State of Two-Dimensional Electrons in a
Quantizing Magnetic Field," Physical Review B, vol. 25, No. 2, Jan. 15,
1982, pp. 1405-1407.
S. Kawaji "Quantum Galvanomagnetic Experiments in Silicon Inversion Layers
Under Strong Magnetic Fields," Surface Science, vol. 73, 1978, pp. 46-69.
D. C. Tsui et al., "Resistance Standard Using Quantization of the Hall
Resistance of GaAs-Al.sub.x Ga.sub.1-x As Heterostructures," Applied
Physics Letters, vol. 38, Apr. 1, 1981, pp. 550-552.
K. V. Klitzing et al., "New Method for High-Accuracy Determination of the
Fine-Structure Constant Based on Quantized Hall Resistance," Physical
Review Letters, vol. 45, No. 6, Aug. 11, 1980, pp. 494-497.
|
Primary Examiner: Edlow; Martin H.
Assistant Examiner: Jackson, Jr.; Jerome
Attorney, Agent or Firm: Caplan; David I.
Claims
What is claimed is:
1. A quantized Hall effect switching element comprising means for
establishing and gate means for interrupting quantum percolation of
electrical current, said means for establishing including:
a pair of solid layers physically contacting each other at an interface
having a closed ring geometry configuration at which during operation an
inversion layer forms, said inversion layer having a zero resistance state
when subjected to a predetermined magnetic field at a predetermined
temperature, said solid layers comprising a first solid semiconductor
layer upon which another solid layer has been grown, a pn junction in the
first solid layer contiguous with an outer edge of the ring.
2. An element according to claim 1 further comprising:
first electrical access means to a first portion of the loop for detecting
the interrupting, whereby an output voltage developed at said first access
means switches in response to an input signal applied to said gate means.
3. An element according to claim 1 or 2 in which said means for
establishing further includes:
second electrical access means to a second portion of the loop.
4. An element according to claim 1 or 2 in which said gate means comprises
a gate electrode and in which said means for establishing further includes
low temperature means and magnetic field means for establishing,
respectively, a temperature and a magnetic field suitable for said
quantized Hall effect.
5. A logic device including first and second switching elements, the first
element and the second element in accordance with claim 1 in which the
gate means of the second element is connected to the first electrical
access means of the first element, whereby the presence versus absence of
said percolation in the second element is a logical function of signal
applied to the gate means of the first element.
6. A logic device including mutually overlapping first and second elements
each according to claim 1, whereby the presence versus absence of said
percolation of current in the second element is a logical function of the
presence versus absence of said percolation of current in the first
element.
7. A switching element comprising:
(a) a pair of solid layers having an interface therebetween at which during
operation is formed an inversion layer in a ring configuration exhibiting
a zero resistance state, completely around the ring, at a predetermined
temperature under the influence of a magnetic field sufficient to produce
the zero resistance state in said inversion layer, said solid layers
comprising a first solid semiconductor layer upon which another solid
layer has been grown, a pn junction in the first solid layer located at an
outer edge of the ring;
(b) a first external contact to a first portion of the ring for injecting
electrical charges into the inversion layer in order to establish an
electrical current percolating around the ring in said zero resistance
state;
(c) a second electrical contact to a second portion, separated from said
first portion, of the ring for detecting the presence versus absence of
said electrical current; and
(d) gate electrode means, proximate said inversion layer at a third portion
thereof, for interrupting said zero resistance state and correspondingly
modulating said electrical current, in response to a voltage applied to
said gate electrode means, without interrupting said inversion layer,
whereby the voltage at said second electrical contact is correspondingly
modulated.
8. A switching element formed by a two-dimensional electron gas in an
inversion layer, in a ring geometry, the inversion layer situated at an
interface between a pair of solid layers, said solid layers comprising a
first solid semiconductor layer upon which another solid layer has been
grown, a pn junction in the first solid layer located at an outer edge of
the ring, having a first pair of spaced apart terminals contacting
opposing first portions of, respectively, inner and outer surfaces of the
ring to establish a voltage across said terminals and hence across said
first portions of the inner and outer surfaces, said inversion layer being
subjected to a sufficient magnetic field and being maintained at a
sufficiently low temperature that electrons can percolate around the ring
in a zero resistance state, whereby an output voltage appears across a
second pair of terminals contacting opposing second portions,
respectively, of said inner and outer surfaces removed from said first
portions and said output voltage disappears if and only if a sufficient
voltage is applied to a gate electrode insulated from the inversion layer
and located in a neighborhood of said inversion layer which is removed
from said first and second portions.
9. An element according to claim 1, 2, 7, or 8 further including means for
applying said magnetic field.
10. An element according to claim 1, 2, 7, or 8 further including means for
maintaining said element at said predetermined temperature.
11. An element according to claim 1, 2, 7, or 8 in which said solid layers
are both Group III-V materials.
12. An element according to claim 11 in which said solid layers are gallium
arsenide and gallium aluminum arsenide.
13. An element according to claim 1, 2, 7, or 8 in which said solid layers
are a silicon body and a silicon dioxide layer.
14. An element according to claim 13 further comprising a layer of
amorphous silicon located on silicon dioxide layer.
Description
FIELD OF THE INVENTION
This invention relates to solid state electrical switching devices, and
more particularly to quantized Hall effect switching devices.
BACKGROUND OF THE INVENTION
In a paper entitled "New Method for High-Accuracy Determination of the
Fine-Structure Constant Based on Quantized Hall Resistance," published in
Physical Review Letters, Vol. 45, pp. 494-497 (1980), K. v. Klitzing, G.
Dorda, and M. Pepper showed that the Hall resistance of a two-dimensional
elctron gas, formed at the inversion layer at an interface of silicon and
silicon dioxide in a metal-oxide-semiconductor field-effect transistor
configuration, is quantized when this resistance is measured at liquid
helium temperatures in a magnetic field of the order of 15 Tesla (150
kilogauss). By "quantized" is meant that the Hall resistance would take on
certain values corresponding to Hall conductivities which were
proportional to the product of the fine structure constant (approximately
1/137) and the speed of light.
In a subsequent paper entitled "Resistance Standard Using Quantization of
the Hall Resistance of GaAs-Al.sub.x Ga.sub.1-x As Heterostructures,"
published in Applied Physics Letters, Vol. 38, pp. 550-552 (1981), D. C.
Tsui and A. C. Gossard demonstrated that a two-dimensional electron gas at
a heterojunction interface--specifically an interface between gallium
arsenide and aluminum gallium arsenide--at sufficiently low temperatures
and under sufficiently high magnetic fields perpendicular to the
interface, similarly evinced quantized resistivities.
More specifically, as indicated in FIG. 1, Tsui and Gossard showed that the
longitudinal or ohmic electrical resistivity (.rho..sub.xx) of the
inversion layer at the heterojunction interface of a sample structure of
GaAs-Al.sub.0.3 Ga.sub.0.7 As at 4.2.degree. K. exhibited minima (as a
function of magnetic field) equal to substantially zero resistivity (less
than 0.1 ohms per square) at magnetic fields of 4.2 and 8.4 Tesla, and
that the transverse or Hall resistivity (.rho..sub.xy) exhibited
stationary (quantized) values (r.sub.1, r.sub.2, r.sub.3, r.sub.4, . . . )
under these magnetic fields.
FIG. 2 illustrates an example showing how to measure these resistivity
effects. As shown in FIG. 2, a source of an electrical current I is
furnished by a battery of electromotive force E connected in series with a
high impedance Z. The current I is supplied to the electrode contacts 11
and 12 located on opposite ends of a solid rectangular rod or bar 10 of
width w and thickness t, and having a side edge 13 and an opposite side
edge 14. The resistance of the impedance Z is sufficiently high that
during operation the current I is essentially constant. The bar is
oriented with w parallel to the y-direction and t parallel to the
z-direction (perpendicular to the plane of the drawing). An inversion
layer is formed at a heterojunction interface 15 (FIG. 3) between top and
bottom portions 16 and 17 of the rod. The heterojunction interface 15
extends at constant z=z.sub.o all the way along a cross section of the rod
10 between the electrode contacts 11 and 12. Each of electrodes 21 and 22
of first pair of electrical probes is located in contact with the bar 10
at z=z.sub. o and at the same x coordinates, and each of electrodes 23 and
24 of a second pair of electrical probes is located in contact with the
bar at z=z.sub.o and at the same x but at a distance l measured along the
x-direction away from the first pair of probes 21 and 22. A uniform steady
magnetic field B is applied to the bar parallel to the z-direction. As a
result of the applied voltage E, a current I flows through the bar along
the x-direction; as a result of the magnetic field B, a Hall effect
voltage is developed across the bar 10 in the y-direction. More
specifically, the voltage or potential difference V between probes 21 and
23 (or between probes 22 and 24) is measured by a voltmeter of extremely
high impedance, that is, a voltmeter which draws negligible current as
compared to I. Likewise, the voltage between probes 23 and 24 (or between
probes 21 and 22) is also measured by a voltmeter of extremely high
impedance. Accordingly, essentially no current flows in the y-direction
once equilibrium is established in the bar 10 under the applied voltage E.
In accordance with the definition of the ohmic resistance R of the bar 10:
R=V/I (1)
On the other hand, the x-component E.sub.x of electric field in the bar 10
is equal in magnitude to V/l; and the x-component j.sub.x of the
electrical current density is equal to I/wt. Accordingly, the longitudinal
resistivity .rho..sub.xx, defined in this case as E.sub.x /j.sub.x, is
given by:
.rho..sub.xx =(V/l)/(I/wt)
or
.rho..sub.xx /t=R(w/l)=(V/I)(w/l) (2)
Accordingly, the quantity (.rho..sub.xx /t) can be obtained from
measurements of V, I, w, and l. The quantity (.rho..sub.xx /t) is called
the "sheet resistivity" and thus has the same dimensions as resistance,
i.e., ohms.
Moreover, as indicated above, because of the presence of the magnetic field
B in the z-direction, the Hall voltage V.sub.H is developed across the
width w of the bar 10, as measured across the probes 23 and 24. The
corresponding Hall resistance is given by
R.sub.H =V.sub.H /I (3)
Accordingly, the Hall resistance R.sub.H of the bar 10 can be formed by
measurements of V.sub.H and I.
On the other hand, the y-component E.sub.y of the electric field in the bar
10 is equal in magnitude to V.sub.H /w. The transverse or Hall resistivity
.rho..sub.xy, defined in this case as E.sub.y /j.sub.x, is thus given by:
.rho..sub.xy =(V.sub.H /w)/(I/wt)
or
.rho..sub.xy /t=R.sub.H =V.sub.H /I (4)
Accordingly, .rho..sub.xy /t is the transverse or Hall "sheet resistivity"
and also has the dimensions of ohms.
In the aforementioned paper by D. C. Tsui and A. C. Gossard, in Applied
Physics Letters, Vol. 38, (.rho..sub.xx /t) and (.rho..sub.xy /t) were
found to behave as indicated in FIG. 1; that is, .rho..sub.xx /t has zeros
at certain values of magnetic field B, and .rho..sub.xy /t has (quantized)
plateaus (r.sub.1, r.sub.2, r.sub.3, . . . ) at these values of the
magnetic field B. In this sense, .rho..sub.xy /t is said to be
"quantized."
More specifically, these quantized values of resistivity have been found to
satisfy the relationships:
r.sub.1 =h/2e.sup.2
r.sub.2 =h/4e.sup.2
r.sub.3 =h/6e.sup.2
r.sub.4 =h/8e.sup.2 ( 5)
where h is Planck constant and e is the charge on the electron. The
existence of these quantized values of Hall resistivity has been shown to
imply the existence of long range order in a two-dimensional electron gas.
More specifically, these quantized Hall resistivities imply the existence
of nonlocalized quantized states corresponding to quantum Landau levels
whose wave functions extend over macroscopic distances in the inversion
layer, that is, electronic states characterized by significant probability
of finding an electron in the inversion layer at differing locations
separated by distances typically as large as the order of millimeters.
Thus far, the only important practical use of this quantized Landau level
effect has been a method for accurate measurement of the value of
h/e.sup.2 and hence of the fine structure constant, e.sup.2
/2.epsilon..sub.o hc=1/137, approximately, where .epsilon..sub.o is the
permittivity of the vacuum and c is the speed of light. On the other hand,
it would be desirable if this phenomenon of quantized Hall resistance,
with its zero resistance state, could be used as a basis for switching
elements and logic gates having relatively high switching speeds and low
switching power-delay products.
SUMMARY OF THE INVENTION
A quantized Hall effect switching element is formed by an inversion layer,
in a closed loop (annular ring) geometry configuration, having a first
pair of spaced apart terminals contacting opposing first portions of,
respectively, inner and outer edges of the ring to establish a voltage
across said terminals, and hence across said first portions of the inner
and outer edges, said inversion layer being subjected to a sufficient
magnetic field and being maintained at a sufficiently low temperature that
electrons can percolate around the ring in a zero resistance state,
whereby an output voltage appears across a second pair of terminals
contacting opposing second portions, respectively, of said inner and outer
edges removed from said first portions, and said output voltage vanishes
if and only if an input voltage is applied to a gate electrode located in
a neighborhood of said inversion layer which is removed from said first
and second portions. More specifically, the magnetic field is adjusted to
a value at which the longitudinal resistivity substantially vanishes.
Accordingly, virtually no power is then being consumed by the percolation
of electrons around the ring.
In the absence of input voltage, it is believed that the electrons in the
inversion layer form a two-dimensional gas of electrons circulating
("percolating") around the ring in orbits corresponding to nonlocalized
(extended) quantum Landau levels or states, as described more fully in the
Appendix; whereas in the presence of the input voltage, the nonlocalized
levels are broken up into localized states, and the electrons no longer
percolate around the ring but circulate in localized orbits associated
with these localized states. By "nonlocalized" orbit (or "extended" orbit)
is meant that the orbit percolates around the entire ring, the term
"orbit" signifying paths or regions characterized by significant (quantum
mechanical) probability that the electron will be found in such regions.
When the input signal attains a certain value, no nonlocalized
(percolating) Landau states can exist any longer, all orbits become
localized (nonpercolating), and the output voltage suddenly vanishes.
During logic operations, in the absence of sufficient input voltage signal,
the electrons thus percolate in the nonlocalized Landau levels around the
ring, and the output voltage is then equal to a nonvanishing fixed value.
If and when the input signal attains a sufficient ("critical") value, the
output voltage thus suddenly vanishes. At intermediate values of input
signal, the output voltage remains at the same (nonvanishing) fixed value.
Thus the output voltage can serve as an output signal that is
representative of the state (percolating vs. nonpercolating) of the
switching element.
It is believed that the sudden switching in this invention--i.e., the
vanishing of the output voltage--will occur with very small power-delay
product and hence very small energy dissipation, typically as low as
10.sup.-20 joule per switching, and with a very small switching time,
typically as low as a few picoseconds. Similarly, when the input signal
voltage is removed, the percolating current will be re-established within
a similarly short switching time, and the output (signal) voltage will
thus be restored similarly quickly. It is further believed that during the
time intervals when the input signal voltage is zero or is increasing to
its critical value, but before it attains the critical value, electrons in
quantized nonlocalized Landau states percolate around the ring in such a
manner as to maintain the output voltage with negligible power
dissipation. For example, at a temperature of about 4.2.degree. K., a
power of the order of only about 10.sup.-8 watts per switching element is
expected to be dissipated even when current is percolating around the
ring.
The effect of a voltage applied to the gate electrode to interrupt the
percolating current flow in the annular ring in the practice of this
invention is to be sharply distinguished from the effect of a voltage
applied to interrupt the current in a conventional insulated gate field
effect transistor (FET). In the case of the field effect transistor, the
current is interrupted (transistor turns OFF) when the applied gate
voltage is sufficient to interrupt the inversion layer so that the
inversion layer no longer extends from source to drain as it did when the
transistor was conducting current (i.e., when it was ON). In the device
element of this invention, by contrast, during operation the inversion
layer (as opposed to the percolating current) always extends all the way
around the annular ring; that is, regardless of whether the device is in
the ON or OFF state, the inversion layer is never interrupted.
Instead of interrupting the inversion layer as in the conventional FET, the
device of the present invention turns OFF when the voltage applied to the
gate electrode suppresses percolation of electrons around the ring in
nonlocalized Landau levels even though the inversion layer is still
maintained all the way around the ring. Indeed the voltage applied to the
gate electrode for turning OFF the percolating current in this invention
can be of the opposite polarity from that of the gate voltage required for
turning OFF a corresponding conventional FET.
Rather than operating by interrupting the inversion layer, it is believed
that the device of this invention thus turns OFF when the voltage applied
to the gate electrode is sufficient to drive all the equipotentials, along
which the nonlocalized Landau states otherwise would be percolating, out
of the inversion layer (at least in the neighborhood of the gate
electrode); so that no longer is there any Landau state with a
corresponding percolating electron orbit defined, that is, confined within
the inversion layer all the way around the ring, every (percolating)
Landau electron orbit being characterized by circulation around the ring
centered along an equipotential line, that is, the intersection of an
equipotential surface with the plane of the inversion layer (considered as
having negligible thickness). Thus, the turning OFF of the device in this
invention is believed to result from the forcing of all equipotentials
associated with Landau states orbits out of the inversion layer at least
in the neighborhood of the gate electrode, and hence the OFF state results
from the interruption and destruction of all nonlocalized (percolating)
orbits in the inversion layer, the inversion layer itself remaining
completely intact and uninterrupted.
BRIEF DESCRIPTION OF THE DRAWING
This invention can be better understood from the following detailed
description when read in conjunction with the drawing in which
FIG. 1 is a graphic plot of resistivity versus magnetic field, exhibiting
the quantized Hall effect in accordance with prior art;
FIG. 2 is a top view diagram, partly in cross section, of a circuit for
measuring the quantized Hall effect in accordance with prior art;
FIG. 3 is a section of a portion of FIG. 2;
FIG. 4 is a top view diagram of a quantized Hall effect switching element,
in accordance with a specific embodiment of the invention;
FIGS. 5 and 6 are cross sections of portions of the switching element shown
in FIG. 4;
FIG. 7 is a symbolic logic representational diagram of the switching
element shown in FIG. 4;
FIG. 8 is a symbolic logic diagram of the switching element shown in FIG. 4
used as a NOR gate in accordance with another embodiment of the invention;
FIG. 9 is a symbolic logic diagram of a pair of switching elements
connected for use as an OR gate in accordance with still another
embodiment of the invention;
FIG. 10 is a symbolic logic diagram of a pair of switching elements
connected for use as an AND NOT gate in accordance with yet another
embodiment of the invntion;
FIG. 11 is a symbolic logic diagram of a triplet of switching elements
connected for use as an AND gate in accordance with still another
embodiment of the invention;
FIG. 12 is a top view diagram of a quantized Hall effect switching element,
in accordance with another specific embodiment of the invention;
FIGS. 13-15 are cross sections of portions of the switching element shown
in FIG. 12;
FIG. 16 is a top view diagram of a quantized Hall effect switching element,
with an overlapping ring geometry, in accordance with yet another specific
embodiment of the invention;
FIG. 17 is a top view diagram of a quantized Hall effect switching element,
with a multiply connected ring geometry, in accordance with still another
specific embodiment of the invention;
FIG. 18 is a cross section view of the element shown in FIG. 17; and
FIG. 19 is a graphic plot of conduction band energy versus distance, useful
in understanding the invention.
Only for the sake of clarity, none of the drawings is to any scale.
DETAILED DESCRIPTION
A switching device element 30 in accordance with a specific embodiment of
the invention is shown in FIG. 4. Here, illustratively, a single crystal
p-type gallium arsenide body 31 serves as a base for the epitaxial growth
of, and mechanical support for, ring-shaped epitaxial layers 32 and 33 of
gallium aluminum arsenide and silicondoped gallium aluminum arsenide,
respectively. More specifically, the body 31 is 0.5 mm thick, with a
uniform concentration of acceptor impurities of typically about 10.sup.15
or less per cm.sup.3 ; the layer 32 is essentially Ga.sub.y Al.sub.1-y As
having a thickness d of typically about 100 .ANG., and a mole fraction y
ordinarily in the approximate range of 0.25 to 0.40, typically about 0.30,
and a uniform concentration of donor impurities of typically about
10.sup.15 or less per cm.sup.3 ; and the layer 33 is essentially Ga.sub.x
Al.sub.1-x As doped with silicon, with a thickness of typically about 600
.ANG., a mole fraction x ordinarily in the approximate range of 0.25 to
0.40, typically about 0.30, and a uniform concentration of donor
impurities of typically about 3.times.10.sup.18 per cm.sup.3. The
epitaxial layers 32 and 33 are typically grown by molecular beam epitaxy,
followed by selective masking and etching--as with a mask of silicon
dioxide and solution etching with a solution of about 3 parts (by volume)
sulphuric acid, 1 part hydrogen peroxide, and 1 part water--to form a
circular ring geometry on the body 31. The ring has an inner edge radius
R.sub.1, typically of about 10 micron, and an outer edge radius R.sub.2,
typically of about 15 micron. It should be understood, however, that the
ring need not be circular and that any closed loop configuration can be
used. At the interface of the epitaxial layer 32 with the top surface 31.5
of body 31, an inversion layer 55 naturally forms in a region of the body
31 contiguous with this interface in the configuration of an annular
(planar) ring. This inversion layer forms in response to the internal
electric field produced, inter alia, by the silicon in the epitaxial layer
33. Ordinarily for this purpose of establishing the inversion layer 55 in
this illustrative example, the concentration of silicon in this layer 33
is in the approximate range of 10.sup.18 to 5.times.10.sup.18 per
cm.sup.3, typically about 3.times.10.sup.18 per cm.sup.3.
As further indicated in FIGS. 4 and 5, the device 30 also includes a first
pair of n.sup.+ localized zones 35 and 36 located contiguous with the top
surface 31.5 of the body 31 and contiguous with the outer and inner edges,
respectively, of the inversion layer 55 at a first portion of the ring, as
well as a second pair of n.sup.+ localized zones 45 and 46 located at the
top surface of the body at a second portion of the ring removed from the
first portion thereof. The term "portion" in this context refers, for
example, to an angular sector of the ring.
A ground plane 41 contacts the entire bottom surface of the body 31, and a
deposited silicon dioxide layer 34 contacts the top of the device 30,
including the exposed portion of the top surface 31.5 of the body 31, the
side surfaces of the epitaxial layers 32 and 33, and the top surface of
the epitaxial layer 33. Apertures are formed in this silicon dioxide layer
34 at areas where electrode contacts 37, 38, 47, and 48 are made,
respectively. Thus electrically conducting metallization layer 61 contacts
the n.sup.+ zone 35 via electrode contact 37, electrically conducting
metallization layer 62 contacts the n.sup.+ zone 36 via electrode contact
38, electrically conducting metallization layer 63 contacts the n.sup.+
zone 45 via electrode contact 47, and electrical conducting metallization
layer 64 contacts the n.sup.+ zone 46 via electrode contact 48. In
addition, the common merger portion of the conducting layers 62 and 63
contact an n.sup.+ zone 53 running from the top surface 31.5 of the body
31 to the ground plane 41 on the bottom surface, in order to furnish an
electrical ground for the n.sup.+ zones 36 and 45. It should be noted that
the n.sup.+ zone 45 can be omitted, since during operation the inside edge
of the ring becomes an equipotential surface. As another alternative, the
n.sup.+ zone 36 can extend all around the inside edge of the ring, or can
extend even throughout the entire portion of the surfaces 31.5 located
within the area encompassed by the inner circle R.sub.1 so that the
metallization layers 62 and 63 then can take the form of a single layer in
the shape of a solid circular disc.
The silicon dioxide layer 34 can be deposited, to a thickness of typically
about 1,000 .ANG., by conventional plasma or chemical vapor deposition,
followed by conventional selective masking and etching to form apertures
in the silicon dioxide for the electrode contacts 37, 38, 47, and 48. The
n.sup.+ zones can then be formed by alloying gold with a donor impurity,
such as tin or germanium. The electrical conducting layers 61, 62, 63, and
64 can all be simultaneously formed by deposition of gold, followed by
selective masking and etching to form the desired metallization stripe
geometry for interconnection with device elements or power supplies. In
addition, as indicated in FIGS. 4 and 6, first and second insulated gate
electrode layers 51 and 52 are also formed, ordinarily simultaneously with
the metallization layers 61, 62, 63, and 64. Alternatively, Schottky
barrier electrode contacts to the epitaxial layer 33 can be used instead
of the insulated gate electrode layers 51 and 52.
During operation of the device 30, a supply voltage of V.sub.o is applied
to metallization layer 37 in the presence of a magnetic field B.
Illustratively, the supply voltage V.sub.o, applied to metallization 61
and hence to n.sup.+ zone 35, is about 0.05 volts; the magnetic field B is
about 9 Tesla directed perpendicular to plane of FIG. 4; and the ambient
temperature T is aout 4.degree. K. An output voltage V.sub.out equal to
V.sub.o is developed and detected at the metallization layer 64 for use by
utilization means 70. Upon application of sufficient input voltages
V.sub.in and VHD in, respectively, each different from zero, to gate
electrodes 51 and 52, the output voltage V.sub.out suddenly drops, i.e.,
switches to zero (i.e., ground). Conversely, V.sub.out suddenly returns to
V.sub.o when the voltages V.sub.in and VHD in, return to zero (or float).
Input voltages V.sub.in and VHD in should be selected, for beneficial
operating margins, to satisfy V.sub.in =-VHD in; but this is not essential
and other relative values for these voltages can be used. Moreover, the
second gate electrode 52 (and hence VHD in as well) may be completely
omitted, at some possible sacrifice of margins of operation and of
reliability of switching. In such a case the input voltage signal V.sub.in
can be of either polarity and of the order of V.sub.o in magnitude.
It should be recognized that the device 30 can function as an inverting
logic element. Specifically, when the input signal V.sub.in is
sufficiently "high", i.e., binary digital "1", the output voltage
V.sub.out is at ground potential or "low", i.e., binary digital "0"; and
when the input signal V.sub.in is ground or "low", i.e., binary digital
"0", the output voltage V.sub.out is equal to V.sub.o or "high", i.e.,
binary digital "1". Accordingly, the device 30 functions as an inverter
logic element.
FIG. 7 symbolically shows the device 30 thus functioning as a logic
element, with the supply voltage V.sub.o, input logic signal A
corresponding to the input signal voltage V.sub.in of FIG. 4, and with
output NOT A (also denoted by A corresponding to the output voltage
V.sub.out, this output NOT A=A0 being the inversion or logical complement
of the input; i.e., when input A is "0", output A0 (i.e., NOT A) is "1",
and when input A is "1", output A0 (i.e., NOT A) is "0".
FIG. 8 symbolically shows the device 30 with two independent inputs A and
B, whereby the outputs is A33 B0 (i.e., NOT A and NOT B, or simply NOR)
because if and only if both inputs A and B are "low" or "0" then a current
will percolate around the ring of the device 30 and thus produce an output
which is "high" or "1". In other words, the NOR logic function is
performed by the arrangement in FIG. 8.
FIG. 9 shows an arrangement to arrive at the OR logic function, using two
ring devices 100 and 200 each in accordance with the device 30 of FIG. 4
except for configuration of input(s). The device 100 has two independent
inputs A and B, just as the device 30 in FIG. 8. The NOR output (A33 B of
this device 100 in fed as input to the device 200 which inverts it to A+B,
that is, A OR B. Hence, the output of the two ring devices (A+B) will be
"1" if and only if either A or B (or both) is "1".
FIG. 10 shows an arrangement to arrive at the AND NOT logic function, using
two ring devices each according to the device 30 except for input
configuration. Finally, FIG. 11 shows an arrangement to arrive at the AND
function, using three such ring devices.
The switching device 30 (FIG. 4) can also be fabricated in silicon MOS
(metal-oxide-semiconductor) technology, as shown in FIGS. 12-15. Here a
silicon MOS switching device 300 includes a silicon body 301 serving as
substrate for this device. The body 301 is essentially monocrystalline
p-type silicon with a substantially uniform acceptor impurity
concentration of the order of typically 10.sup.15 acceptor per cm.sup.3.
Upon a major planar surface 301.5 of the silicon body oriented (1,0,0) is
a thermally grown silicon dioxide layer 301, typically in the range of
about 500 to 1,000 .ANG. thick. Localized diffused n.sup.+ zones 303, 304,
305, and 306 are located at the surface of the body 301 contiguous with
apertures 313, 314, 315, and 316, respectively, through the oxide layer
301. These n.sup.+ zones are contacted by electrodes 323, 324, 325, and
326, respectively, typically of doped n.sup.+ polycrystalline silicon
overlayed with aluminum. These n.sup.+ zones 323, 324, 325, and 326
(typically formed by arsenic impurity implantation and diffusion) serve
the same respective functions in the device 300 (FIGS. 12 and 13) as do
the n.sup.+ zones 35, 36, 45, and 46, respectively, in the device 30
(FIGS. 4 and 5). On the other hand, gate electrodes 323 and 326 serve
similar respective gating functions in the device 300 as do the gate
electrodes 61 and 64, respectively in the device 30; whereas the
electrodes 324 and 325 of the device 300 are connected in common to ground
during ordinary operation, that is, they are connected to substrate
potential of the body 301; and these electrodes 324 and 325 thus function
similarly as does the electrode 34 (FIG. 5) in the device 30.
An amorphous .alpha.-silicon layer 330 coated with a chemically vapor
deposited layer of silicon dioxide 331 defines a ring structure for the
device 300 similarly as do the gallium aluminum arsenide layers 32 and 33
for the device 30, except for an additional metallization electrode
contact 327 (FIGS. 12 and 14) to the amorphous silicon layer 330 through
an aperture 317 in the oxide layer 331. Typically this electrode 327 is of
polycrystalline silicon overlayed with aluminum. Finally, electrodes 328
and 329 (FIGS. 12 and 15), also typically of polycrystalline silicon
overlayed with aluminum, serve the same function as do electrodes 51 and
52 (FIGS. 4 and 6) in the device 30.
The purpose of the amorphous silicon layer 330 in the device 300 is to
ensure the continued existence of an inversion layer in the underlying
silicon. Accordingly, this amorphous silicon layer 330 is initially
charged by applying at room temperature suitable potential to it by
contacting the electrode 327 to a suitable voltage source for a sufficient
charging time, typically about 5 volts for a time of the order of an hour.
This charged amorphous silicon layer 330 will then remain charged at
operating temperatures (about 4.2.degree. K.) for a time typically of the
order of years after disconnecting the voltage source. Because of the
larger effective mass of silicon, however, the magnetic field should be
about 3 times as large as in gallium arsenide for the same switching
speed. The low field mobility of electrons in the inversion layer at
operating temperature ordinarily should be at least about 10,000 cm.sup.2
/volt-second, for proper operation.
It should be understood that many similar devices 300 can be fabricated on
a single silicon body 301 in accordance with integrated circuit
techniques. The overall diameter of the ring shaped portion formed by the
amorphous silicon layer can be as large as 1,000 micron or as small as a
few micron, or less, depending upon the state of the fabrication art.
Neighboring devices, as well as the interior portion of the ring, can be
protected from spurious inversion layers by conventional implantation of
channel stop p-type regions at the surface 301.5 of the silicon body 301,
as well as by thick field oxide as known in the art of silicon integrated
circuits.
FIG. 16 shows a pair of square ring devices 400 and 500, each similar to
(except for square ring configuration) the device 30 or 300, in an
overlapping geometry, thereby avoiding the need for an added input line.
The ring devices 400 and 500 can be circular as before, or can have any
other convenient contour. Each of these rings is built at a slightly
different level, i.e., different distance from the ground plane on the
other side of the semiconductor body, so that a region of overlap is
achieved. In this configuration, the presence vs. absence of percolating
current in one of the rings affects the percolation in the other, in that
only one of the rings can percolate at one time. Accordingly, the pair of
ring devices 400 and 500 forms a bistable switching element. Moreover,
several such ring devices can overlap a single such ring device, and a
multiplicity of such ring devices can overlap in pairs, triplets, etc., in
an array or pattern according to a desired logic function.
FIGS. 17 and 18 illustrate a multiply connected ring device 600, comprising
a central branch 601 and a pair of outer branches 602 and 603, together
with source region 610 and drain region 611, as well as overlying control
electrode 612 to which input voltage V.sub.in can be applied. When
V.sub.in =0, the current percolates in a first percolation state along the
central branch 601 and the outer branch 602 but not the outer branch 603
(for a magnetic field directed into plane of drawing), and V.sub.out
=V.sub.o. When V.sub.in goes through V.sub.o /2 to V.sub.o, all current
percolates in a second percolation state along the central branch 601 and
the outer branch 603 but not 602, and V.sub.out =0. Thus, the output
switches from V.sub.o to 0. Indeed, V.sub.in can be varied from a value
slightly less than V.sub.o /2 to a value slightly more than V.sub.o /2 in
order to switch the percolation from the outer branch 602 to the outer
branch 603, and hence in order to switch V.sub.out from V.sub.o to 0.
Thereby the energy required to switch the device 600 is reduced. Moreover,
since there is no source to drain current when V.sub.in is greater than
V.sub.o /2, i.e., during the state of percolation where V.sub.out =0, a
substantial saving in energy consumption can therefore result.
Although the invention has been described in terms of specific embodiments,
various modifications can be made without departing from the scope of the
invention. For example, instead of the semiconductor epitaxial gallium
aluminum arsenide structure shown in FIG. 5, the epitaxial structure
disclosed in the aforementioned paper of D. C. Tsui and A. C. Gossard can
be used. Indeed, any semiconductor structure can be used which furnishes
an inversion layer that exhibits a zero resistance state and that can be
shaped into an annular ring geometry. Accordingly, instead of inversion
layers formed at heterojunction interfaces of gallium arsenide with
gallium aluminum arsenide, other combinations of Group III-V or Group
II-VI materials can be used, such as indium gallium arsenide with indium
phosphide, tin telluride with lead selenide, or cadmium telluride with
mercury cadmium telluride (for which the required magnetic field would be
only about 1 Tesla or less). Moreover, one can also use the interface of
silicon dioxide with silicon, where an inversion layer forms in the
silicon that exhibits a zero resistance state, the required quantizing
magnetic field, however, being somewhat larger (by a factor of about 2)
for silicon than for gallium arsenide.
Also, instead of circular rings, other ring shapes can be used, such as
rectangular or square rings (as indicated, for example, by the shapes of
the devices illustrated in FIGS. 16 and 17).
Appendix
Workers in the art have found that the quantized values r.sub.1, r.sub.2,
r.sub.3, etc., of (transverse) Hall resistivity .rho..sub.xy /t satisfied:
r.sub.1 =h/2e.sup.2
r.sub.2 =h/4e.sup.2
r.sub.3 =h/6e.sup.2 etc.
or, in general:
r.sub.i =h/2ie.sup.2 (6)
where h is Planck's constant, e is the charge of an electron, and i is an
integer (i=1, 2, 3, . . . ).
The interpretation or explanation of this quantized phenomenon of Hall
resistivity has been given by various workers in terms of the existence of
quantized energy levels in a uniform magnetic field, so-called Landau
energy levels, produced in response to the application of the magnetic
field B. These levels and their associated quantized electronic states are
described more fully, for example, in L. D. Landau and E. M. Lifshitz,
Quantum Mechanics, Non-Relativistic Theory, (Third Edition, 1977), pp.
453-458. In the special case of a low temperature T of operation
(ordinarily well below liquid nitrogen temperature) and a small thickness
(in the z-direction) of the region of electron confinement--as afforded by
an inversion layer, for example, typically only about 50 .ANG. thick--the
quantum states corresponding to Landau levels of differing electron
momenta p.sub.z in the z-direction are separated by energies which are so
much greater than kT (k=Boltzmann contact) that only the quantum states
associated with Landau levels of lowest energy are ever occupied at that
low temperature of operation; all electronic states at levels
corresponding to higher values of momentum p.sub.z, and hence of higher
energy, remain completely unoccupied during operation. Thus, for all
practical purposes, no electronic transitions due to thermal effects can
occur through any changes in momentum component p.sub.z ; therefore,
motion of the electrons in the z-direction is of no importance (is "frozen
out") during operation, and the resulting system of electrons in the
inversion layer behaves as a two-dimensional (x-y) electron system or "2-D
electron gas." On the other hand, the electronic motion in the x-y plane
corresponds to quantized Landau levels, named after their discoverer, L.
D. Landau. The levels are characterized by quantized energy E.sub.n
satisfying:
E.sub.n =(n+1/2)hf.sub.c (7)
where n=0, 1, 2, 3, . . . , and is called the energy "quantum number"; and
where f.sub.c is the "cyclotron frequency":
2.pi.f.sub.c =eB/m (8)
Thus, neighboring Landau levels (E.sub.n, E.sub.n+1) are separated by
energy hf.sub.c.
Physically, f.sub.c is the frequency of the uniform circular motion of a
free electron of charge e and of effective mass m in a uniform magnetic
field B. For electrons in solids, this effective mass m is the so-called
reduced mass, typically less than the free electron mass by a factor of
about 0.07 in gallium arsenide. It should be noted that for each value of
(integer) quantum number n, the corresponding Landau energy level E.sub.n
is very "degenerate"; that is, to each value of energy E.sub.n, there are
very many quantum states with this same value of energy. More
specifically, for given E.sub.n (with p.sub.z in its lowest state), the
number of states N.sub.n is equal to:
N.sub.n =2eBS/h (9)
where S is the area (wL) in the x-y plane within which the two-dimensional
motion of the electrons in a uniform magnetic field B (in the z-direction)
is confined, for example, by the inversion layer. The factor of 2 is
caused by the two possible spins of an electron. All effects, if any, due
to spin-splitting of levels will be neglected for clarity of presentation;
such splitting would not change the results qualitatively. Note that
N.sub.n is independent of n; that is, each level contains the same number
of states. On the other hand, at low temperatures T for which kT is small
compared with hf.sub.c --i.e., the thermal energy is small compared with
the separation of neighboring Landau levels--the separation hf.sub.c
between neighboring Landau levels is then large compared with kT, so that
thermal agitation or scattering effects are not sufficient to induce
electronic transitions between energy levels of differing energy--that is,
for example, between successive Landau energy E.sub.n and E.sub.n+1. Thus,
for a given value of f.sub.c and hence for a given applied magnetic field
B, if the Fermi level E.sub.F falls well between (i.e., at least several
kT from both E.sub.n and E.sub.n+1) the two successive levels E.sub.n and
E.sub.n+1, then thermal scattering effects are not strong enough to induce
electronic transitions between these two levels or, a fortiori, between
either of these levels and any others. Accordingly, in such a situation
there is no significant electron scattering, and hence the longitudinal
("parallel") electrical conductivity .sigma..sub.L (but not the transverse
conductivity .sigma..sub.T) vanishes, where .sigma..sub.L symmetric case
is defined in terms of current density (j.sub.x, j.sub.y) by the
relationships:
j.sub.x =.sigma..sub.L E.sub.x +.sigma..sub.T E.sub.y
j.sub.y =-.sigma..sub.T E.sub.x +.sigma..sub.L E.sub.y (10)
The vanishing of .sigma..sub.L thus immediately leads to simpler
relationships of current density to electric field:
j.sub.x =.sigma..sub.T E.sub.y
j.sub.y =-94.sub.T E.sub.x (11)
On the other hand, in the situation (FIG. 2) where j.sub.y itself vanishes,
i.e., j.sub.y =0, it then follows that E.sub.x also vanishes, i.e.,
E.sub.x =o, even though j.sub.x does not necessarily vanish. Accordingly,
in this situation where .sigma..sub.L vanishes, the voltage drop,
V=E.sub.x 1, will also vanish; and also .rho..sub.xx =E.sub.x /j.sub.x
vanishes, i.e., .sigma..sub.xx =o. Summarizing the conditions in FIG. 2 in
the situation where the Fermi level falls well between two successive
Landau levels:
.sigma..sub.L =0
j.sub.y =0
E.sub.x =0
.rho..sub.xx =0 (12)
Accordingly, in this situation where the longitudinal conductivity vanishes
(.sigma..sub.L =0), since also E.sub.x =0 the power dissipation, P=j.sub.x
E.sub.x +j.sub.y E.sub.y, will also vanish, even in the presence of
non-vanishing current density j.sub.x in the x-direction.
By varying the applied magnetic field B, a Landau level, such as E.sub.n,
can be made to approximate the Fermi level, that is, to within kT or less;
under the influence of that field B, the longitudinal resistivity
.rho..sub.xx no longer vanishes.
On the other hand, under the influence of a magnetic field B for which the
longitudinal resistivity vanishes, the (two-dimensional) electron system
is said to be in a "zero-resistance state." The allowed quantized values
r.sub.1, r.sub.2, r.sub.3, . . . of transverse resistivity .rho..sub.xy in
these zero-resistance states can be theoretically derived from the
following considerations. The lowest Landau energy level has an energy
E.sub.o given by E.sub.o =(1/2)hf.sub.c =heB/4.pi.m. At a fixed
temperature T, starting with a magnetic field B so large that even this
lowest Landau level E.sub.o lies above the Fermi level E.sub.F by more
than kT, and then reducing the field B until this lowest Landau level lies
below the Fermi level E.sub.F by more than kT (but the next lowest Landau
level, E.sub.1 =(3/2)hf.sub.c, does not lie below the Fermi level
E.sub.F), then every one of the very many electronic quantum states
associated with the level E.sub.o is filled, and thus each such state can
contribute two electrons (two spins) for transporting charge through the
body and thus for contributing to the current; thus, from Equation (9), a
total of N=2eBS/h electrons are supplied by all these states of Landau
energy level E.sub.o to the electrical conduction capability of the body.
This situation, where the Fermi level falls (approximately midway) between
the Landau energy level E.sub.o =(1/2)hf.sub.c and E.sub.1 =(3/2)hf.sub.c,
is illustrated in FIG. 19. Here the bottom of the conduction band E.sub.c
is plotted against distance z in the semiconductor body having a
heterojunction at z=z.sub.o (where an inversion layer occurs).
In order for a zero resistance state to exist, for example, with the Fermi
level following midway between the Landau levels E.sub.o =(1/2)hf.sub.c
and E.sub.1 =(3/2)hf.sub.c, the average thermal energy kT (k=Boltzmann's
constant, T=temperature) must be considerably less than the energy
separation of the Fermi level from either level E.sub.o or E.sub.1. Thus,
for such a zero resistance state to exist, kT must be considerably less
than 1/2hf.sub.c =heB/4.pi.m; or, in other words, for an effective mass m
of about 0.07 electronic masses as in gallium arsenide, the temperature T
must be considerably less than about 9.5.degree. K./Tesla. For a magnetic
field B of about 9 Tesla, the temperature T must thus be considerably less
than about 85.degree. K. for a zero resistance state to exist.
In the zero resistance state (FIG. 18), from elementary considerations, the
current I (in the x-direction) due to the N electrons in the filled level
E.sub.o is given by:
I=(N/St)ev.sub.x wt (13)
where vHD x is the average drift velocity in the x-direction of the
electrons in the (degenerate) Landau level E.sub.o. Since N=2eBS/h, it
follows that the resulting electrical current I is given by:
I=2e.sup.2 Bv.sub.x w/h (14)
Due to the electron drift in the x-direction (FIG. 2), a magnetic force
evHD xB drives the electrons to the bottom edge 14 of the bar 10, thereby
resulting in an accumulation of electrons thereat and thus also resulting
in a static electric field E.sub.y parallel to the y-axis. Equilibrium, as
is well known, requires vanishing of the average Lorentz force in the
y-direction, e(E.sub.y -vHD xB), so that
v.sub.x =E.sub.y /B (15)
On the other hand, the Hall voltage V.sub.H is given by:
V.sub.H =E.sub.y .multidot.w, (16)
so that the average drift velocity (in the x-direction) vHD x is given by:
v.sub.x =V.sub.H /wB (17)
Accordingly, the current I is given by:
I=2e.sup.2 V.sub.H /h (18)
Thus it follows that the ratio of I.sub.k to V.sub.H is given by:
I/V.sub.H =2e.sup.2 /h (19)
Accordingly, the electrons of the lowest Landau level E.sub.o contribute a
conductance equal to 2e.sup.2 /h. Similarly, by decreasing the magnetic
field further so that the next lowest Landau level E.sub.1 =3/2hf.sub.c
falls below the Fermi level (but the level E.sub.2 =5/2hf.sub.c does not),
it follows that the conductance then increases (by virtue of the filling
of the Landau level E.sub.1 in addition to E.sub.o) by the same amount
2e.sup.2 /h, and thus the total conductance becomes 4e.sup.2 /h. Thus, in
general, if the Fermi level falls between the n'th and (n+1)'th Landau
level, the ratio of the current I to Hall voltage V.sub.H will be given
by:
I/V.sub.H =2(n+1)e.sup.2 /h (20)
Thus, the reciprocal ratio will be given by:
V.sub.H /I=h/2(n+1)e.sup.2 (21)
Accordingly, the quantized values of transverse resistivity (r.sub.i ; i=1,
2, 3, . . . ) will be given by Equation (5), with i=n+1. In addition, the
current I is thus seen, for any given quantized resistance state, to be
independent of the width of the bar 10 for a given Hall voltage V.sub.H,
this current I being dependent only upon the number (n+1) of (completely)
filled Landau levels and upon the Hall voltage V.sub.H itself.
It is believed that in the presence of the electric field E.sub.y in the
bar 10, the wave function of each of the (many) quantum states in a given
(degenerate) Landau level E.sub.n has a (ordinarily slightly) different
energy (due to the electrical potential eE.sub.y Y) and has a wave
function in the form, as a function of x, of an imaginary exponential
(plane wave propagating in the x-direction) and, as a function of y, the
form of the k'th eigenfunction of a linear harmonic oscillator centered at
y.sub.o, with the allowed values of y.sub.o running between those
corresponding to the top edge 13 and the bottom edge 14 of the rod 10 in
steps .delta.y.sub.o. Thus the number of states N.sub.n (two spins for
each y.sub.o) for a given level E.sub.n is now given by:
N.sub.n =2w/.delta.y.sub.o (22)
But, N.sub.n is also given by Equation (5) as 2eBS/h; so that:
2w/.delta.y.sub.o =2eBwL/h (23)
and hence:
.delta.y.sub.o =h/eBL (24)
It is convenient to introduce the Landau length a.sub.H, that is, a
distance measure of the extent or dispersion (region of appreciable value
different from zero) of the wave functIt is convenient to introduce the Landau length a.sub.H, that is, a
distance measure of the extent or dispersion (region of appreciable value
different from zero) of the wave function in the y-direction for level
E.sub.o :
a.sub.H.sup.2 =h/(2.pi.m)(2.pi.fc)=h/2.pi.eB (25)
as given, for example, in L. D. Landau and E. M. Lifshitz, Quantum
Mechanics: Non-Relativistic Theory (Third Edition, London, 1977), p. 457.
It is then seen that eB=h/2.pi.a.sub.H.sup.2 and that therefore:
.delta.y.sub.o =2.pi.a.sub.H.sup.2 /L (26)
For example, with a magnetic field of 10 Tesla, a.sub.H is about 80 .ANG..
Accordingly, with this field and for a length L of the order of 10 micron,
.delta.y.sub.o is then of the order of 0.4 .ANG.; that is, successive
electron paths or orbits are separated from each other by only 0.4 .ANG.
in the y-direction, the term "path" or "orbit" referring to regions of
widths of the order of a.sub.H (i.e., .delta.y.sub.o is of the order of 80
.ANG. in width in this example).
Each of these electron paths is believed to be centered at and to follow
along a separate equipotential line in the "two-dimensional" electron
system defined by the inversion layer. These equipotential surfaces are
determined, at least in part, by the field E.sub.y caused by the surface
distribution of charge on the edges of the ring under the influence of the
magnetic field acting on the moving electrons.
It is believed that so long as even but a single equipotential line extends
across the entire length of the bar 10 from one electrode contact to the
other, with sufficient distance margin on either side to accommodate a
Landau level orbit (i.e., the equipotential is separated by at least a
distance of the order of a.sub.H from either edge of the bar 10), then a
macroscopic number (of order L/a.sub.H) of orbits can percolate
(uninterrupted) around the ring and thus the zero resistance state
persists even in the presence of local perturbations of potential in the
bar (due to such causes as, for example, random impurities therein). It is
further believed that any and all such percolating orbits are destroyed by
an added sufficient electrostatic field of the gate electrode, and hence
that the zero resistance state is destroyed by sufficient input signal
voltage applied to the gate electrode.
It should be noted that when sufficiently even lower temperatures are used,
the gyromagnetic electron spin energy can become significant in splitting
can Landau level into two separate levels and thereby introducing a factor
of 1/2 in Equation (20), for example.
* * * * *
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