The present invention relates to a quantum Turing machine formed using a superconductor.
As a technique of applying the phase difference between multiple superconducting order parameters to electronics, with respect to superconducting electronics that utilize phase difference solitons created between plural types of superconducting electrons, there is the disclosure of Patent Document 1 (Japanese Patent Application Publication 2003-209301) that precedes the present invention.
On the other hand, in quantum Turing machines, various quantum bits have been devised. Methods that use nuclear spin, and methods that use the energy levels of atoms are representative of these. There have also been attempts to create artificial atoms using semiconductors. Quantum bits based on ordinary superconductors have also been proposed.
In the superconducting electronics disclosed in the above Patent Document, the phase difference soliton S between bands that constitutes an information bit has been difficult to manipulate because of its ubiquity in connected circuits. To facilitate bit manipulation, it has to be confined in a spatially small region.
The above Patent Document also provided a method of constituting quantum bits by producing a state in which quanta are superimposed. However, a basic computation method that uses this quantum bit to constitute a quantum Turing machine has not been provided.
With respect to quantum bits that have been proposed up until the present for producing a quantum Turing machine, whatever the proposed method, multiple-bit implementation is difficult with current technology, and it is considered that practical application will take 100 years or more.
Also, with quantum bits that do not use a macroscopic quantum state such as a superconducting state, a superimposed state for making a quantum Turing machine function is easily broken down by interaction with the environment, making it impossible to obtain enough time to use the quantum Turing machine to execute a quantum algorithm.
This invention was devised in view of the above, and has as its object to provide a quantum Turing machine that can easily constitute a quantum bit and surely execute a basic logical operation, and has multiple-bit capability and, moreover, can ensure sufficient time for executing a quantum algorithm.
To attain the above object, the present invention comprises a quantum Turing machine formed using a superconductor, and is constituted by a quantum bit created by utilizing phase differences between superconducting order parameters existing at each of multiple bands of the superconductor.
The utilization of phase differences between the superconducting order parameters also includes utilization of a phase difference soliton created between plural types of superconducting electrons.
In addition to the invention constituted as described above, the above quantum bit is a quantum bit localizing a phase difference soliton in a line circuit that includes a line circuit main body formed of the superconductor and well-shaped portions formed with a reduced line-width at at least two positions on the line circuit main body.
The above quantum bit is a quantum bit localizing a phase difference soliton in a ring that includes a ring main body formed of the superconductor and well-shaped portions formed with a reduced line-width at at least two positions on the ring main body.
The above quantum bit is a quantum bit constituted by affixing a first auxiliary ring a first well-shaped portion of above the double well-shaped portions has on a portion thereof to the ring, by affixing a second auxiliary ring the second well-shaped portion has on a portion thereof to the ring, and by also providing a switch on each of the rings, the first auxiliary ring and the second auxiliary ring.
The present invention also includes achieving realizing unitary transformation of a quantum bit by localizing a phase difference soliton in the ring and operating each switch of the first auxiliary ring and the second auxiliary ring.
The present invention also includes performing the unitary transformation of the quantum bit by first, within the ring, creating a phase difference soliton in the ring by switching on the switch of that ring while applying a magnetic field corresponding to phase slip produced by a phase difference soliton, next, switching on the switch of an auxiliary ring selected from one of the first and second auxiliary rings, applying a magnetic flux as an external field inside the selected auxiliary ring, switching off the switch of the selected auxiliary ring, and switching it on again after a prescribed time has elapsed.
The present invention includes constituting a control NOT gate between two of the quantum bits by arranging the above quantum bits in two parallel lines, superimposing a balance ring equipped with a switch on a first auxiliary ring of the quantum bit on one side, and also superimposing an interaction ring equipped with a switch across both a second auxiliary ring of the quantum bit on one side and a second auxiliary ring of the quantum bit on the other side.
The present invention also includes executing operation of the control NOT between the above two quantum bits by, first, creating a phase difference soliton within each ring of the two quantum bits by switching on the switch of that ring while applying a magnetic field corresponding to phase slip produced by a phase difference soliton, and after that, switching on the interaction ring switch.
The present invention also includes an arbitrary number of the above quantum bits for multiple-bit implementation.
The present invention also localizes the above phase difference soliton with a probability of either 0% or 100% and performing classic digital logic that does not use a superimposed state.
The present invention also includes a quantum Turing machine formed using a superconductor, constituted by a quantum bit created by utilizing plural types of superconducting order parameters existing in a same band of the above superconductor.
By devising the configuration of the electric wire of superconduction, a superconducting soliton S having multiple superconducting order parameters can be localized, bit manipulation becomes easy, and quantum bits easily consist of quantum Turing machines of this invention. Also, basic logical operation can be surely executed. Also, multiple-bit and integration are possible. Furthermore, using the macroscopic quantum state that is a superconductor makes it easier to maintain coherence and can ensure sufficient time for executing a quantum algorithm.
a) is a diagram showing the state of a soliton in the left well-shaped portion of the electric line of
a) is a diagram for explaining a mode of modulating the tunneling probability of a soliton constituting a quantum bit using an auxiliary ring.
b) is a diagram showing conceptually potential energy with respect to the soliton.
Embodiments of this invention will be described based on the drawings.
In this invention, a quantum Turing machine is constituted by a quantum bit formed utilizing phase differences between superconducting order parameters existing at each of multiple bands of a superconductor. Here, this utilization of phase differences between superconduction order parameters is, for example, utilization of a phase difference soliton S created between plural types of superconducting electrons.
First, a configuration that localizes this phase difference soliton S will be explained. As shown in
When switch SW is switched on while applying a magnetic field Φsoliton corresponding to the phase slip Θsoliton based on the phase difference soliton S, soliton S is produced in the ring R (
The soliton S thus created has the same energy wherever it is in the ring R, so it is ubiquitous in the ring R. The existence probability thereof will comply with a quantum-mechanical probability distribution.
Next, an example of a shape devised for localizing the soliton S is described. In
In
In this way, the soliton S can be localized by a process of partial narrowing or the like of the electric line C.
Next, an example of using the soliton S thus localized by the above method to constitute a quantum bit is described.
Narrowed portions (well-shaped portions) W1, W2 are formed left and right at two positions on the electric line C, as shown in
[Equation 1]
H=VLaL+aL+VRaR+aR+TA(aL+aR+aR+aL) (1)
If one soliton S is inserted into such a Hamiltonian H, it becomes a quantum bit. If the wave function when the soliton S is on the left is ΨL, and the wave function when on the right is ΨR, the wave function Ψ(t) of this quantum bit is expressed by the following equation (2).
[Equation 2]
Ψ(t)=cL(t)ψL+cR(t)ψR (2)
In the above equation (2), cL(t), cR(t) are coefficients that change with time, complex numbers that satisfy the following equation (3).
[Equation 3]
|cL((t)|2+|cR(t)|2=1 (3)
Incidentally, when a quantum Turing machine is realized using a quantum bit, the qualities required of the quantum bit are the two points
First, an example of a method of realizing unitary transformation of one quantum bit is described.
As shown in
where,
χB=(ψL+ψR)/√{square root over (2)}
χA=(ψL−ψR)/√{square root over (2)}
In equation (4), usually directly after switching on (t=0) is cA(t=0)=0.
As shown in
Then, as shown in
[Equation 5]
ΦLex
Based on the boundary conditions, when there is a soliton S in the first well-shaped portion W1 of the ring R0, the following equation (6) applies,
[Equation 6]
ΦLex+μLIL+Φsoliton=0 (6)
and the following equation (7) applies when there is a soliton S in the second well-shaped portion W2.
[Equation 7]
ΦLex+μLIL=0 (7)
In the above equations (6) and (7), μL is the coefficient of self-induction of the first auxiliary ring RL, IL is the induced superconducting electric current induced in the first auxiliary ring RL, and Φsoliton is the amount of magnetic flux for compensating for the soliton S based phase slip.
When there is a soliton S, energy rises by
and when there is no soliton S, energy rises by
Here, if
using equation (1), the system Hamiltonian H will be the following.
[Equation 11]
H=(VL+VL(1))aL+aL+VRaR+aR+TA(aL+aR+aR+aL)
If the following,
[Equation 12]
|VL+VL(1)−VR|>>|TA|
then
[Equation 13]
ΔV=VR−(VL+VL(1))
is maintained, and the system wave function Ψ(t) will take the following form.
In the above equation (14), ta is the time at which the switch SW1 of the first auxiliary ring RL is switched on.
Next, an example will be used to explain how the wave function Ψ(t) evolves over time with the switch SW1 of the first auxiliary ring RL being on or off.
In
[Equation 15]
Ψ(t)=(ψL+ψR)/√{square root over (2)} (15)
Next, it is assumed that the switch SW1 of the first auxiliary ring RL is switched on at time t=ta. At this time, the evolution over time will be as follows.
Switch SW1 of the first auxiliary ring RL is left switched on until
time is t=tb. When it becomes this time, it will be
so switch SW1 is switched off.
Wave function Ψ(t) in t=tb is expressed by the following equation (19).
After switching SW1 off, evolution over time in t>tb will again revert to the form of equation (4), and if left at
will become
and if the switch SW1 of the first auxiliary ring RL is again closed at t=tb, the evolution over time from there on is left at:
will become the following.
α0 and β0 can be arbitrarily selected from 0 to 2π, so equation (24) provides n arbitrary unitary transformations with respect to the one quantum bit that is a component of the quantum Turing machine. That is to say,
Next, a method is described of fabricating a control NOT gate between two quantum bits that is required to create a quantum Turing machine. Taking the quantum bit explained with reference to
That is, as shown in
For simplicity, here, it is assumed that it has been designed so that the coefficient of self-induction of the interaction ring M and the coefficient of self-induction of the balance ring N are the same. This coefficient of self-induction is taken to be μ coupling. Also, it is assumed that after being electrically insulated, the first auxiliary ring RL of quantum bit B and the balance ring N are closely vertically superimposed so that only magnetic flux generated in the first auxiliary ring RL of quantum bit B is sensed.
The interaction ring M and the balance ring N are both taken to be constituted of single-order parameter superconductor, and that a superconducting current flows that cancels out all of the magnetic flux generated in the auxiliary rings RL, RR of quantum bits A, B. That is, the route taken by the magnetic flux is that it passes through the interior of the auxiliary ring RL of each of the quantum bits A, B, and inside the interaction ring M is repulsed, passing to the outside of the interaction ring M.
Then, the operation of the control NOT between the two quantum bits A, B is executed by, first, creating a soliton S in the ring R0 of each of the quantum bits A, B while applying in each ring R0 a magnetic field corresponding to the phase slip Θsoliton based on the phase difference soliton S, and then switching on the switch SW4 of the interaction ring M.
The state realized at this time is a in which the states cited in
Each of the states defined in
Here, for simplicity, the external field applied to auxiliary rings RL, RR is omitted. Also, regarding the auxiliary rings RL, RR of the quantum bits A, B as having the same coefficient of self-induction, energy produced by the ring-shaped superconducting current was subtracted beforehand as an offset. Also, the energy of the magnetic field based on the coefficient of mutual induction was also ignored for simplicity.
TA is the tunneling probability of the soliton S at quantum bit A, and TB is the tunneling probability of the soliton S at quantum bit B. Also,
is the energy produced by the interaction ring M, balance ring N. If ε, which is further offset, is deducted from the above matrix equation (25), we get the following equation (27).
Next, if TA<<TB, the following equation (28) applies.
Regarding TA<<TB, prior to effecting interaction of the quantum bits A, B, the connections of the electric lines constituting quantum bits A, B can be changed and the lines modified, such as by making them longer. Also, as described below, the auxiliary rings can be used to modify the tunneling probability.
In addition, when TB<<ε, we get the following.
The time-evolution of the system wave function Ψ(t) is expressed by the following equation (30).
In the above equation (30),
[Equation 31]
c00, c01, c10+11, c10−11
is a complex number constant. Particularly when
|10> is transformed to |11>, and |11> to |10>.
That is, at this time, the unitary transformation matrix with respect to wave function will be the following
where, the phase term shown below is associated with this equation.
[Equation 34]
exp(−iθ0), exp(−iθ1), exp(−iθ2)
This phase term can be made 1 by unitary transformation with respect to the above one quantum bit. Executing this unitary transformation makes it possible ultimately to realize the control NOT gate
that is the object.
In the above, with respect to the setting of the tunneling probability to TA<<TB, the connections of the electric lines constituting quantum bits A, B are changed and the lines modified, such as by making them longer, prior to effecting interaction of the quantum bits A, B, but the auxiliary rings can also be used to modify the tunneling probability. As shown in
While the above examples have been described with reference to one or two of the quantum bits, multiple-bit implementation is possible by provision of an arbitrary number of the quantum bits.
A bit can be read by measuring the magnetic flux generated in the auxiliary rings RL, RR. After having once been read, the soliton S can be handled as a classical information bit by modifying the site energy of the soliton S to make it greater than the tunneling energy. That is, taking the localizing probability of the phase difference soliton S as either 0% or 100%, classical digital logic which a superimposed state isn't used in can be effective.
Also, there are cases in which the multiple superconducting order parameters used in the present invention exist not only in multiple bands, but in the same band. For example, if a superconductor is a d-wave superconductor, as shown in
As described in the foregoing, with the quantum Turing machine of this invention, a soliton S can be localized in a superconductor having multiple superconducting order parameters by contriving the shape of a superconducting electric line.
Therefore, it becomes easy to manipulate bits, making it possible to facilitate quantum bit constitution. It is also possible to surely execute basic logical operation processing such as unitary transformation and control NOT operations. Also, multiple-bit and integration are possible. Furthermore, using the macroscopic quantum state that is a superconductor makes it easier to maintain coherence and can ensure sufficient time for executing a quantum algorithm.
Number | Date | Country | Kind |
---|---|---|---|
2003-316252 | Sep 2003 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2004/013093 | 9/2/2004 | WO | 00 | 1/16/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2005/027234 | 3/24/2005 | WO | A |
Number | Name | Date | Kind |
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6670630 | Blais et al. | Dec 2003 | B2 |
6885325 | Omelyanchouk et al. | Apr 2005 | B2 |
7042004 | Magnus et al. | May 2006 | B2 |
20050107262 | Tanaka et al. | May 2005 | A1 |
Number | Date | Country |
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2000-068495 | Mar 2000 | JP |
2003-209301 | Jul 2003 | JP |
Number | Date | Country | |
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20070120727 A1 | May 2007 | US |