The present disclosure relates generally to quantum computation, and more particularly to superconducting topological qubits protected from noise.
Superconducting qubits are one of the most promising candidates for developing commercial quantum computers. Indeed, superconducting qubits can be fabricated using standard microfabrication techniques. Moreover they operate in the few GHz bandwidth such that conventional microwave electronic technologies can be used to control qubits and readout the quantum states.
A significant challenge in quantum computation is the sensitivity of the quantum information to noise. The integrity of the quantum information is limited by the coherence time of the qubits and errors in the quantum gate operations which are both affected by the environmental noise.
One manner to address this issue is to design and use topological qubits, which are intrinsically protected against noise. Topological qubits employ quasiparticles called anyons, and more specifically non-Abelian anyons. However, non-Abelian anyons have not yet been found in nature. This has hindered the development of topological quantum computers.
In accordance with a broad aspect, there is provided a topological superconducting qubit circuit. The circuit comprises a plurality of physical superconducting qubits and a plurality of coupling devices interleaved between pairs of the physical superconducting qubits. The coupling devices are tunable to operate the qubit circuit either in a topological regime or as a series of individual physical qubits. At least two superconducting loops, each one threadable by an external flux, are part of the qubit circuit.
In various embodiments, the circuit further comprises at least one component for generating a magnetic field for inducing the external flux in the superconducting loops.
In various embodiments, the component comprises two transmission lines, each one coupled to one of the superconducting loops through a mutual inductance.
In various embodiments, each one of the physical superconducting qubits is composed of at least one capacitor and at least one Josephson junction connected together.
In various embodiments, the Josephson junction is part of a SQUID.
In various embodiments, the capacitor and the Josephson junction are connected together at a first node, and the coupling devices are connected to the physical qubits at the first node.
In various embodiments, one of the superconducting loops comprises a second node having the same superconducting phase as the first node.
In various embodiments, the capacitor and the Josephson junction are connected together at a first node, and the coupling devices are connected to the physical qubits at a second node different from the first node.
In various embodiments, one of the superconducting loops comprises a third node having the same superconducting phase as the second node.
In various embodiments, one of the superconducting loops is a loop of superconducting material interrupted by a SQUID.
In various embodiments, another one of the superconducting loops is interrupted by a Josephson junction of the SQUID.
In accordance with another broad aspect, there is provided a method for topological protection of quantum information in a qubit circuit. The method comprises coupling a plurality of physical qubits with a plurality of interleaved coupling devices, each one of the coupling devices comprising at least one superconducting loop threadable by an external flux ϕext. Parameters for the external flux ϕext are selected such that
where J is a coupling device energy and h is a physical qubit energy. The external flux ϕext is applied to the superconducting loop to induce a phase shift in the coupling devices and to operate the qubit circuit in a topological regime.
In various embodiments, selecting parameters for the external flux ϕext comprises selecting ϕext to induce a phase shift with a value between π/2 and 3π/2 (mod 2π) in at least one Josephson junction of the qubit circuit.
In various embodiments, selecting parameters for the external flux ϕext comprises selecting ϕext to induce a phase shift of ϕ (mod 2ϕ) in at least one Josephson junction of the qubit circuit.
In various embodiments, the method further comprises applying an external flux ϕSQUID to the second superconducting loop of at least one of the plurality of coupling devices.
In various embodiments, applying the external flux ϕSQUID comprises applying the external flux ϕSQUID to the second superconducting loop of all of the plurality of coupling devices.
In various embodiments, the method further comprises selecting parameters for ϕSQUID=(2n+1)/2*ϕo, where n is an integer and ϕo is a flux quantum.
In various embodiments, the method further comprises modulating ϕSQUID for at least one of the plurality of coupling devices.
In various embodiments, modulating ϕSQUID comprises changing ϕSQUID adiabatically.
In various embodiments, modulating ϕSQUID comprises changing ϕSQUID from (2n+1)/2*ϕo to another value.
Features of the systems, devices, and methods described herein may be used in various combinations, in accordance with the embodiments described herein.
Reference is now made to the accompanying Figs. in which:
It will be noted that throughout the appended drawings, like features are identified by like reference numerals.
The present disclosure comprises circuits and methods for topological quantum computing using superconducting qubits. In various embodiments, a topological qubit comprises a plurality of physical superconducting qubits and a plurality of coupling devices which are interleaved between the physical qubits.
A superconducting circuit is described which can be used to artificially engineer non-Abelian anyon quasi-particle dynamics. Such a circuit may be used in developing a topological quantum processor.
For various operations of a quantum computer, such as anyon creation, braiding, and fusion, one may need to control the strength of the coupling between the physical qubits. Accordingly, a tunable qubit circuit for topological protection 100 is described herein and illustrated in
In some embodiments, a physical qubit 102 may be coupled to one or more other physical qubits 102 through corresponding coupling devices 104, thus creating a network of physical qubits which can support different configurations of topological qubits. Changing the configuration of the topological qubits is possible due to the tunability of the coupling devices interleaved between the physical qubits. All of the qubits 102 in the circuit 100 may be of a same configuration. Alternatively, qubits 102 of the circuit 100 may have different configurations. All of the coupling devices 104 of the circuit 100 may be of a same configuration. Alternatively, coupling devices 104 of the circuit 100 may have different configurations. Although three qubits 102 and two coupling devices 104 are illustrated, these numbers are for illustrative purposes only.
The qubits 102 may be composed of at least one capacitor and at least one Josephson junction connected together. In some embodiments, the qubits are transmon qubits, which are a specific type of superconducting qubit composed of at least one Josephson junction and at least one capacitor.
Example embodiments for the qubits 102 are shown in
The total energy of a circuit 100 having N qubits 102 may be found from its Hamiltonian. One can use the Jordan-Wgner transformation to show that circuit 100, designed with proper coupling devices 104, has a similar Hamiltonian to an Ising spin chain that behaves like a topological quantum system supporting Majorana edge states, which are one type of non-Abelian quasi-particles. In the Ising spin chain model, the Hamiltonian of a chain of N coupled qubits is written as:
where the σi are the Pauli operators on qubit i. The first term relates to the energy of the qubits 102. The second term represents the energy of the coupling between two qubits 102. The coupling is said to be of ferromagnetic type for J>0 (and antiferromagnetic type for J<0). A phase transition from a non-topological phase to a topological phase occurs when the coupling energy becomes larger than the qubit energy. In other words, the condition for achieving topological protection is
When this condition is met, we refer to the circuit 100 as having “deep strong coupling”. A circuit having deep strong coupling is said to operate in a topological regime.
Referring to
Each loop 314, 316 of circuit 300 is threadable by an external flux. The loop is said to be threadable by an external magnetic flux when a non-zero magnetic flux may be induced in the loop in a controlled fashion by an applied magnetic field passing through a surface defined by the loop. The magnetic field is generated by a component and/or device coupled to the loop. For example, the magnetic field can be generated by a current-carrying line such as a transmission line or a waveguide in proximity to the loop. Such current-carrying line is coupled to the loop through a mutual inductance and connected to a current source. An example is illustrated in
A magnetic field is applied to the circuit 300 in order to induce a phase shift in the coupling devices 302, so as to obtain a deep strong coupling regime. The magnetic field induces a non-zero external flux Φext threading loop 316.
A superconducting node phase ϕi and a charge number ni are assigned to each qubit 308, and the Hamiltonian of a chain of N qubits 308 is given by:
with
where Φo is the flux quantum, e the electron charge and ΦSQUID the flux applied to the SQUID of the coupling devices 302. The cosine term involving ϕext in the Hamiltonian can then be rewritten as:
cos(ϕi−ϕi+1−ϕext)=cos(ϕi−ϕi+1)cos ϕext+sin(ϕi−ϕi+1)sin ϕext. (3)
Expanding the cosine and sine terms involving ϕi to second order Taylor series, the Hamiltonian becomes
The first term corresponds to the sum of the Hamiltonians of N transmon qubits having Josephson energy equal to J=EJq+2EJc cos ϕext while the second term represents the coupling between nearest neighbours. The last term is an additional single-qubit term stemming from the external flux. For a finite chain, the two qubits at the ends of the chain have effective Josephson energies of J=EJq+EJc cos ϕext. The effective qubit impedance and plasma frequency are defined as:
Rewriting the Hamiltonian in terms of the Pauli operators gives:
In the Ising model, the condition for achieving topological protection is
In the present case, that becomes:
|EJc cos ϕext|>. (10)
If there is no external flux, i.e. ϕext=0, then the condition cannot be realised with EJc and EJq being positive. Deep strong coupling can only be satisfied if:
Topological order is thus attainable with such a design if an external phase having a value between π/2 and π/2 is applied to the coupler. Coupling is maximal at ϕext=π, in which case the condition on the design becomes EJq/3<EJc.
We can see that the separation between the ground state and the first excited state decreases from 6 GHz to less than 1 GHz when fSQUID approaches zero, where the coupling is maximal. Moreover, the derivative of the energy levels is zero at the maximal coupling point for fSQUID=0.
The calculated spectrum with four and five qubits 308 is shown in
Noting that the junction 708 and junction 714 form an asymmetric SQUID with zero flux, we can simply replace EJq by Ejq+EJs in equation (2) to find that the same Hamiltonian as the one presented above governs the embodiment of
Replacing the junctions 714 and 716 by superconducting inductors would lead to a similar result.
The circuit 800 has the same Hamiltonian as the circuit 300 when the capacitance is replaced by C/2 such that
in equation (2). The condition for reaching topological order is the same.
The Hamiltonian of the circuit 900 is the same as the Hamiltonian of the circuit 300 if we set
and replace EJq and EJc in equation (2) by EJs and EJq′, respectively. By inducing a phase shift of π in junction 906 and junction 910 using external fluxes, the condition for deep strong coupling becomes EJs/3<EJq′. Note that for tunability, the EJq′ junction 906 may be implemented as a SQUID.
Circuit nodes 1018, 1020 are associated with a node phase denoted by variables ϕi and ξi, respectively. The ϕi nodes 1018 are associated with a charge number ni. The total Hamiltonian for such a qubit chain is:
where
and ϕext=2πΦext/Φo. The coupler 1010 and the junctions 1006 and 1016 form a flux qubit with a=EJc/EJs. For a<0.5, the ground state of the flux qubit does not involve any persistent current such that the ϕi and ξi are approximated as being small. In that case, the Hamiltonian may be rewritten by expanding the cosines to second-order Taylor series:
Since the ξi nodes 1020 have no capacitance, a degree of freedom may be removed from the Hamiltonian by writing ξi in terms of ϕi. This is done by writing the Kirchoff current law at the coupling nodes:
EJc sin(ξi−1−ξi+ϕext)+EJq sin(ϕi−ξi)=EJs sin (ξi)+EJc sin(ξi−ξi+1+ϕext). (15)
Expanding the sines to first order gives:
This expression shows that in general, the coupling between the qubits 1002 is not limited to first nearest-neighbours. Indeed, the coupling term in the Hamiltonian is proportional to ξi+1ξi.
There exists a condition for which the coupling remains limited to next-nearest neighbours and the Hamiltonian is greatly simplified. Indeed, when EJc<<EJq, the following can be approximated:
Defining
the Hamiltonian may be rewritten as:
If the circuit 1000 is operated in the regime where EJq>>EJc& EJs, and a≈1, then we retrieve the Hamiltonian of equation (2). Indeed, when EJq>>EJs, the inductance of the junction EJq is very small compared to the other inductances of the circuit 1000 and can thus be considered as a short circuit. Using circuit 1000 with a≈1 instead of circuit 300 may allow the individual qubit frequency to be separately tuned in the non-topological regime, assuming junction 1004 is implemented as a SQUID, since this junction is decoupled from the flux bias of the superconducting loop 1024.
In order to find the condition to obtain deep strong coupling using the architecture of
=(a−1)2EJg+α2EJs−2a2EJc. (19)
The condition for deep strong coupling is:
<a2EJc. (20)
If a≈1, this condition implies EJc/EJs>⅓, consistent with the condition previously derived for the circuit 300 of
Replacing the junctions 1016 and 1006 by superconducting inductors (i.e. replacing the two-junction qubits 1002 by inductively shunted qubits) would lead to a similar result.
The energy spectrum of the coupled qubits 1002 as a function of the flux applied to the superconducting loop 1022, as per the embodiment of
All coupler designs presented hereinabove exhibited antiferromagnetic coupling (i.e. J<0).
We refer to the phase difference on junctions 1206, 1208, 1210 as δ1i, δ2i and ϕi respectively. Considering the quantization of the phase around the superconducting loop threaded by the external flux, we have:
δ1i+δ2i−ϕi−ϕext=0(mod 2π), (21)
where we have defined ϕext=2πΦext/Φ0. For the rest of this derivation, we will assume that ϕext=π.
The problem has a second constraint: that the current in junctions 1206, 1208 in series must be the same, which means that:
EJ1 sin δ1i=EJ2 sin δ2i. (22)
We now assume that EJ1>>EJ2. As a result, δ1i is limited to very small values around zero and δ2i approaches π due to the external flux. Combining equations (21) and (22) and assuming ϕext=π, we have:
EJ1 sin δ1i=−EJ2 sin(−δ1i+ϕi). (23)
Using a first order Taylor expansion we find:
We now write the Hamiltonian:
where in equation (27) we have shifted the argument of the cosine on the EJ2 term to make sure the argument is close to zero. We can now replace δ1i and δ2i by their equivalent in terms of ϕi and expand the cosine terms to second order to find:
We can now define an effective Josephson energy and qubit impedance r as:
and
The Hamiltonian can be rewritten using Pauli operators as:
with h=r/2 and J=r EJc/2.
From that, we find that the condition for deep strong coupling and topological order leads to:
This implies that
is larger than EJq for positive EJc.
Equations (23) to (32) were derived assuming EJ1>>EJ2. Having instead EJ1<<EJ2 leads to a swapping of EJ1 and EJ2 in the equations. Replacing either EJ1 or EJ2 by a superconducting inductor would also give a similar result.
As will be understood, the circuits 100, 300, 700, 800, 900, 1000, 1200 may be operated as topologically protected qubit circuits.
At step 1304, parameters are selected for the external flux ϕext such that
where J is the coupling devices and h is the energy of the physical qubits. In some embodiments, selecting parameters as per step 1304 comprises selecting ϕext to induce a phase shift with a value between π/2 and 3π/2 (mod 2π) in at least one Josephson junction of the qubit circuit. In some embodiments, selecting parameters as per step 1304 comprises selecting ϕext to induce a phase shift of π (mod 2π) in at least one Josephson junction of the qubit circuit.
At step 1306, the external flux ϕext is applied to the at least one superconducting loop to induce a phase shift in the coupler and operate the circuit in a topological regime. In some embodiments, ϕext is selected to induce a phase shift of π in the coupler.
In some embodiments, the qubit circuit comprises at least a first superconducting loop threadable by the external flux ϕext, and at least a second superconducting loop threadable by an external flux ϕSQUID. The method 1300 may thus, in some embodiments, also comprise a step 1308 of selecting parameters for the external flux ϕSQUID, and/or a step 1310 of applying the external flux ϕSQUID to the second superconducting loop. The parameters for ϕamp may be selected such that ϕSQUID=(2n+1)/2*ϕo, where n is an integer and ϕo is the flux quantum.
The qubits may be decoupled and operated as individual physical qubits with the appropriate choice of external flux ϕSQUID. In some embodiments, ϕSQUID=+/−0.5 ϕo provides such capability. A flux ϕSQUID=(2n+1)/2*ϕo can also be applied only to selected couplers. For example, if a flux ϕSQUID=(2n+1)/2*ϕo is applied to a coupler in the middle of a chain of N coupled qubits (N even), then the topological qubit can be broken into two topological qubits each made of N/2 physical qubits.
The flux in the SQUID of one coupler may be changed from a value of (2n+1)/2*ϕo to a different value. For example, the flux in a coupler between two chains of N/2 coupled physical qubits can be modified to a value different from (2n+1)/2*ϕo, such as a value of nϕo, in order to convert the two topological qubits made of N/2 physical qubits into a single one made of N qubits.
In general, the strength of the coupling can be modulated by modulating ϕSQUID. In some embodiments, ϕSQUID is changed adiabatically to ensure that the symmetry of the wave function is preserved during the procedure.
Although illustrated as sequential, the steps 1304-1310 of the method 1300 may be performed in any desired order, and in some cases concurrently. For example, parameters for both fluxes may be selected concurrently, as per steps 1304 and 1308, but applied sequentially as a function of a desired implementation. Steps 1306 and 1310 will necessarily be performed sequentially, but not necessarily in the order illustrated.
Various aspects of the circuits and methods described herein may be used alone, in combination, or in a variety of arrangements not specifically discussed in the embodiments described in the foregoing and is therefore not limited in its application to the details and arrangement of components set forth in the foregoing description or illustrated in the drawings. For example, aspects described in one embodiment may be combined in any manner with aspects described in other embodiments. In addition, all of the embodiments described above with regards to circuit 100 may be used conjointly with the method 1300.
Although particular embodiments have been shown and described, it will be apparent to those skilled in the art that changes and modifications may be made without departing from this invention in its broader aspects. The scope of the following claims should not be limited by the embodiments set forth in the examples, but should be given the broadest reasonable interpretation consistent with the description as a whole.
The present application claims the benefit of U.S. Provisional Patent Application No. 62/740,450 filed on Oct. 3, 2018, and on U.S. Provisional Patent Application No. 62/812,393 filed on Mar. 1, 2019, the contents of which are hereby incorporated by reference in their entirety.
Number | Name | Date | Kind |
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7109593 | Freedman et al. | Sep 2006 | B2 |
7518138 | Freedman et al. | Apr 2009 | B2 |
8581227 | Freedman et al. | Nov 2013 | B2 |
9489634 | Bonderson | Nov 2016 | B2 |
20170212860 | Naaman | Jul 2017 | A1 |
20180032894 | Epstein | Feb 2018 | A1 |
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62812393 | Mar 2019 | US | |
62740450 | Oct 2018 | US |