The present disclosure is directed to quantum computation. More particularly, the present disclosure relates to systems and methods for storing and processing quantum information.
In the field of quantum computation, the performance of quantum bits (“qubits”) has advanced rapidly in recent years, with a variety of qubit implementations proving to be promising candidates for scalable computing architectures. In contrast with classical computational methods, where data is manipulated and stored in the form of well-defined binary states, or bits, quantum computation takes advantage of the quantum mechanical, probabilistic nature of quantum information. Quantum systems characterized by quantized energy levels can represent a superposition of multiple quantum states.
In general, a qubit can encode quantum information using a simple two-level system whose state can be represented as a vector in a two-dimensional complex Hilbert space. In some approaches, such two-level systems may be constructed using a semiconductor-based quantum dot system, as well as other physical systems. Such implementations are advantageous due to their scalability and ease of integration with present semiconductor-based electronics technologies. In general, quantum dots are artificially structured systems that can be filled with electrons or holes which may become trapped in three dimensions using controllable potential barriers generated by various device configurations and/or electrical gating. The confined electrons or holes can then form localized bound states with discrete energy levels, similar to the quantum states of atoms and molecules. The wavefunctions describing these states may then be utilized to establish the two-level system. Specifically, if the spatial part of an electron wavefunction is used, a charge qubit is achieved, with the spatial wavefunction defining the electron charge distribution. On the other hand, if the spin portion of the wavefunction is used, a spin qubit is produced.
A charge qubit can be implemented using a double-dot configuration having a single excess electron at the highest occupation level localized on one of the dots. However, charge qubits have high decoherence, resulting in the loss of information stored in the qubit. Specifically, the motion of charged defects in the device gives rise to time-varying electric fields causing fluctuations in the detuning, which is the energy difference between the two charge states of the qubit. Such fluctuations reduce the coherence time of the charge qubit, limiting computational applications. In some aspects, the charge qubit coherence may be improved by operating at a “sweet spot,” defined as a special value of the detuning where the derivative of the energy difference between the qubit states as a function of detuning is zero. However, so far it has not been possible to achieve high fidelity operations in a charge qubit by exploiting a single sweet spot. In particular, universal qubit control requires the ability to perform rotations about a second axis, and for dc pulsed gates, this second rotation axis needs to be implemented away from the sweet spot, yielding low gate fidelities. In principle, ac gating can be used to perform a universal set of qubit rotations without leaving the sweet spot. However, in practice it is difficult to perform operations with fidelities high enough for quantum information processing applications since noise moves the qubit away from the sweet spot.
Spin qubits can be sufficiently decoupled from their environments, thus providing relatively long quantum information lifetimes for performing computation. However, manipulation of electron spins in quantum dots requires precise control over the magnetic properties of the device and the ability to generate fast-pulse localized magnetic fields. Also, spin qubits are more difficult to couple to external circuitry, and often necessitate use of various spin-charge conversion techniques. By contrast, charge qubits can easily be coupled to external circuitry, facilitating control and measurement. In addition, charge qubits can be easily integrated with present semiconductor technologies, and lend themselves well to scalability due to ease of spatial selectivity addressing individual qubits in a multi-qubit quantum computer architecture. In addition, charge qubits can be manipulated quickly up to gigahertz frequencies. However, charge qubits are susceptible to environmental noise that is intrinsic to the materials and geometries used, and suffer from relatively poor gate fidelities for the same reasons. As such, spin qubits are often considered to be leading candidates in the realization of semiconductor quantum dot-based quantum computers.
In light of the above, there is a need for systems and methods for quantum computing based on charge qubit implementations that are amenable to realistic computing architectures.
The present disclosure overcomes the drawbacks of previous technologies by providing a quantum system and method for quantum computation. Specifically, in recognizing that electric field fluctuations are a strong source of decoherence in conventional charge qubits, which lead to reduced quantum information lifetimes, a novel charge qubit is therefore provided. As will be described, charge qubits implemented in quantum dot assemblies prepared with symmetric charge distributions substantially reduce dominant dipolar contributions to the dephasing caused by charge noise, thereby appreciably enhancing qubit coherence times in comparison to conventional charge qubits.
In accordance with one aspect of the disclosure, a quantum computing system for performing quantum computation is provided. The system includes at least one charge qubit comprising a quantum dot assembly prepared with a symmetric charge distribution, wherein the symmetric charge distribution is configured to reduce a coupling between the charge qubit and a charge noise source. The system also includes a controller for controlling the at least one charge qubit to perform a quantum computation. The system further includes an output for providing a report generated using information obtained from the quantum computation performed.
In accordance with one aspect of the disclosure, a method for performing quantum computation is provided. The method includes preparing at least one charge qubit comprising a quantum dot assembly with a symmetric charge distribution that is configured to reduce a coupling between the charge qubit and a charge noise source, and controlling the at least one charge qubit to perform a quantum computation. The method also includes performing a readout of the at least one charge qubit following the quantum computation. The method further includes generating a report using information obtained from the quantum computation performed.
The foregoing and other aspects and advantages of the invention will appear from the following description. In the description, reference is made to the accompanying drawings that form a part hereof, and in which there is shown by way of illustration a preferred embodiment of the invention. Such embodiment does not necessarily represent the full scope of the invention, however, and reference is made therefore to the claims and herein for interpreting the scope of the invention.
It is a well-known problem that conventional semiconductor charge qubits suffer from the loss of quantum information due to coupling to external noise sources. In particular, charge noise due to trapped defects and metallic gates can lead to strong decoherence. Motion of charges that are much farther from the qubit than the qubit size generate electric fields that vary slowly in space. A charge qubit sensitive to these ubiquitous fields would then experience undesirable decoherence. However, the realization of any viable quantum computing architecture, according to the DiVincenzo criteria, would not only necessitate low decoherence for carrying out sufficient qubit operations and measurements, but also the capability for communication. That is, a charge qubit would require strong response to fields that vary quickly in space at short length scales in order to achieve fast operations and strong coupling to other qubits or external circuitry. Hence, it is a discovery of the present disclosure that highly symmetric quantum dot qubit structures can achieve both sensitivity to strongly varying electric fields, enabling fast gate operations and quantum information exchange, as well as an insensitivity to remote charge noise, leading to long coherence times.
Therefore, the present disclosure provides a system and method for quantum computation that is based on symmetric quantum dot-based qubit configurations, and more particularly on charge qubits prepared with symmetric charge distributions. As will be appreciated from descriptions below, the present approach is advantageous for reducing dominant dipolar contributions to the charge noise that are responsible for the loss of quantum information in charge qubits. In this manner, significantly increased coherence times can be achieved in comparison to conventional charge qubits.
In one embodiment, a charge quadrupole qubit based on three quantum dots arranged collinearly and prepared with one electron in a symmetrical charge distribution is disclosed. In particular, such a qubit may be defined using basis states having different charge distributions with the same center of mass. That is, a localized state can be included in the center dot, and a delocalized state with a symmetric superposition of charge can be included in the left and right dots. Since these states do not form a dipole, uniform electric field fluctuations due to charge noise would not change the energy difference between the states, and hence would not lead to appreciable decoherence. Although a third “leakage” state, corresponding to an anti-symmetric superposition of charge in the left and right dots, could lead to an unwanted dipole in a triple dot assembly, enforcing a symmetric geometry would decouple such a state, resulting in suppressing the dipole.
Although some qubit realizations have been attempted using three quantum dots, these are fundamentally different because they rely on the spin degree of freedom, rather than charge, and utilize spin-based configurations and operational techniques. Also, any implementation in a realistic quantum computer would necessitate spin-charge conversion capabilities in order to communicate with external circuitry, such as other qubits, a bus, a stripline, or other measurement circuitry. In addition, although spin-based qubits could be less sensitive to charge noise in some designs, gating protocols necessary for qubit operation would nonetheless lead to non-symmetric charge configurations, and hence enhanced decoherence during such operations. By contrast, charge qubit embodiments described herein are explicitly designed to be highly symmetric even during gating operations.
As may be appreciated, concepts detailed in the present disclosure need not be limited to triple dot charge qubits, and may be readily extended to other symmetrical qubit configurations. For instance, a four dot charge qubit may be possible, in which three quantum dots are arranged at 120 degree angles relative to a central dot, or a five dot charge qubit, in which four quantum dots are arranged symmetrically relative to the central dot. Furthermore, although described in the context of charge qubits involving a single electron, the present approach may be readily extended to include logical spin qubits that include more than one electron, as well.
Turning now to
In some embodiments, the qubit circuitry 102 includes one or more charge qubits implemented using a quantum dot assembly. In accordance with aspects of the present disclosure, the quantum dot assembly may be configured symmetrically to substantially reduce or eliminate a coupling between the charge qubit(s) and a charge noise source, such as a noise originating from trapped defects or metallic leads. In one example, the quantum dot assembly may include three dots arranged collinearly. In another example, the quantum dot assembly may include four dots, in which three dots are arranged symmetrically at 120 degree angles relative to a central dot. In yet another example, the quantum dot assembly may include five dots, in which four dots are arranged symmetrically at 90 degree angles relative to a central dot. Other symmetrical charge qubit configurations are also possible. For instance, a quadrupole geometry may be achieved using a combination of a quantum dot and donor confinement potentials, as will be described. Furthermore, in some aspects, the qubit circuitry 102 may additionally or alternatively include logical spin qubits, as well as any number of linear and non-linear circuit components, including inductors, capacitors, resistors, diodes, and so on.
As known in the art, a quantum dot is a general term referring to a physical system where one or more electrons (or holes) may be confined. By tuning the confinement strength and electrochemical potential using lateral or vertical gates, as well as the coupling to other dots or reservoirs, the size and occupation of the each dot can be controlled to obtain a wide variety of quantum systems for use in quantum computation. For instance, quantum dots have been obtained using trapped molecules, layered or patterned metallic, semiconducting and superconducting materials, ferromagnetic nanoparticles, self-assembled crystals or colloids, nanowires, carbon nanotubes, graphene, and so on. In this regard, the quantum dot assembly may be constructed using any such lateral and/or vertical circuit configurations, as well as using various materials and geometries. For instance, the quantum dot assembly can include a number of semiconductor quantum dots produced using nanofabricated GaAs/AlGaAs or Si/SiGe heterostructures, or metal-oxide-semiconductor interfaces.
In some aspects, the qubit circuitry 102 may include various circuit elements for use in the preparation, manipulation, and readout of the charge qubit(s). For instance, the qubit circuitry 102 may include one or more metallic gating leads configured to control charge confinement and states of the quantum dots in the quantum dot assembly. By way of example,
Referring again to
By way of example,
Referring again to
In general, the control hardware 104, as directed by the controller 106, may be used to prepare the qubit(s) formed by the qubit circuitry 102, as described. For instance, the control hardware 104 may be configured to populate the quantum dot assembly with one or more electrons (or holes). In addition, the control hardware 104 may be configured to form qubit states for the charge qubit using different charge distributions having the same center of mass. In some aspects, the control hardware 104 may prepare and manipulate the qubit(s) with symmetric charge distribution, such that a coupling between the qubit(s) and a charge noise source is substantially reduced or eliminated. For example, the control hardware 104 may perform a number of quantum logic operations, including the application of ac gates, dc gates, pulsed gates, and combinations thereof, while preserving charge symmetry. The control hardware 104 can then readout the qubits(s), for instance, using one or more charge sensors, and provide, via the output 108, a report of any form for the quantum computation results obtained.
Turning now to
At process block 404, a number of steps may be carried out on the qubit(s) to manipulate the qubits and perform various quantum computations. For example, a number of quantum logic operations may be carried out, including the application of ac gates, dc gates, pulsed gates, and combinations thereof. Then, readout of the qubits(s) may be carried out, for instance using one or more charge sensors, as indicated by process block 406. A report may then be generated and provided to an output at process block 408, the report being in any form and indicating the results of quantum computations performed. For example, the report may provide information regarding a state of the charge qubit following the application of one or more quantum operations.
In a conventional double-dot charge qubit, charge may be localized in two different configurations, namely left-localized and right localized, defined as |10c and |01c, respectively, where the subscript c indicates a charge basis state. As described above, such a conventional qubit, herein referred to as a charge dipole (“CD”) qubit, couples to spatially uniform electric fields. By contrast, a charge quadrupole (“CQ”) qubit implemented in a triple quantum dot, and prepared in accordance with aspects of the present disclosure, provides new possibilities for qubits that are not dipolar, as detailed below.
In a qubit, it may be useful to express electrical noise in terms of fluctuations of the detuning parameters in the Hamiltonian. Long-wavelength noise that that couples to a charge dipole can be associated with the dipolar detuning parameter ∈d, while noisy field gradients parallel to the qubit axis, can be associated with the quadrupolar detuning parameter ϵq. Below, it is shown that the energy difference between CQ qubit states is independent of ϵd fluctuations, yielding an ϵd sweet spot. It is also shown that in typical semiconductor quantum dots, fluctuations of ϵd are much stronger than those of ϵq, when the noise originates from remote charge fluctuators. Universal sets of pulsed and resonant gate operations for CQ qubits are also described, where in some aspects, ϵq is used as a control parameter, while keeping ϵd fixed at its sweet spot. Moreover, it is shown the effects of fluctuations in ϵd (which mainly give rise to leakage as opposed to dephasing) can be made very small by appropriate choice of qubit parameters. As a result, a CQ qubit as described below, would be mainly sensitive to fluctuations of the quadrupolar detuning ϵq, herein denoted as δϵq, yielding significant improvements in gate fidelities.
As described, in some embodiments, a CQ qubit may be implemented using a symmetric triple dot configuration. As shown in
The parameters tA and tB are the |100c-|010c and 010c-|001c tunneling amplitudes, and U1, U2 and U3 are site potentials. It is convenient to define the polar and quadrupolar detuning parameters as
Note that the dipolar detuning ϵd corresponds to what is commonly termed ϵ in a conventional, double dot charge qubit. Up to a diagonal constant term, the Hamiltonian is then given by
The qubit states |0 and |1 would then be the lowest and highest energy eigenstates of the 3-level Hamiltonian, Eqn. (3). As described, the other eigenstate is a leakage state, |X, which would not be occupied during successful operation. Explicit solutions for the qubit energy splitting E01=E1−E0 are obtained below, whose fluctuations determine the qubit dephasing.
As mentioned, a CQ qubit, in accordance with the present disclosure, is by design less susceptible to charge noise than a CD qubit because in solid state devices the dipolar component of the charge noise, ϵd, is typically much larger than the quadrupolar component, ϵq. Herein, the relative strengths of these two components are estimated based on experimental measurements of charge noise in semiconducting qubit devices. The basis for this argument is that both types of electric field noise arise from the same remote charge fluctuators.
When considering charge noise from remote charge traps in the semiconductor device, a simple model may include a charge trap with two possible states: occupied or empty. Compared to a dipole fluctuator, in which the charge toggles between two configurations separated by less than a nanometer, the monopole fluctuator can be considered as a worst-case scenario in terms of its effect on the quadrupolar detuning. This is because the monopole field decays as 1/R while the dipole field decays as 1/R2, where R is the dot-fluctuator separation. This monopole model can be used to estimate the characteristic separation R between the fluctuator and the quantum dot, based on charge noise measurements in a double-dot charge qubit. In particular, experimental measurements of the dephasing of charge qubits yield estimates for the standard deviation of the dipole detuning parameter, ac, ranging approximately between 3 and 8 μeV for double dots separated by roughly 200 nm, leading to estimates for the dot-fluctuator separation of R approximately between 1.1 and 2.5 μm.
With this information, the ratio δϵq/δϵd can be estimated. In a worst-case scenario, corresponding to the strongest quadrupolar fluctuations, the monopole fluctuator would be lined up along the same axis as the triple dot. Adopting a point-charge approximation for the fluctuation potential, V(r)=e2/4πr, and assuming L/R<<1, Eqn. (2) then yields
As an example, typical devices have dimensions L approximately 200 nm, and R approximately between 1 and 3 μm. This leads to an estimate for the ratio δϵq/δϵd approximately between 0.07 and 0.2. In other words, in this case, quadrupolar detuning fluctuations would be approximately 10 times weaker than dipolar detuning fluctuations. In fact, it may be appreciated from Eqn. (4) that as device dimensions are reduced, δϵq/δϵd can be further suppressed. For example, quantum devices with dot separations L of approximately 50 nm, would yield further reduction in δϵq/δϵd by a factor of 4.
The four independent (and, in general time-varying) parameters in the Hamiltonian, Eqn. (3), are tuned to yield desirable properties during qubit operations. To specify the procedure, a discussion of the qubit states and how they depend on the Hamiltonian parameters is now given. Specifically, the eigenvalues E of Eqn. (3) satisfy the equation:
(E2−ϵd2)(E−ϵq)−tA2(E+ϵd)−tB2(E−ϵd)=0 (5)
The energy eigenstates |0 and |1 are the lowest and highest energy eigenstates of the Hamiltonian, while the other eigenstate |X is a leakage state.
Goals of the tuning procedure would be to suppress the leakage into the state |X during gate operations, suppress the dephasing caused by δϵd fluctuations, and suppress the dephasing caused by δϵq fluctuations. In particular, it may be appreciated that insignificant dephasing due quadrupolar fluctuations may be readily achievable because δϵq fluctuations are already weak, according to Eqn. (4).
It is advantageous to suppress the leakage to state |X, which may occur when a control parameter (e.g., ϵd or ϵq) is varied, generating a nonzero projection of the electron wavefunction onto the leakage state. Leakage occurs because in general the composition of the leakage state depends on the control parameter. However, leakage can be suppressed by minimizing this dependence, through a judicious tuning of the CQ qubit. In order to appreciate this, let the leakage state be expressed as |X=(a,b,c) in the charge basis and impose the constraint:
Combining the above conditions with the eigenstate equation H|x=Ex|X yields the auxiliary equations (∂H/∂ϵd)|X=(∂EX/∂ϵd)|X and (∂H/∂ϵq)|X=(∂EX/∂ϵq)|X, from which the requirements for leakage suppression can be derived, namely ϵd=b=atA+ctB=EX=0.
As described, it is desirable to suppress the dephasing that arises from δϵd fluctuations. Such dephasing occurs since δϵd fluctuations produce fluctuations in the energy eigenvalues in Eqn. (5). As such, expressing ϵd in terms of its average (
tA=tB and ϵd=0 (7)
At this operating point the leakage state is given by |X=(1,0,−1)/√{square root over (2)}. In principle, it may be possible to establish a ϵd sweet spot, even for the case of an asymmetric geometry with tA≠tB. This is consistent with the notion that it would be possible to find two orthogonal states with the same center of mass in a triple-dot geometry, regardless of the symmetry. However, only the symmetric geometry described above can suppress leakage during gate operations.
The combined requirements of
Hence, after setting tA=tB=t and ϵd=0, Eqn. (3) can be solved analytically, yielding
The resulting energy level diagram is shown as a function of the quadrupolar detuning parameter ϵq in
where the first term on the right-hand side expresses the charge qubit Hamiltonian in standard form, and the constant term ϵq/2 may be considered irrelevant. For any control parameter α, a sweet spot may be defined as a point where the energy difference between the qubit states E01 satisfies ∂E01/∂α=0. CD and CQ qubits both have sweet spots with respect to the ϵd tuning parameter, which arise from the same physical mechanism, namely when the adiabatic qubit eigenstates have the same center of mass, the dipole moment vanishes and the qubit decouples from uniform external fields. For a conventional CD qubit, the fluctuations of ϵd away from its sweet spot merely cause dephasing. However for a CQ qubit, the δϵd fluctuations cause an asymmetric charge distribution, consistent with a partial occupation of the leakage state |X. This leakage will be explored in further detail below.
In some aspects, the ideal case with no leakage may be considered, focusing on the localized/delocalized basis states,
|L=(0,1,0), |D=1/√{square root over (2)}(1,0,1), (12)
as defined in the charge basis. Without loss of generality, we may also refer to the states |L and |D in terms of their occupation probabilities (0,1,0) and (½,0,½). In the subspace spanned by {|L,|D}, the qubit eigenstates are now given by
At the CQ sweet spot specified by Eqn. (7), both ∂ϵ0/∂ϵd=0 and ∂E1/∂ϵd=0. At this working point, Eqns. (8) and (10) yield
E01=√{square root over (ϵq2+8t2)} (14)
Hence, it may be seen that ϵd=ϵq=0 corresponds to a double sweet spot, ∂E01/∂ϵd=∂E01/∂ϵq=0, where the qubit is also protected from small fluctuations of ϵq. It may be recognized that spending as much time as possible at this double sweet spot would be advantageous. However, applying dc gates to obtain a second rotation axis would pulse away from this sweet spot. Nevertheless, this can be readily accomplished by varying ϵq, while still remaining at the ϵd sweet spot. By contrast, ac gating can be accomplished while remaining near the double sweet spot at all times, by adding a resonant drive to ϵq at its average value
Thus far, it has been assumed that electric field fluctuations, δF, couple to ϵd but not to ϵq. This relies on particular assumptions regarding the symmetries of a triple dot. However, in realistic devices, such assumptions might not hold. Specifically, if the triple-dot symmetry is imperfect, uniform field fluctuations can induce effective quadrupolar fluctuations δϵq, thus interfering with the CQ noise protection. This dot-to-dot variability is now explored.
As described, quantum dots are generally confined in all three dimensions, and in particular with vertical confinement being typically very strong. As such, a sub-band approximation can be made, in which the vertical dimension is ignored. The dot can then be treated as a two-dimensional (“2D”) system. In a 1D parabolic approximation for the lateral confinement the potential may be expressed as:
where i=1, 2, 3 is the dot index, hωi is the splitting between the simple harmonic energy levels, xi is the center of the dot, and U0,i is the local potential. In some aspects, a more accurate description of Vi(x) could also include an-harmonic terms, which would yield higher-order corrections to the results obtained below.
The parameters ωi, xi and U0,i can vary from dot to dot. In particular, U0,i can be controlled simply by applying appropriate voltages to the top gates, such that values are adjusted to satisfy the requirement that
In particular, a uniform field fluctuation introduces a new term into Eqn. (15) of the form −exδF. Eqn. (15) can then be rewritten as
where xi′=xi+(e/mωi2)δF represents the shifted center of the dot.
The matrix elements in Eqn. (3) may be computed from the total Hamiltonian, which includes Eqn. (16) and the kinetic energy operator. It may be noted that, although x′ depends on δF, none of the matrix elements in Eqn. (3) directly depends on xi′. Dot-to-dot variations in the first term on the right-hand side of Eqn. (16) can therefore be compensated via the potential U0,i. The leading order O[δF] fluctuation term in Eqn. (16) that modifies a matrix element is therefore −exiδF, which does not depend on ωi. Hence, to order O[δF], variations in ωi would not affect the results.
The leading-order fluctuations can now be calculated in terms of the quadrupolar detuning caused by δF. From Eqn. (2),
which is linear in δF, a term which needs to be suppressed. This may be accomplished by adjusting the dot separations to make them equal, namely
x2−x1=x3−x2=Lx. (18)
Repeating this analysis for the confinement along the y axis, additional requirements may be obtained, namely,
y2−y1=y3−y2=Ly. (19)
In other words, the three dots would preferably be equally spaced along a line. However, these new symmetry conditions need not be necessarily enforced geometrically, and could be readily achieved by simply including two top gates to fine-tune the x and y positions of one of the dots. Such, fine-tuning can be accomplished using a number of automated control methods. Moreover, small errors in the dot position, δx, can be tolerated since they only increase the detuning by a linear factor, namely δϵq=(δx/L)δϵd, where the field fluctuations are expressed in terms of the dipolar detuning.
To demonstrate advantages of coherence properties for the herein provided CQ qubits, compared to conventional CD qubits, where the latter are not fully protected from weak fluctuations of ϵd, the standard two-dot qubit is analyzed as follows. Specifically, assuming a standard two-level Hamiltonian
express in the {|10c,|01c} charge basis of a double dot. Note that the CD qubit couples only to the dipolar tuning. The qubit energy is then given by E01,CD=√{square root over (ϵd2+4t2)}. By introducing fluctuations of the form ϵd→
The first term of E01,CD indicates that ϵd can be used to control the qubit. The second term indicates that the qubit is only protected from O[δϵd] detuning fluctuations at the sweet spot,
By contrast, for the CQ qubit, the energy eigenstates can be solved by performing a fluctuation expansion, replacing ϵd→δϵd, ϵq→
As discussed, terms O[δϵq2] are much smaller than terms of O[δϵd2]. Consistent with the discussion above, it may be seen that a charge qubit, in accordance with the present disclosure, is protected from both dipolar and quadrupolar detuning fluctuations of linear order at the double sweet spot,
Next, the effects of fluctuations on CQ and CD gate operations are compared. The qubits are first initialized, for instance, by tuning the devices far away from their charge degeneracy points and waiting. For the CQ qubit, it may be convenient to initialize into the ground state |L in the regime where ϵd=0, ϵq<<0. Readout can be performed at the same setting. In particular, for CQ qubits, this involves measuring the charge occupation of the center dot. After initialization, the qubits can be adiabatically tuned to their sweet spots.
In general, a qubit gate implements a prescribed transformation of the qubit on the Bloch sphere. Specifically, the Bloch sphere is a geometrical representation of the state space for a two-level quantum system, where the north and south poles on the sphere represent the |0 and |1 state, respectively. Two rotation axes are commonly required for universal gate operations. For a CD qubit, it is advantageous that one of these gates is performed at the sweet spot,
For a CQ qubit, in accordance with the present disclosure, the gates may be controlled by pulsing
The ϵ01 fluctuation terms expressed Eqns. (21) and (22) cause dephasing, leading to the loss of quantum information in a qubit. To illustrate the advantage of the present approach as compared to previous techniques, a comparison is now made for their relative magnitudes. Specifically, z rotations performed at the sweet spot (or the double sweet spot) have very similar dephasing characteristics for the two types of qubits. In both cases, they are O[δϵd2]. On the other hand, x rotations are performed away from the (double) sweet spot, yielding very different dephasing characteristics. That is, for CD qubits dephasing characteristics are dominated by δϵd noise, while for CQ qubits, they are dominated by δϵq noise. Evaluating the leading fluctuation terms at tuning values corresponding to 45° rotation axes, the size of the fluctuations is found to be reduced by the factor δϵq/δϵd<<1 for CQ qubits. For pulsed gates, the CQ qubit is protected from its pre-dominant noise source (δϵd fluctuations) for both x and z rotations, while the CD qubit is only protected during z rotations.
As may be appreciated, leakage is not a problem for ordinary CD qubits, because there is no leakage state. CQ qubits can be carefully tuned to a symmetry point where the leakage is suppressed. However, leakage could still be a concern in the presence of δϵd fluctuations. When ϵd≠0 the block diagonalization of Eqn. (11) is imperfect, and leakage would occur during pulsed gating.
To estimate the magnitude of this effect, a pulse sequence is considered in which the qubit is initialized into the ground state |0=|L when ϵq→∞, then suddenly pulsed to the sweet spot at ϵq=0. At this location, the full 3D Hamiltonian of Eqn. (3) can be exactly diagonalized, yielding a nonzero probability of occupying the leakage state PX=|X|L|2=δϵd2/(δϵd2+2t2)˜δϵd2/2t2. It is noted here that the assumed voltage pulse, beginning at ϵq→∞, is unphysical, namely infinite, and hence a more realistic initial state would slightly suppress this leakage.
The accuracy of this leakage estimate was verified by performing simulations of finite-voltage pulse sequences, including quasistatic noise in δϵd. A half-cosine ramp function, ϵq(t), with variable ramp rates was specifically considered, obtaining very good agreement with the PX estimate for fast ramps. It is envisioned that the leakage can be further suppressed by ramping ϵq slowly. However this could also yield low gate visibilities in the adiabatic limit. One can also compare the magnitude of leakage errors (PX) to rotation errors, defined as δE01/E01. From Eqn. (22), it is found that δE01/E01≅δϵd2/4t2, which has the same scaling form as PX.
For ac gates, it is common to work in a frame rotating at the qubit frequency, with the two driven gate operations being x and y rotations, which are distinguished by the relative phase of the ac driving with respect to the intrinsic qubit rotation. It is convenient to choose a working point (
Decoherence during driven evolution is most easily analyzed in the rotating frame, where the predominant decay mechanism is longitudinal, with the corresponding decay time T1ρ. In this case, the charge noise environment can be well approximated as quasi-Markovian, so that, on resonance, the following is obtained
1/T1ρ=2S2(ϵac/)+Sx([ϵac+√{square root over (8)}t]/)+Sx([ϵac−√{square root over (8)}t]/) (23)
where ϵ(t)=ϵac sin(E01t/) is the resonant driving term at the sweet spot, and Sz and Sx are the longitudinal and transverse noise spectral densities in the lab frame, respectively. These spectral densities describe noise in the detuning parameters used to drive the rotations, corresponding to ϵd for CD qubits or ϵq for CQ qubits. In the weak driving regime, ϵac<<√{square root over (8)}t, the term 2Sz(ϵac/) would normally dominate Eqn. (23) because Sx,z(ω)∝1/ω for charge noise. However, at the sweet spot, ϵ noise is precisely orthogonal to the quantization axis, so Sz(ω)=0. This is highly advantageous for resonant driving because the other terms in Eqn. (23) are much smaller, since their arguments are much larger.
To compare T1ρ for CD and CQ qubits the following important observation can be made. Specifically, in the noise model above described above, δϵd and δϵq arise from the same fluctuators, such that the ratio of their respective noise strengths would be independent of the frequency. The decoherence rate for resonant x (or y) rotations in a CQ qubit, which are driven via the detuning parameter δϵq, would therefore be suppressed by the same small factor δϵq/δϵd that was obtained for pulsed x rotations. In both cases (pulsed and resonant gates), it is expected that the CQ qubit would be protected from the predominant δϵd noise mechanism during both x (y) and z rotations, while the CD qubit would only protected during z rotations.
Up to this point, description of CQ qubits has been directed to qubit implementations formed using quantum dots, as shown in the dot-dot-dot configuration 600 of
In addition to charge qubits, many types of logical spin qubits can also be protected from dipolar detuning fluctuations by employing symmetric triple-dot geometries. For example, the standard two-electron singlet-triplet qubit formed in a double quantum dot would not be protected from dipolar detuning fluctuations. However, a singlet-triplet qubit formed in a triple dot could be protected by tuning the device to one of the charge transitions (1,0,1)-(½,1,½) or (0,2,0)-(½,1,½). Here, the delocalized states with half-filled superpositions would be analogous to those shown in
In a similar fashion, quantum dot hybrid and exchange-only qubits can be also implemented as three-electron quadrupolar qubits by enforcing symmetric geometries. In this case, charge transitions occur between the configurations (1,1,1)-(3/2,0,3/2), (1,1,1)-(½,2,½) for the quantum dot hybrid qubit and (0,3,0)-(½,2,½) for the exchange-only qubit. When the qubit basis involves both singlet-like (“S”) and triplet-like (“T”) spin states, the singlet-triplet energy splitting in dots 1 and 3 would need to be equalized.
It is noted that the optimal working point for single-qubit operations in a conventional exchange-only qubit occurs at a double sweet spot in the (1,1,1) charging configuration. However, other modes of operation, such as two-qubit gates, readout, or coupling to a microwave stripline, may necessitate changing the charge occupations. For the conventional exchange-only qubit, the modified charge state can be taken to be (2,0,1) or (1,0,2). However, the quadrupole version employs one of the symmetric, half-filled superposition states, namely (3/2,0,3/2) or (½,2,½), yielding significant improvements in the coherence properties when the qubit is coupled to other devices. It may be emphasized that the quadrupolar working point occurs at one of the charging transitions, and is therefore different than the double sweet spot of the conventional exchange-only qubit.
Two types of interactions have been proposed to mediate two-qubit gates between logical spin qubits, namely classical electrostatic (capacitive) interactions and quantum exchange interactions. Capacitive interactions may also be used to couple charge qubits. The mechanisms and methods for performing such gates may be readily adopted here, provided that qubit symmetry is preserved during the coupling. This suggests that, in three-dot implementations, the middle dots could be used for coupling to the qubits. For capacitive gates, this can be most easily accomplished by employing a floating top-gate antenna above, or near, the middle dot, as illustrated in
An important application for quadrupole qubits disclosed herein can include a cavity quantum electrodynamics (“cQED”) system consisting of a triple dot capacitively coupled to a superconducting stripline resonator. Previously, couplings of up to g=30-50 MHz were reported for systems employing CD qubits. However, the desired strong coupling limit has so far remained elusive, because CD coherence times are typically of order 1 ns. The relevant figure of merit for strong coupling in this system is g2/ΓqΓs, where Γq˜1/T1ρ and Γs are the decoherence rates of the resonantly driven qubit and the superconducting stripline, respectively.
For cQED, it is expected that quadrupole qubits, in accordance with the present disclosure, would yield a much better figure of merit compared to CD qubits. Specifically, for the CD qubit, the coupling is implemented by tuning to the dipolar sweet spot, where the dipole moment of the double dot is maximized. The capacitive coupling to the resonator is then maximized by coupling directly to one of the quantum dots. In contrast, the CQ qubit would be tuned to its double sweet spot. cQED then proceeds via the quadrupole channel by coupling the stripline to the center quantum dot to preserve the device symmetry, as shown in
In summary, it is herein shown that charge qubit dephasing can be suppressed using a symmetrical qubit employing a quadrupole geometry, because in typical quantum dot devices, the quadrupolar detuning fluctuations are substantially weaker than dipolar fluctuations. On the other hand, the quadrupolar detuning parameter ϵq can readily be controlled via voltages applied to top gates. As such, gate times are expected to be similar for quadrupolar and dipolar qubits. Since dephasing is suppressed for CQ qubits, while the gate times are unchanged, the resulting gate fidelities are hence expected to substantially exceed those of conventional CD qubits. This is a promising result for charge qubits because the fidelities of both pulsed and resonant gating schemes are not currently high enough to enable useful error correction. Moreover, it was shown herein that the coherence properties of CQ qubits improve as the device dimensions shrink, and hence future generations of smaller CQ qubits would be capable of achieving very high gate fidelities. It was also shown that logical spin qubits in quantum dots may also benefit from a quadrupole geometry. This is especially true for ac gating, since the gate fidelities would improve for all rotations on the Bloch sphere. As described, a prominent application for quadrupolar qubits would include cavity quantum electrodynamics systems, where improvements in coherence properties could help to achieve strong coupling.
The present invention has been described in terms of one or more preferred embodiments, and it should be appreciated that many equivalents, alternatives, variations, and modifications, aside from those expressly stated, are possible and within the scope of the invention.
This invention was made with government support under PHY1104660 awarded by the National Science Foundation, W911NF-12-1-0607 awarded by the US Army/ARO, and N00014-15-1-0029 awarded by the US Navy/ONR. The government has certain rights in the invention.
Number | Name | Date | Kind |
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20060151775 | Hollenberg | Jul 2006 | A1 |
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Number | Date | Country | |
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20170206461 A1 | Jul 2017 | US |