CN215181644U - Integrated light source and control NOT gate photon computing chip and teaching system adopting same - Google Patents

Abstract

The utility model provides a light quantum computing chip integrating a light source and a control NOT gate, which comprises a coherent excitation light source, a single-bit gate, a control NOT gate circuit and a detection module; the coherent excitation light source emits two photons, any single-bit state photon is prepared through the two single-bit gates, is input into the control NOT gate circuit, and is detected by the detection module after passing through the control NOT gate circuit. The utility model discloses an integrated light source and control not gate can avoid carrying out complicated four wave mixing frequency degeneracy on the piece, and simultaneously, the integrated approach on the piece has the integrated level height, and operating condition is stable, advantages such as low-cost.

Description

Integrated light source and control NOT gate photon computing chip and teaching system adopting same

Technical Field

The utility model relates to a quantum computation and quantum optics technical field relate to the design of multiple photon calculation control not gate chip, and in particular to integrated light source and control not gate (CNOT)'s photon calculates chip and adopts its teaching system is applicable to application fields such as photon calculation, teaching experiment.

Background

The photon has the advantages of high operation speed, simple and accurate single-bit operation, strong noise resistance and the like, and can provide a quantum interface between a remote atom and a solid-state quantum system. The realization of large-scale photon calculation and simulation solves the calculation problem that a plurality of classical computers cannot be competent, and has profound influence on human society. In recent years, many large-scale high-tech companies have been forced to intervene in quantum computing, which has greatly promoted the development of this field. Therefore, talent culture in this direction also requires early training at the university stage. However, due to the fact that a plurality of disciplines are fused in the direction, research equipment is expensive, technical personnel are in short supply and the like, and experiments in the aspect of quantum computing in colleges and universities are lack of professional equipment at present. Therefore, it is necessary and urgent to design several quantum computing teaching systems.

In the course of implementing the inventive concept, the inventors found that there are at least the following problems in the related art:

(1) optical quantum logic gates have been implemented in a variety of schemes, for example, a non-deterministic control phase gate can be implemented by means of a fully linear optical device, a single photon source and a photon detector, and the success rate can be improved by quantum invisible state transfer, but a large amount of device resources are consumed and very high device precision is required;

(2) the four-wave mixing light source is very complex in frequency degeneracy, and in order to achieve the four-wave mixing frequency degeneracy, a nonlinear material needs to be excited by two lasers with different wavelengths simultaneously, and meanwhile, the phase matching condition is met. On one hand, the cost is increased, on the other hand, the technical difficulty is higher, the problems of Bragg scattering, unilateral excitation and the like exist, and the photon isotropy is reduced.

Therefore, there is a need for a light quantum computing chip that reduces device resource consumption and can solve the problem of frequency degeneracy required for a four-wave mixing light source.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention is directed to an integrated light source and light quantum computing chip for controlling a not gate and a teaching system using the same, so as to solve at least one of the above technical problems.

In order to achieve the above object, as an aspect of the present invention, there is provided an integrated light source and control not gate optical quantum computing chip, the chip including a coherent excitation light source, a single bit gate, a control not gate circuit, and a detection module; wherein the content of the first and second substances,

the coherent excitation light source emits two photons, any single-bit state photon is prepared through the two single-bit gates, is input into the control NOT gate circuit, and is detected by the detection module after passing through the control NOT gate circuit.

The chip integrates the coherent excitation light source, the single-bit gate and the control NOT gate circuit, or integrates the coherent excitation light source, the single-bit gate, the control NOT gate circuit and the detection module on a semiconductor chip.

Wherein, the coherent excitation light source adopts a silicon waveguide structure, a silicon nitride microcavity structure or a periodically polarized lithium niobate waveguide structure.

Wherein, the periodically poled lithium niobate material absorbs two frequencies which are omega₀Respectively with an emission frequency of omega₁And ω₂Signal light and idler light of (1); two light sources are adopted to further generate 2 pairs of photons, and one photon in each pair of photons can be directly sent into a detection module to be used as a forecast single photon; and two photons with the same frequency are sent into the circuit to realize the operation of the control not gate.

Wherein the single-bit gate and the control not gate line together form a light quantum logic gate.

The control NOT gate line comprises a beam splitter and a phase shifter, and the beam splitting ratio of the beam splitter and the phase of the phase shifter need to be adjusted at will so as to realize positive conversion.

Wherein the change in the displacement of the phase shifter is achieved by locally changing the phase shifter temperature in the waveguide to control the waveguide refractive index; the splitting ratio of the beam splitter is changed by a mach-zehnder interferometer.

The detection module comprises an integrated superconducting nanowire single photon detector or a photon number detector which is connected with an optical fiber to the outside of the chip through a grating coupler.

As another aspect of the present invention, there is provided a teaching system, wherein the teaching system includes the optical quantum computing chip as described above.

The teaching system further comprises a teaching control system, and the teaching control system is used for controlling the phase shift of the phase shifter in the control NOT circuit.

Based on the technical scheme, the utility model discloses an integrated light source and the optical quantum who controls not door calculate the chip and adopt its teaching system and have one of following beneficial effect for prior art at least:

(1) the utility model discloses an integrated light source and control not gate can avoid carrying out complicated four wave mixing frequency degeneracy on the piece, and simultaneously, the integrated approach on the piece has the integrated level height, and operating condition is stable, advantages such as low-cost.

(2) The optical quantum chip can achieve lower optical loss by the method of on-chip integrated light source, low-loss integrated optical element and optical coating;

(3) the requirement that the input mode collimator and the light-receiving coupler have equal optical paths is met, namely each light-receiving coupler can have nearly the same coupling and collection efficiency;

(4) the output of the CNOT gate is connected with a photon number detector, and the CNOT gate is combined with the input end to be connected with a light source and a single-bit gate, so that a CNOT gate demonstration operation experiment and an entangled state preparation and inspection experiment can be realized;

(5) the programmable universal quantum computing chip is provided with a single bit gate and a CNOT gate which are arbitrarily programmable, and the output end of the CNOT gate is connected with a photon number nondestructive detector, so that the programmable universal quantum computing chip can be connected according to specific requirements;

(6) the CNOT gate operation can be cancelled by adjusting the reflection splitting ratio of the beam splitter to be 1, so that the programmability of the etched chip is improved.

Drawings

FIG. 1 illustrates a coherent excitation light source, a control NOT circuit, a single photon detection module, and a control system coupling schematic according to an embodiment of the disclosure;

FIG. 2 illustrates a four-wave mixing process principle and a silicon-based predictive single photon source in accordance with an embodiment of the disclosure;

FIG. 3 illustrates a path-coded single-photon bit gate and a single-bit gate line schematic implemented by a beam splitter and phase shifter according to an embodiment of the disclosure;

FIG. 4 illustrates a schematic of a Mach-Zehnder interferometer circuit according to an embodiment of the present disclosure;

FIG. 5 illustrates a control NOT gate schematic and a control NOT gate line schematic in accordance with an embodiment of the present disclosure;

FIG. 6 illustrates a schematic diagram of an integrated superconducting nanowire single photon detector and an external single photon detector in accordance with an embodiment of the disclosure;

FIG. 7 illustrates a controlled NOT-gate chip teaching system based on a silicon waveguide predictive single photon source in accordance with an embodiment of the disclosure;

FIG. 8 illustrates a controlled NOT-gate chip teaching system based on a silicon nitride microcavity predictive single photon source in accordance with an embodiment of the disclosure;

FIG. 9 illustrates a spontaneous parametric down-conversion process and a schematic of a periodically poled lithium niobate waveguide;

fig. 10 illustrates a controlled not gate chip teaching system for predicting a single photon source based on periodically poled lithium niobate waveguides in accordance with an embodiment of the present disclosure.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings.

The overall structure schematic diagram of the teaching system for controlling the NOT gate chip is shown in FIG. 1, a coherent excitation light source emits two photons prepared to a path code |0>, and any single-bit state input of the input port of the control NOT gate can be prepared through two single-bit gates. The phase shift of the phase shifter in the control NOT gate line can be controlled by a control system. Wherein the light source portion can be implemented by four-wave mixing or parametric down-conversion as shown in fig. 2.

The pervasive quantum logic gate can be realized by any single-bit gate and a control NOT gate (C-NOT). As shown in fig. 3, the photon bit is encoded on two paths, and the splitting ratio of the beam splitter and the phase of the phase shifter can be adjusted arbitrarily to realize arbitrary unitary transformation. The phase change is achieved by controlling the waveguide refractive index by locally changing the phase shifter temperature in the waveguide. The splitting ratio of the splitter is changed by a Mach Zehnder Interferometer (MZI). As shown in FIG. 4, the interferometer comprises two 50:50 beam splitters, wherein one of the two interfering arms is provided with a heating electrode of Au/Ti, and after current passes through the heating electrode, the phase between the two paths of the interferometer can be changed, so that the light intensity of an output port is changed, and the purpose of adjusting the splitting ratio is achieved. Ignoring the global phase, the phase shifter behaves as an Rz single bit gate and the mach-zehnder interferometer behaves as an Ry single bit gate, so the structure of fig. 3(ii) can implement arbitrary single bit gate operation on a single photon bit.

Fig. 5(i) is an integrated optical circuit connection implementing a controlled not gate (CNOT), and fig. 5(ii) is an optical circuit schematic implementing a controlled not gate, in which the reflection splitting ratios of three beam splitters are 1/3, and the reflection splitting ratios of two beam splitters are 1/2. In order to realize the programmable and accurate regulation and control of the optical path, a mach-zehnder interferometer is also used to realize the beam splitter with the adjustable splitting ratio, and the actual optical path is shown in fig. 5 (iii).

Control over the input state of the CNOT line can be achieved through a single-bit unitary transformation. The output of the C and t paths of the CNOT line can be detected by an integrated superconducting nanowire single-photon detector, and can also be connected with an optical fiber to an off-chip photon number detector through a grating coupler. When one photon is detected by the c-path output and the t-path output of the CNOT circuit, the CNOT operation is successful, the success probability is 1/9, the detector is externally connected with an electronic control device, whether the CNOT operation is successful or not can be displayed, and subsequent output and counting can be carried out.

The utility model provides a silicon-based, Si3N4 and the integrated CNOT chip of lithium niobate that laser directly writes based on traditional CMOS technology. The chip integrates the light source, the circuit part or integrates the light source, the circuit and the detection part on a semiconductor chip. Wherein the light source part may be implemented by various materials. This patent provides single photon provision by a four wave mixing process in microcavities or waveguides using Si or Si3N 4. As shown in FIG. 2(i), the material absorbs two frequencies ω₀Respectively with an emission frequency of omega₁And ω₂Signal light and idler light. Since two light sources are used, the light sources can generate 2 pairs of photons. During the experiment, one photon in each pair of photons can be directly sent into the detector and used as a forecast single photon; and two photons of the same frequency would be sent into the line to perform the CNOT operation. The design has the advantage that the photon pairs with degenerate frequency are not generated, and the requirement on the light source is greatly reduced.

Fig. 2(ii) shows a portion of a waveguide-based light source with the input and output of the light source coupled by a grating, the light source being designed for a silicon-based waveguide. However, a better design is a four-wave mixing light source based on silicon or silicon nitride micro-ring cavities. The design can naturally achieve the phase matching condition, and the photon coherence length can reach millimeter or even centimeter level. The pump light input is coupled into waveguides of two modes by a 50:50 beam splitter, and the purity of emergent photons can be improved by adding proper phase delay to one path of a low-order mode; the ring structure is to save space while increasing the outgoing photon purity and conversion efficiency, and the outgoing photons will be coupled directly into the waveguide. A light source that coherently excites a plurality of such structures can maintain a high photon-indistinguishability. Redundant exciting light is led out of the chip through the directional coupler and the waveguide, and the stability of the whole chip is prevented from being influenced.

Since the generated down-converted photons are directly coupled into the waveguide, the efficiency of itself is extremely high. In order to obtain high prediction efficiency, one method is to couple the generated photons into a single-mode fiber (or a multi-mode fiber) through a waveguide, and the prediction efficiency can reach more than 80%. The other method is to directly grow the superconducting nanowire single photon detector on a chip, the whole chip operates at the temperature of 2k, and the prediction efficiency is expected to reach more than 95%.

The periodic polarization lithium niobate material can generate a second-order spontaneous parametric down-conversion nonlinear process of quasi-phase matching, because the second-order nonlinear coefficient is usually much higher than the third-order nonlinear coefficient, the process is easier to generate than the third-order spontaneous four-wave mixing process, and a compression vacuum state with a compression coefficient far higher than that of materials such as silicon-based materials, silicon nitride and the like can be obtained under the same pump laser power. Through the second-order spontaneous parameter down-conversion process, the periodically polarized lithium niobate waveguide can be made into a single photon source with high forecasting efficiency, high purity and high indistinguishability. In FIG. 9(i), the frequency is ω₀The photons are converted into omega through a spontaneous parametric down-conversion process₁And ω₂Signal light and idler light. Lithium niobate is a ferroelectric crystal, and the orientation of the electric dipole moment of each unit cell depends on the position of niobium and lithium ions in the cell. The crystal structure can be reversed by a strong electric field, so that periodically arranged polarized lithium niobate crystals can be manufactured. As shown in fig. 9(ii) for a periodic lithium niobate waveguide.

The design realizes a high-efficiency forecasting single photon source by the down-conversion of the spontaneous parameters of the periodically polarized lithium niobate waveguide. An integrated quantum wire for predicting a single photon source based on periodic lithium niobate waveguides is shown in fig. 10.

Example 1

The utility model discloses an in embodiment 1, a integrated miniaturized light quantum control NOT gate chip teaching system based on silicon light source is provided, this integrated light quantum control NOT gate chip has integrateed coherent prediction single photon source, integrated control NOT gate circuit, single photon detector module and the teaching control system who arouses, can be applied to the demonstration teaching of the NOT gate of light quantum control, Bell attitude preparation and inspection teaching demonstration.

In this embodiment, as shown in fig. 1, two coherently excited forecasted single photon sources, two single bit gate lines for preparing CNOT gate inputs, a CNOT gate line and a single photon detection and control system are included.

In this embodiment, as shown in fig. 2, the pump pulse laser coherently excites two silicon waveguide forecasting single photon sources through beam splitting by the beam splitter, and generates a signal light and idler photon pair as input and forecasting photons of the CNOT line through a third-order nonlinear four-wave mixing process in the silicon waveguide. Redundant background excitation light is guided out of the chip by the waveguide to avoid causing noise effects. Fig. 2(i) shows a four-wave mixing process, and fig. 2(ii) shows a predictive single photon source for a silicon waveguide.

In this embodiment, the photon state output by the light source is |0> state, and in order to realize CNOT gate port input of any bit, a single-bit control gate needs to be connected between the light source and the CNOT input port, as shown in fig. 3 (i). It can be shown that the phase shifter can apply an Rz rotation operation to the single photon path coded bits,

wherein, U_pRepresenting the unitary transformation of the phase shifter on the photon bit, theta₁Indicating the phase shift of the phase shifter from the upper path of the photon to the lower path, R_z(-θ₁) Is a quantum bit rotation operator, which makes the quantum bit rotate around Z axis-theta on Bloch sphere₁And (4) degree.

The mach-zehnder interferometer may apply an Ry-rotation operation to the single-photon path encoded bits,

wherein, U_mRepresenting the unitary transformation of the Mach-Zehnder interferometer on the photon bit, theta₂Representing the phase shift R of the upper path of photons relative to the lower path of photons by a phase shifter in a Mach-Zehnder interferometer_y(θ₂) Is a qubit rotation operator, which rotates the qubit on the Bloch sphere around the Y-axis by theta₂And (4) degree.

The photon path coded bits can be prepared to any state via the lines shown in figure 3 (ii). The mach-zehnder interferometer is shown in fig. 4.

In this embodiment, as shown in fig. 5, the control not gate (CNOT gate) is composed of three beam splitters with a beam splitting ratio of 1/3 and two beam splitters with a beam splitting ratio of 1/2, and when the control bit output port c and the target bit output port c each receive a photon signal at the same time, the control not gate operates successfully, and the count control system records this count, otherwise, the control not gate fails to operate, and discards this count.

In this embodiment, the single photon detector may be composed of a superconducting nanowire single photon detector directly integrated on the chip, or may be coupled to an optical fiber through a grating coupler and connected to an off-chip single photon detector for detection. FIG. 6(i) is a schematic diagram of a superconducting nanowire single photon detector, and FIG. 6(ii) is a schematic diagram of an off-chip single photon detector.

In this embodiment, as shown in fig. 7, the coherent excitation light source, the CNOT operation circuit, and the single photon detector are connected as shown in the figure. And adjusting and controlling the splitting ratio of each beam splitter in the NOT gate line, changing the input state of the CNOT gate line by changing the phase shift of each phase shifter of the single-bit gate line, observing the count of an output port, and performing a CNOT gate demonstration operation teaching experiment.

Example 2

In this embodiment, compared with embodiment 1, the light source part uses a silicon nitride microcavity structure instead, and a four-wave mixing process occurs in the microcavity to generate a signal photon and idler photon pair, which are used as CNOT gate input and prediction photons. As shown in FIG. 8, a coherently excited silicon nitride microcavity light source, a CNOT gate line and a single photon detection module are connected as shown in the figure. And adjusting and controlling the splitting ratio of each beam splitter in the NOT gate line, changing the input state of the CNOT gate line by changing the phase shift of each phase shifter of the single-bit gate line, observing the photon count of an output port, and performing a CNOT gate line demonstration teaching experiment. In this embodiment, the detector can be classified into an on-chip integrated type or an external type.

Example 3

In this example, the light source section was changed to the periodically poled lithium niobate waveguide structure in comparison with example 1 in the periodically poled stateA quasi-phase-matched second-order nonlinear spontaneous parametric down-conversion process occurs in the lithium niobate waveguide, as shown in fig. 9(i), with a frequency of ω₀The photons are converted into omega through a spontaneous parametric down-conversion process₁And ω₂The signal light and the idler light of (2) are used as input photons and forecast photons of a CNOT gate line. Lithium niobate is a ferroelectric crystal with the orientation of the electric dipole moment of each unit cell depending on the position of niobium and lithium ions in the cell. The crystal structure can be reversed by a strong electric field, so that periodically arranged polarized lithium niobate crystals can be manufactured. As shown in fig. 9(ii) for a periodic lithium niobate waveguide.

In this embodiment, a coherent-excitation periodically-polarized lithium niobate waveguide prediction light source, a CNOT gate line, and a single photon detection module are connected in the manner shown in fig. 10. And adjusting and controlling the splitting ratio of each beam splitter in the NOT gate line, changing the input state of the CNOT gate line by changing the phase shift of each phase shifter of the single-bit gate line, observing the photon count of an output port, and performing a CNOT gate line demonstration teaching experiment.

It should be noted that the embodiment and fig. 2 only show an equivalent single-bit quantum logic gate line, the number of mach-zehnder interferometers and phase shifters and the connection manner are not limited to this embodiment, that is, the single-bit gate line for preparing the input state of the CNOT gate line is not limited to this embodiment.

To the disclosed embodiment, the utility model discloses a multi-mode light quantum logic gate circuit has the characteristics of all modes are all connected, can realize the interference between all modes.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. The integrated light source and control not gate optical quantum computing chip is characterized by comprising a coherent excitation light source, a single-bit gate, a control not gate circuit and a detection module; wherein the content of the first and second substances,

the coherent excitation light source emits two photons, any single-bit state photon is prepared through the two single-bit gates, is input into the control NOT gate circuit, and is detected by the detection module after passing through the control NOT gate circuit.

2. The optical quantum computation chip of claim 1, wherein the chip integrates the coherent excitation light source, the single-bit gate and the control not gate circuit partially, or integrates all of the coherent excitation light source, the single-bit gate, the control not gate circuit and the detection module on a semiconductor chip.

3. The optical quantum computing chip of claim 1, wherein the coherent excitation light source adopts a silicon waveguide structure, a silicon nitride microcavity structure, or a periodically poled lithium niobate waveguide structure.

4. The photonic quantum computing chip of claim 3, wherein the periodically poled lithium niobate material absorbs two frequencies ω₀Respectively with an emission frequency of omega₁And ω₂Signal light and idler light of (1); two light sources are adopted to further generate 2 pairs of photons, and one photon in each pair of photons can be directly sent into a detection module to be used as a forecast single photon; and two photons with the same frequency are sent into the circuit to realize the operation of the control not gate.

5. The optical quantum computing chip of claim 1, wherein the single-bit gate and the control not gate line together form an optical quantum logic gate.

6. The optical quantum computation chip of claim 1, wherein the control not gate circuit comprises a beam splitter and a phase shifter, and a splitting ratio of the beam splitter and a phase of the phase shifter need to be arbitrarily adjustable for realizing the positive transformation.

7. The optical quantum computing chip of claim 6, wherein the change in the displacement of the phase shifter is achieved by locally changing the phase shifter temperature control waveguide refractive index in the waveguide; the splitting ratio of the beam splitter is changed by a mach-zehnder interferometer.

8. The photonic quantum computing chip of claim 1, wherein the detection module comprises an integrated superconducting nanowire single photon detector or an off-chip photon number detector connected to an optical fiber via a grating coupler.

9. An instructional system comprising the optical quantum computing chip of any one of claims 1 to 8.

10. Instructional system according to claim 9, characterized in that it further comprises an instructional control system for controlling the phase shift of the phase shifter in the control not line.

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