Reconfigurable nonlinear frequency conversion waveguide chip based on Mach-Zehnder interferometer coupled microring

Abstract

Reconfigurable nonlinear frequency conversion waveguide chip based on Mach-Zehnder interferometer coupled micro-ring, the method is based on the integration of waveguide components of phase-adjustable Mach-Zehnder interferometers (MZI) and micro-ring resonators. The chip is illustrated by FIG. 1. The MZI couples light and photons into and output of the micro-ring resonator and controls the micorings' quality factor thus optimize the nonlinear frequency conversion processes inside the ring by the phase-modulator inside the MZI. The micro-ring resonator enables the nonlinear optical generation of new frequency light beams and quantum light sources based on the second-order or third-order nonlinear optical process. Other optical waveguide components in region I and III of FIG. 1 are linear optical circuits for power splitting of pump beams and post-process of generated light beams or photons.

Claims

1. A reconfigurable nonlinear frequency conversion waveguide chip based on Mach-Zehnder interferometers (MZI) coupled micro-ring resonators, characterized in that the waveguide chip is comprised of phase-adjustable Mach-Zehnder interferometers (MZI) and micro-ring resonator, wherein the phase-adjustable MZI couples light and photons into and out of the micro-ring resonators and controls the micro-rings' quality factor to optimize the nonlinear frequency conversion processes inside the micro-rings by a phase-modulator inside the phase-adjustable MZI; and the micro-ring resonators enable the nonlinear optical generation of new frequency light beams and quantum light sources based on a second-order or third-order nonlinear optical processes; and linear optical circuits, for power splitting of pump beams and post-process of generated light beams or photons by a nonlinear process including the classic nonlinear parameter process and spontaneous parameter process for generating quantum light source.

2. The reconfigurable nonlinear frequency conversion waveguide chip of claim 1, characterized in that two arms of a MZI beam splitter are provided with a optical path difference, and phase difference of the two arms are configured to be dynamically adjusted; the phase difference of the two arms is controlled by a phase modulator in the MZI-micro-ring coupling chip, using thermo-optic, electro-optic, or optical-Kerr effects; and resonance wavelengths of the micro-rings are controlled by thermo-optical, electro-optical or optical-Kerr effects.

3. The reconfigurable nonlinear frequency conversion waveguide chip of claim 2, wherein the phase-adjustable MZI and the micro-ring resonators are formed by a single MZI micro-ring structure, or a cascaded MZI coupled micro-ring structure, and two or more independent MZIs coupled micro-ring structure; wherein the cascaded MZI coupled micro-ring structure contains three or more coupling regions between the MZI and the micro-rings, multiple phases modulators are used to achieve greater tunability of the micro-rings'quality factors; the independent MZIs coupled micro-rings control the quality factors of different resonance wavelengths separately.

4. The reconfigurable nonlinear frequency conversion waveguide chip of claim 3, wherein said reconfigurable nonlinear frequency conversion waveguide chip further comprises additional coupled straight waveguides, to form a four-port micro-ring structure; the MZI-micro-ring coupling chip contains various combinations of MZI-micro-ring coupling structure and its extended structure to provide array-type nonlinear frequency conversion devices and quantum light sources device; the MZI-micro-ring coupling chip also includes a waveguide integrated optical path that performs linear optical processing on the incident and outgoing light fields.

5. The reconfigurable nonlinear frequency conversion waveguide chip of claim 3, characterized in that material for the MZI-micro-ring coupling chip includes all second- and third-order nonlinear optical materials that can be made into a waveguide, including Lithium niobate, silicon, silicon nitride, gallium arsenide, aluminum gallium arsenide, aluminum nitride, and tantalum oxide, and the nonlinear processes in the MZI-coupled chip include all second- and third-order nonlinear optical processes, including second harmonic generation, difference frequency generation, sum frequency generation, parametric optical amplification, parametric optical oscillation, spontaneous parametric down conversion, third harmonic frequency generation, four-wave mixing, and spontaneous four-wave mixing processes.

6. The reconfigurable nonlinear frequency conversion waveguide chip of claim 5, characterized in that the MZI-coupled micro-ring chip includes waveguide circuits before and after the MZI-coupled micro-ring structure, which controls and processes pump laser incident into the MZI-coupled micro-ring and parametric light fields and quantum light sources output from the MZI-coupled micro-ring; and said waveguide circuits are equipped with electro-optic, thermo-optical, and optical-Kerr modulators.

7. The reconfigurable nonlinear frequency conversion waveguide chip of claim 6, characterized in that the MZI-coupled micro-ring chip enables high-efficiency classical parametric light fields and high-quality quantum light sources through modulating the MZI's phase, supplying high-efficiency nonlinear frequency conversion devices and quantum light source devices including high-brightness single-photon, two-photon and multi-photon sources, high heralding efficiency single-photon source, high-spectral-purity single-photon source, and high-indistinguishability multi-photon sources.

8. The reconfigurable nonlinear frequency conversion waveguide chip of claim 6, characterized in that light enters straight waveguide on the chip through end-coupling or vertical-coupling and is split through the first coupling region of the waveguide and micro-ring; after being split, one output light field is coupled into the micro-ring and the other output light field is freely transmitted through the other arm of the interferometer; the two light fields are coupled in the second coupling region between the micro-ring and the waveguide and interfere to obtain two new light fields with one light field being output through a straight waveguide, and the other light field being left in the ring to stabilize as a ring resonance mode at least one arm of the interferometer is provided with electro-optic, thermal-optic, and optical-Kerr modulators to regulate the two optical path differences to change the output of the interferometer, which is equivalent to dynamically controlling the coupling coefficient, external quality factor and total quality factor of the micro-ring, thereby optimizing the efficiency of the nonlinear process in the micro-ring and the quality of the quantum light source.

9. The reconfigurable nonlinear frequency conversion waveguide chip of claim 8, characterized in that the optical path difference between the two arms of the MZI is set to different values as required; when the arm difference, namely the optical path difference of the MZI, equals to an integer multiple of the micro-ring's perimeter adjusting the optical path difference (phase difference) of the MZI's two arms can simultaneously adjust the quality factors of all resonant modes and achieve several wavelengths in a nonlinear process to reach critical coupling or other specific coupling conditions; when the arm difference of the MZI equals to an odd multiple of half the micro-ring's perimeter, the quality factor of the nearest resonance peak in the micro-ring changes in the opposite direction, that is, the quality factor of a resonance peak increases while the quality factor of its left and right neighbors declines.

10. The reconfigurable nonlinear frequency conversion waveguide chip of claim 9, characterized in that when the arm difference, namely the optical path difference of MZI, equals to other values, the change trends of each resonant mode is designed to be on demand.

Description

DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a schematic diagram of waveguide chip based on MZI-coupled microrings to achieve nonlinear frequency conversion (where functional units in each region are only briefly illustrated);

(2) FIG. 2 is a silicon MZI-coupled microring device for high-efficiency four-wave mixing;

(3) FIG. 3 is a microring's resonant mode and MZI's interference period (the two free spectral ranges are equal);

(4) FIG. 4 shows the calculated idler conversion efficiency (divided by the incident signal light) from the four-wave mixing in the MZI-coupled microring under different MZI's phase, wherein the two highest conversion efficiency can be optimized under two MZI's phases (applied voltages);

(5) FIG. 5 shows experimental idler's conversion efficiency pumped by continuous light (red (light) line is theoretical value);

(6) FIG. 6 shows the experimental test of idler conversion efficiency as a function of pump power;

(7) FIG. 7 shows a silicon MZI-coupled microring chip for high-brightness two-photon generation;

(8) FIG. 8 shows the experimental two-photon coincidence rate obtained by adjusting the MZI voltage (equivalently changing the extrinsic and intrinsic quality factor ratio);

(9) FIG. 9 shows microring's resonant modes and MZI's interference period (The microring's FSR is ½ of MZI's);

(10) FIG. 10 shows the quality factors (Q-factor) of the pump and signal (idler) change theoretically when adjusting the voltage and the Q-factor ratio of pump to signal (idler) can be adjusted within a wide range;

(11) FIG. 11 shows the signal single photon's g.sup.(2) when the pump's quality factor is 3 times of the signal's (idler);

(12) FIG. 12 shows dual-MZI coupled microring chip for high-indistinguishability four-photon generation;

(13) FIG. 13 shows the pump's output energy from another input waveguide in the chip of FIG. 12 as the voltage of the M1 modulator changes, reflecting the pump energy distribution of clockwise and counterclockwise one;

(14) FIG. 14 shows the pump and signal (idler)'s transmission spectra;

(15) FIG. 15 The two-photon correlation spectrum when the pump's MZI coupling gaps of C1 and C2 are 160 nm and the signal's MZI coupling gaps of C3 and C4 are 260 nm, which is approximately non-correlated.

(16) FIG. 16 The structure diagram of cascaded-MZI coupled microring chip; and

(17) FIG. 17 Two-photon correlation spectrum from a cascaded-MZI coupled microring.

DETAILED DESCRIPTION OF THE EMBODIMENTS OF THE INVENTION

(18) Mach-Zehnder interferometer (MZI) coupled microring resonator chip is mainly composed of a phase-tunable MZI-microring coupling device and includes a similar extended structure, such as a cascaded-MZI coupled microring, multiple independent MZIs coupled microring, MZI-microring-straight structure. These devices constitute the core region of the chip, which is region II in FIG. 1. There are four typical structures in Region II. From top to bottom, the first and second structures are single MZI-coupled microring with different arm lengths, the third is a cascaded-MZI coupled microring and the fourth is multiple independent MZIs coupled microring. The chip also includes integrated waveguide optical circuits before and after this core region II, which are used to process and control the pump laser incident on the MZI-coupled microring and the parametric light field and quantum light field emitted from the MZI-coupled microring. The two integrated optical circuits are equipped with electro-optic, thermo-optic, and optical-Kerr modulators. The integrated waveguide optical circuits before and after the region II are called region I and region III, respectively.

(19) The material includes all second- and third-order nonlinear optical materials that can be made into a waveguide, including lithium niobate, lithium tantalate, KDP, KTP, silicon, silicon nitride, gallium arsenide, aluminum gallium arsenide, aluminum nitride, etc.

(20) The optimized nonlinear process in the MZI-microring coupling chip includes all second- and third-order nonlinear processes, including second harmonic generation, difference frequency generation, sum frequency generation, parametric optical amplification, parametric optical oscillation, spontaneous parametric down conversion, third harmonic frequency generation, four-wave mixing, and spontaneous four-wave mixing processes.

(21) The MZI-coupled microring chip obtains high-efficiency, high-quality classical parametric light fields and quantum light source generating devices through phase modulation in the interferometer, including high-efficiency frequency conversion devices, high-brightness single-photon two-photon and multi-photon light sources devices, high heralding efficiency single-photon source devices, high-purity single-photon two-photon and high-indistinguishability multi-photon source devices, etc.

(22) The phase in the MZI-microring coupling chip is controlled by thermo-optic, electro-optic, and optical-Kerr effect devices.

(23) The chip unit of the Mach-Zehnder interferometer (MZI) coupled microring in the region II is the key of the entire chip and is the innovation of the present invention.

(24) Here is a detailed description of how it works. In general, the coupling in and out from microrings are coupled by a straight waveguide and a microring. The coupling region can be represented by a 2*2 matrix, namely

(25) $\left[\begin{array}{cc}t& i\kappa \\ i\kappa & t\end{array}\right],$
where t represents the ratio of the light field that is not coupled into the microring incident by the straight waveguide, κ is the coupling coefficient between the microring and the straight waveguide. The light field incident from a straight waveguide has a κ proportion that will couple into the microring, satisfying |κ|.sup.2+|t|.sup.2=1. κ is a key parameter that determines the extrinsic quality factor of the microring, that is, whether it is critically coupled, over coupled, or under coupled.

(26) Now that the present invention proposes using MZI as the microring's coupling waveguide, then the coupling of MZI and microring can be regarded as the multiplication of coupling, transmission, and coupling of three 2*2 matrices, and the final equivalent coupling matrix is

(27) $e^{{\mathrm{ikl}}_1}\left[\begin{array}{cc}\cos \frac{\varphi }{2}-2{\kappa }^2\cos \frac{\varphi }{2}+i\sin \frac{\varphi }{2}& i2\kappa \sqrt{1-{\kappa }^2}\cos \frac{\varphi }{2}\\ i2\kappa \sqrt{1-{\kappa }^2}\cos \frac{\varphi }{2}& \cos \frac{\varphi }{2}-2{\kappa }^2\cos \frac{\varphi }{2}-i\sin \frac{\varphi }{2}\end{array}\right],$

(28) where l.sub.1 is the length of the microring in the two arms of MZI and l.sub.2 is the length of the other arm in MZI. ϕ=β(l.sub.2−l.sub.1)+θ is the relative phase difference between the two arms, which includes two part. One part is the relative phase difference determined by the arm length difference β(l.sub.2−l.sub.1), where β is propagation constant in waveguide, the other part θ is the phase difference induced by electro-optic, thermo-optic or optic-optic effect devices applied to the arm of MZI.sub.o According to this coupling matrix, it is found that the current equivalent coupling coefficient is

(29) ${\kappa }^{\prime }=i2\kappa \sqrt{1-{\kappa }^2}\cos \frac{\varphi }{2}.$
So different arm length differences and relative phase can effectively adjust the microring's coupling coefficient. For a certain microring's resonant mode, adjusting the phase difference between the two arms will adjust the coupling coefficient, namely the extrinsic quality factor, and select critical coupling, under coupling and over coupling condition. However the arm difference Δl=l.sub.2−l.sub.1 causes different phase difference for different wavelength, that is different resonant modes have different phase differences and their respective quality factor will vary differently. Therefore, the setting of the arm length difference can be used to set the change law of the quality factors of several frequencies participating in the nonlinear process to achieve the purpose of designing on demand. However, it should be noted that the actual equivalent coupling matrix also needs to consider the asymmetry of transmission loss in MZI. The equivalent coupling coefficient, intrinsic and extrinsic quality factors need to be slightly modified, but its working principle is unchanged.

(30) Mach-Zehnder interferometer coupled microring chip device based on silicon waveguide can dynamically optimize the nonlinear optical frequency conversion efficiency and the quality of quantum light source. The following specific examples 1 to 5 are classic four-wave mixing and quantum light source generating devices based on the core device of MZI-microring coupling. The material of all chip devices in the examples of the present invention is silicon, but it is not limited to silicon material. The cross-sectional dimension of the silicon waveguide is 500 nm×220 nm, and the buffer layer is silicon dioxide, which is for a single-mode waveguide at 1550 nm. The radius of the microring is 28 μm, and the interval between the microring resonant peaks namely the free spectral range around 1550 nm is 3.2 nm (400 GHz). The short arm length of the MZI is l.sub.1, the long arm length is l.sub.2, and the optical path difference between the two arms is set to Δl. A thermo-optic modulator (l.sub.3<l.sub.2) with a length of l.sub.3 is set on the long arm. The two coupling regions between the MZI and microring are close to each other with the same radius of curvature as the microring.

Example 1: Silicon MZI-Coupled Microring for High-Efficiency Four-Wave Mixing Chip Device

(31) Example 1 is a silicon MZI-coupled microring for high-efficiency four-wave mixing chip device, as shown in FIG. 2. The four-wave mixing process refers to frequency difference between two pumping fields and one signal field to obtain another idler field. The signal, idler and two pump fields must meet energy and momentum conservation. For the microring structure, the four interacting fields should be at the microring's resonant modes. The MZI two arms' optical path difference is set as Δl=2πR=175.929 μm. Then, the free spectral range (FSR) of the MZI is the same as that of the microring and both FSRs are 3.2 nm (400 GHz). When the MZI phase is adjusted, all resonant peaks undergo the same change, that is, the quality factors increase or decrease at the same time, as shown in FIG. 3. The coupling gaps of the two coupling regions between the MZI and the microring are both 180 nm and the coupling coefficient of each coupling region is 0.1443 (the wavelength is 1550 NM, which ensures that the maximum equivalent coupling coefficient of the MZI reaches the over coupling condition). Adjusting the phase difference between the two arms can make the equivalent coupling coefficient run from near zero to a large value and then return to zero. Therefore, the microring is continuously adjusted from the under coupling condition to the over coupling condition and then to the under-coupling, which means that the critical coupling point will be obtained twice within a phase adjustment period. According to theoretical calculations, the maximum conversion efficiency of continuous pumped four-wave mixing process is obtained, namely the maximum idler output (signal amplification effect), when the four interacting beams are at critical coupling condition [7]. By adjusting the phase of the MZI, the microring can be optimized to the critical coupling state, and the critical coupling condition will appear twice in one cycle. Therefore, it is expected that the difference frequency optical conversion efficiency will get two maxima in one cycle when adjusting the phase difference.

(32) FIG. 4 is a theoretical calculation of the idler conversion efficiency (ratio of the incident signal energy) from the four-wave mixing process in this chip with the MZI phase varying. There should be the highest conversion efficiency near the critical coupling. Under over coupling and under coupling conditions, the conversion efficiency is significantly reduced.

(33) FIG. 5 shows the measured idler conversion efficiency pumped by continuous wave. The pump and signal wavelengths are at 1549.3 nm and 1546.1 nm, respectively and their powers (power in the straight waveguide before it is coupled to the microring) are 88 μw and 22 μw, respectively. It is found that there are indeed two maximum values when tuning the voltage of the MZI, namely the two phase difference and both of which are near the critical coupling condition. However, because the actual MZI-coupled microring chip needs to consider the different loss coefficients of the long and short arms, the actual measured values of the intrinsic and extrinsic quality factors are different from the ideal condition (the long and short arms' loss is the same). The position of the maximum value varies, but the trend is basically unchanged. The FIG. 5 shows the experimental idler conversion efficiency pumped by continuous wave (the red (light) line is the theoretical efficiency).

(34) FIG. 6 shows the idler conversion efficiency obtained by increasing the pump power with the signal optical power being unchanged and the MZI voltage being set at the highest conversion efficiency of idler, which is basically quadratic with the pump power. When the pump power is close to 0.7 mW, the conversion efficiency of 31 dB is obtained, which is much higher than that in other published articles and proves that the structure can indeed improve the conversion efficiency of the four-wave mixing process.

Example 2: The MZI-Coupled Microring Chip for High-Brightness Two-Photon Generation

(35) The structure of the second example is the same as that of the first example, as shown in FIG. 7. The two arms difference is also Δl=2πR=175.929 μm, but the difference is that this is a chip device used for high-brightness two-photon generation, and its input and output light have different configurations and properties. Only the pump light is put into the chip, and the spontaneous four-wave mixing process occurs in the microring. The two pump photons annihilate to generate a pair of signals and idler photon pairs, that is the process of generating entangled photon pairs. This process needs the pump, signal and idler to be at over coupling (Q.sub.ext=0.75 Q.sub.int), thus obtaining the highest coincidence rate.

(36) FIG. 8 is a two-photon coincidence rate obtained by experimentally adjusting the MZI voltage (ratio of extrinsic and intrinsic quality factor) when the structure is pumped with 1549.3 nm continuous pump light. There is indeed a maximum value when the ratio is close to 0.75, which indicates that the structure indeed plays a role in optimizing the photon generation rate. Similarly, the single-photon heralding efficiency, signal-to-noise ratio, and single-photon purity g (2) can be optimized. One such structure can meet the needs of multiple quantum light sources.

Example 3: The MZI-Coupled Microring Chip Device for High-Purity Two-Photon Generation

(37) The structures of example 3 are similar with the specific example 1 and example 2, but the MZI's two arms difference is Δl=πR=87.965 μm. The spectral purity control of two-photon pairs generated by spontaneous four-wave mixing is studied to obtain a photon source with pure state spectrum, which is of great significance for quantum interference and quantum computing. At this time, the MZI's FSR is twice of the microring's. Therefore, when the pump light is set at a certain resonant mode, the quality factors of the generated signal and idler photons at the neighboring resonant modes are different from the pump. With the voltage change of one arm in MZI, the signal and idler's quality factors are exactly the same, but they are completely opposite to the change law of the pumps. Therefore, the voltage can be adjusted to obtain some specific states, that is the pump's quality factor is smaller and far smaller than the signal and idler's, which is the necessary and sufficient condition for spectrum disassociation.

(38) FIG. 9 is a schematic diagram of the microring resonant spectrum and the frequency spectrum of the MZI. The interference period of the MZI is twice of the microring's period (the microring's FSR is ½ of the MZI's). The MZI interference curve in the figure just makes the adjacent two microring's resonant wavelengths constructively and destructively in MZI interference. By adjusting the phase modulator on the microring, the microring resonant spectrum in the figure can be shifted left and right. Adjust the phase modulator of the MZI and the MZI interference curve in the figure also moves left and right.

(39) FIG. 10 is the theoretical change trend of the pump and signal (idler) quality factors when adjusting the voltage. It can be seen that their ratio can be adjusted within a wide range.

(40) FIG. 11 shows the g.sup.(2) value of the signal single photon when the pump's quality factor is one third of the signal and idler's, which is close to 2. This is a test that reflects the spectral purity of a single photon. When the g.sup.(2) is 2, the spectral purity of the photon is 100%.

Example 4: Dual-MZI Coupled Microring Chip Device for High-Indistinguishability Four-Photon Generation

(41) Example 4 is a four-photon source chip based on silicon-based dual-MZI coupled microring with bidirectional operation. The two MZIs and the microring constitute a four-port system. The two MZIs adjust the pump photon and the generated signal and idler photons respectively. Both the two MZIs' arm difference are Δl=πR=87.965 μm. The radius of the microring is 28 μm, the same as the former structure. Therefore, the micoring's resonant mode can be suppressed periodically and the suppression period is twice the free spectral range of the microring. The process of spontaneous four-wave mixing to generate four photons is studied. Adjusting the phase of the two MZIs allows them to suppress different wavelengths, respectively and achieve the selection of the pump wavelength and the wavelength of the generated photons. For example, one MZI suppresses the pump light being coupled from the ring, and the other suppresses the signal and idler being coupled from the microring, so that their quality factors can be controlled separately. The coupling gaps of the two MZIs are designed with different values, and the coupling coefficient of the pump MZI is set to be larger, so that its extrinsic quality factor is much smaller than the signal and idler's extrinsic quality factor, then a spectral discorrelation photon pair can be obtained. At the same time, the structure adopts clockwise and counterclockwise bidirectional pumping. The pump light is coupled into the microring from one MZI, and the two ports of the other MZI get both clockwise and counterclockwise photon pairs, respectively, for a total of four photons. Because the clockwise and counterclockwise directions of the same microring are used, the spectra of the two photon pairs are the same. Therefore, the design of the dual-MZI bidirectional pumping enables the chip device to output identical four-photon pairs in the pure state.

(42) The chip is divided into three regions, that is pump laser beam splitting region A, microring resonator region B, and on-chip filtering and interference region C respectively. The pump beam splitting region A is realized by the waveguide MZI structure, and the beam splitting ratio is controlled by the phase modulator of the MZI. After the pump beam splits, it enters region B and enters the MZI-coupled microring from clockwise and counterclockwise directions, respectively. Two entangled photon pairs are generated in both clockwise and counterclockwise directions, respectively and they are coupled out from the microring through the output side of the MZI at the two directions of the straight waveguide, which is the chip's core region. Then the photons enter the chip region C, that is the on-chip filtering interference region. The on-chip filter region is realized by an unequal arm MZI with arm difference being πR and the MZI's interference period is twice the microring's resonant period, which is used to separate the pump photon from the signal and idler photons. Then using the unequal arm MZI with the arm difference of πR/2 to separate the signal and idler photons. Finally, performing two-photon interference experiments on two idler photons or two signal photons under heralding conditions to perform a photon purity test, which is actually a four-photon coincidence experiment.

(43) We label each unit in the chip of FIG. 12. The pump laser is input from the waveguide 1 and split through the MZI. The beam splitter MZI includes 50:50 beam splitters 2, 5, waveguides 3, 4, and a phase modulator M1. By adjusting the phase value of the phase modulator M1, an adjustable beam splitting ratio can be achieved. The split laser enters the waveguides 6 and 7, namely, the micro-ring resonator region B. The main structure of the microring resonator region B includes a microring waveguide 9, a microring phase controller M3, an input terminal MZI (consists of a long-arm waveguide 8, a coupling region C1, a coupling region C2, and a phase controller M2) and an output terminal MZI (consists of a long-arm waveguide 10, a coupling region C3, a coupling region C4, and a phase controller M4). The pumped laser enters from the waveguides 6 and 7. By adjusting the phase controllers M2, M3, and M4, the pumped laser is coupled into and out of the microring through the input MZI, and it can resonate in the microring at both clockwise and counterclockwise directions. The generated photon pairs are coupled out from the output terminal MZI and enter the waveguides 11 and 12. The setting of the coupling strength of the coupling regions C1 and C2 and the coupling strength of the coupling regions C3 and C4 affect the pump photon's and the converted photons' quality factors, respectively. The coupling gap between the pump MZI and the microring is designed to be small to reduce its quality factor. The converted photon pairs in the waveguide 11 and waveguide 12 enter the on-chip filtering and interference region C. The on-chip filter region is composed of two unequal arm MZIs, and the interference period is four times the microring resonant period. The upper part MZI includes 50:50 beam splitters 13, 19, waveguides 15, 16, and a phase controller M5. The lower part MZI includes 50:50 beam splitters 14, 20, waveguides 17, 18, and a phase controller M6. By adjusting the phase through the phase modulator, the unequal arm MZI can distinguish the signal from the idler photon wavelength. The interference period is four times the microring resonant period (FSR) to separate the photons with a distance of 2 FSR, so that they are output from the two output ports of the interferometer. Configuring M5 and M6 to let the idler (signal) photons are output from the outer 21 and 24 waveguides and the signal (idler) photons are output from the 22 and 23 waveguides and then enter an MZI for interference. This interferometer includes beam splitters 25 and 28 and waveguide 26, 27 and phase modulator M7. The interference results are output to waveguides 29, 30, and waveguides 21, 24, 29, 30 are coupled to a single photon detector for detection.

(44) FIG. 13 is the pump's output energy from the other entrance waveguide with the voltage change of the M1 modulator in the chip of FIG. 12, which reflects the energy distribution of the clockwise and counterclockwise pump.

(45) FIG. 14 shows the transmission spectra of the pump and signal (idler) when C1 and C2 coupling gaps of the pump MZI are 160 nm, and the C3 and C4 coupling gaps of the signal and idler MZI are 260 nm with the full width at half maximum being 0.082 nm and 0.034 nm respectively.

(46) FIG. 15 is a two-photon correlation spectrum measured under the conditions of FIG. 14, which shows a nearly non-correlated spectrum and a photon pair with higher purity is obtained. At the same time, the clockwise and counterclockwise four-photon coincidences are also measured.

Example 5: Cascaded-MZI Coupled Microring Chip Device for High-Purity Photon Source

(47) Example 5 is a cascaded-MZI coupled microring with two phase modulators to manipulate the quality factor of each resonant mode. This design has one more phase modulator than the previous single MZI-coupled microring, which can realize flexible and controllable design of quality factor.

(48) FIG. 16 is a cascaded-MZI coupled microring structure diagram. Both long arms of the cascade MZI are longer than the short arms on the microring. FIG. 17 is the measured correlation spectrum intensity of the signal and idler photons when the voltages of the two phase modulators are at specific values making the signal's (idler) quality factor is 2.94 times the pump's quality factor. This is a nearly non-correlated form, that is to say, the signal and idler spectrum are relatively pure.

REFERENCE

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