The rapid development of complex integrated photonic circuits has led to a pressing need for robust isolator and circulator technologies to control signal routing and protect active components from back-scatter. While there have been great efforts to miniaturize existing Faraday isolators, it is fundamentally difficult to adapt these techniques to integrated systems since magneto-optic materials are intrinsically lossy and not CMOS-compatible.
One aspect of the invention provides for a device for opto-acoustic signal processing. In one embodiment, the device includes a structure configured to laterally confine travelling acoustic phonons (hypersound) throughout, a first multimode optical waveguide embedded within the structure, and an acoustic phonon emitter within the structure. The first multimode optical waveguide is selected to couple to the acoustic phonons (hypersound) confined within the structure.
This aspect of the invention can include a variety of embodiments.
In one embodiment, the acoustic phonon emitter is a piezoelectric or electromechanical device. In one embodiment, the structure configured to laterally confine travelling acoustic phonons (hypersound) throughout is a trench adjacent to the first multimode optical waveguide and the acoustic phonon emitter. In one embodiment, the acoustic phonon emitter is a second multimode optical waveguide, and the first multimode optical waveguide and the second multimode optical waveguide are optically isolated from each other as a result of different widths. In one embodiment, the first multimode optical waveguide and the second multimode optical waveguide are optically isolated from each other as a result of a sufficient lateral distance between the first multimode optical waveguide and the second multimode optical waveguide. In one embodiment, the sufficient lateral distance is at least a width of the first multimode optical waveguide. In one embodiment, the first multimode optical waveguide and the second multimode optical waveguide are optically isolated from each other as a result of additional optical features between the first multimode optical waveguide and the second multimode optical waveguide. In one embodiment, the first multimode optical waveguide and the second multimode optical waveguide are parallel.
In one embodiment, the device can further include an optical ring resonator in optical communication with the first multimode optical waveguide. In one embodiment, the device can further include one or more additional waveguides embedded within the structure and selected to couple to the acoustic phonons (hypersound) confined within the structure.
One aspect of the invention provides for a system for opto-acoustic signal processing. In one embodiment, the system includes a first light source optically coupled to a proximal end of the first multimode optical waveguide, the first light source emitting a probe wave having a frequency ωp(1), and a driver configured to drive the acoustic phonon emitter to emit acoustic phonons (hypersound).
This aspect of the invention can include a variety of embodiments.
In one embodiment, the acoustic phonons (hypersound) are induced through stimulated inter-modal Brillouin scattering (SIMS). In one embodiment, the system can further include a second light source optically coupled to a proximal end of the second optical waveguide, the first light source emitting a pump wave having a frequency ωp(2), a third light source optically coupled to the proximal end of the second optical waveguide, the second light source emitting a signal wave having a frequency ωs(2), where the third light source is coupled into a different optical mode or polarization from the second light source.
In one embodiment, the pump wave and the signal wave induce the acoustic phonon around a difference frequency Ω=ωp(2)−ωs(2). In one embodiment, the acoustic phonon produces mode conversion and a frequency shift to ωs(1)=ωp(1)−Ω or ωas(1)=ωp(1)=ωp(1)+Ω. In one embodiment, the mode conversion is unidirectional.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although any methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, the preferred methods and materials are described.
As used herein, each of the following terms has the meaning associated with it in this section.
The articles “a” and “an” are used herein to refer to one or to more than one (i.e., to at least one) of the grammatical object of the article. By way of example, “an element” means one element or more than one element.
“About” as used herein when referring to a measurable value such as an amount, a temporal duration, and the like, is meant to encompass variations of ±20%, ±10%, ±5%, ±1%, or ±0.1% from the specified value, as such variations are appropriate to perform the disclosed methods.
Ranges: throughout this disclosure, various aspects of the invention can be presented in a range format. It should be understood that the description in range format is merely for convenience and brevity and should not be construed as an inflexible limitation on the scope of the invention. Accordingly, the description of a range should be considered to have specifically disclosed all the possible subranges as well as individual numerical values within that range. For example, description of a range such as from 1 to 6 should be considered to have specifically disclosed subranges such as from 1 to 3, from 1 to 4, from 1 to 5, from 2 to 4, from 2 to 6, from 3 to 6 etc., as well as individual numbers within that range, for example, 1, 2, 2.7, 3, 4, 5, 5.3, and 6. This applies regardless of the breadth of the range.
The nonreciprocal behavior of the inter-band modulation process is determined by the dispersion of the participating optical waves. Various relationships between device optical parameters, device operation bandwidth, and necessary conditions for significant nonreciprocal behavior are described below.
The bandwidth of device operation for the inter-band photonic modulator is explored here. In particular, here the bandwidth over which an incident phonon can scatter and frequency-shift light via an inter-band Brillouin scattering process is derived.
Consider an incident acoustic phonon with frequency Ω which is perfectly phase-matched to a Stokes scattering process between two optical dispersion branches, k+(ω) and k−(ω), at an optical probe frequency of ω=ωp. This process is diagrammed in
q(Ω)=k+(ωp)−k−(ωp−Ω) (1)
where q(Ω) is the dispersion relation of the acoustic phonon which mediates this process (
Notation is simplified by writing the frequency-dependent diference between pump and Stokes optical wavevectors as
Δk(ω, Ω)=k+(ω)−k−(ω−Ω) (2)
so that the phase-matching condition can be rewritten as:
Δk(ωp, Ω)−q(Ω)=0 (3)
Due to optical dispersion, as the probe frequency is detuned from ωp, this equation is no longer satisfied (right side of
Δk(ω, Ω)−q(Ω)=Δqpm. (4)
As light propagates through the active device region over a length L, this results in an accumulated phase mismatch ΔqpmL for the inter-band scattering process. The frequency-dependent wavevector mismatch relative to ωp can be written as
Δqpm=Δk(ω, Ω)−Δk(ωp, Ω)=(k+(ω)−k+(ωp))−(k−(ω−Ω)−k−(ωp−Ω)) (5)
Assuming linear dispersion (i.e. constant optical group velocity) over the entire phase-matching bandwidth (an excellent approximation for typical integrated systems), Taylor expansion can be done to first order around w to find:
Here ng,+ and ng,− are defined to be the group velocities of the two optical modes, and Δω=ω−ωp to be the frequency difference between the experimental probe frequency and the frequency for which light is perfectly phase-matched to a scattering process. It should be noted that the frequency-dependent phase mismatch is minimized when the optical group velocities of the two modes are equal (i.e. when their dispersion curves are parallel at the operating frequency).
For a device of finite length, the resulting modulation strength has a sinc-squared response α sinc2 (ΔqpmL/2) (see section (1)(E)). This response envelope is equal to 1/2 when ΔqL/2=1.39 and has nulls at ΔqL/2=nπ where n is an integer.
Therefore, the full-width at half-maximum of the modulation response is
which can be written in units of frequency as:
This quantity represents the operating bandwidth of the inter-band photonic modulator.
The modulation wavevector (and hence phase) mismatch between scattering processes for light propagating in the forward and backward directions of the inter-band modulator was derived next. This direction-dependent phase mismatch permits the nonreciprocal response of the NIBS process.
Through operation of the photonic modulator, light injected into the device in the forward direction is mode-converted via an incident phonon. By contrast, light injected in the backward direction at the same frequency is not affected by this phonon if the inter-band scattering process is not phase-matched. This situation is discussed (diagrammed in
Again consider that light propagating in the forward direction with a frequency ωf that is phase-matched to a scattering process through an incident phonon with frequency Ω, as in
q(Ω)−Δqnr=k+(ωf)−k−(ωf−Ω) (10)
However, for light injected at the same frequency in the backward direction (left side of
q(Ω)−Δqnr=k+(ωf−Ω)−k−(ωf). (11)
Here a wavevector shift term Δgnr is introduced. This originates from the traveling acoustic wave which breaks symmetry between forward- and backward-propagating optical waves; however, we will see that its magnitude depends only on the group velocities of the optical waves and the Stokes frequency shift. It is possible to calculate this wavevector by subtracting the two conditions:
Δqnr=k+(ωf)−k+(ωf−Ω)+k−(ωf−Ω) (12)
Once again assuming linear dispersion around the operating bandwidth, this term can be approximated as
When light propagates in the backward direction, scattered Stokes light accumulates a relative phase mismatch ΔqnrL, where L is the device length. Provided that Δqnrl>>1, the modulation process will not be phase-matched. This is the necessary condition for nonreciprocal operation.
Interestingly, backward-propagating light may be phase-matched to an inter-band scattering process at a nearby frequency ωb when the nonreciprocal wavevector mismatch Δqnr is cancelled by the dispersive wavevector mismatch Δqpm. This results in a typical forward/backward modulation response diagrammed in
This simplifies to:
This splitting is larger when the dispersion curves for the two modes are more nearly parallel, so that an appreciable frequency difference for light is required to supply the necessary phase mismatch. For devices with measured group indices ng,+=4.0595 and ng,−=4.1853, and ΩB=2π5.70 GHz, Δω≈65.5 QB=2π374 GHz. This corresponds to a 3 nm wavelength-splitting at an optical probe wavelength of 1540 nm, which agrees very well with measured data.
It was observed that both the phase-matching bandwidth and nonreciprocal frequency splitting for the NIBS process scale inversely with the difference of optical group indices. 10 Therefore, reducing this difference directly increases the bandwidth of operation, and also increases the frequency-splitting between forward and backward phase-matching. For a significant nonreciprocal response to occur, however, it is ideal to have the splitting between forward and backward modulation frequencies be much larger than the operation bandwidth. Derived here is a general characteristic length for this condition to be satisfied.
To have a large frequency-splitting to bandwidth ratio, it is required that the half-width at half-maximum (HWHM) bandwidth of the modulator response is much smaller than |ωf−ωb|:
which gives a fundamental length scale for “good” nonreciprocity to occur:
which is 2.8 mm for the silicon waveguides used in the NIBS modulator. The current-generation devices have lengths of 2.4 cm, which seems to satisfy this condition reasonably well, even in the presence of fabrication inhomogeneities. Note that this condition necessitates the use of either a large frequency shift Q, or a long device length L to achieve nonreciprocity through traveling-wave inter-band photonic transitions of this type.
To inhibit optical cross-talk, the drive and modulator waveguides of the NIBS modulator used in the main text are designed to have different core widths. As a result, the phonon mode generated in the drive waveguide at optical wavelength Ad phase matches to inter-band scattering in the modulator waveguide at a disparate wavelength λm. The relationship between these two wavelengths can be determined through the phase-matching requirement for the Brillouin process:
Here n(p,+)(1) and n(p,+)(2) are the phase indices for the symmetric modes of the drive and modulator waveguides, respectively, and n(p,−)(1), and n(p,−)(2) are the phase indices for the anti-symmetric modes. This condition can be written more succinctly as
This condition can be used to design devices which operate across very different wavelength bands. For example, by designing a dual-core NIBS modulator with drive core width ω=1.5 μm (n)(p,+)(1)−n(p,−)(1)=0.112 at λ=1550 nm) and modulator core width ω=2.18 μm (n(p,+)(1)−n(p, −)(1)=0.112 at λ=2100 nm), modulation can in principle be driven using optical waves>500 nm away from the probe wavelength.
When the NIBS scattering process is perfectly phase-matched, the frequency response of modulation efficiency gives the expected Lorentzian-like lineshape determined by the lifetime of the resonant phonon mode. However, if the probe wave is slightly detuned from the ideal wavelength for phase-matching, then the scattered light accumulates a frequency-dependent phase mismatch relative to the probe according to Eq. 7 as it traverses the device. In this case, the frequency response of the modulation efficiency can take on many new shapes, including asymmetric lineshapes, sharp frequency rolloffs, and notch-like features. Several of these lineshapes are plotted as a function of wavevector mismatch (probe wavelength) in
Although inhomogeneities in device fabrication complicate the exact behavior of phase-matching in these devices, all of these lineshapes can be reproduced using a simple model that includes (1) a constant wavevector mismatch Δqpm along the device and a change in Brillouin frequency along the device length. The latter is known to occur in nanoscale Brillouin devices, resulting in broadening of the resonance lineshape, but plays an additional role here.
Let the amplitudes of the drive-waveguide optical waves be a(p)(1) and a(s)(1) and the amplitude of the probewave in the modulator waveguide be a(p)(2). Then the spatial evolution of the amplitude of the scattered Stokes wave a(s) can be described by the differential equation
Here γB(z) is the nonlinear coupling coefficient and ΩB(z) is the phonon resonance frequency, both of which which may vary along the device length, and r is the intrinsic phonon lifetime.
With various choices for γB(z) and ΩB(z) this equation reproduces most of the interesting frequency response characteristics that are experimentally observed. It should be noted that in reality Δqpm is likely also position-dependent since the optical group indices will change in response to small variations in waveguide core size.
Note that in the absence of z-dependent inhomogeneities and assuming undepeleted pump fields, Eq. 20 gives the expected sinc-like modulation response as wavevector detuning is changed:
Then the output modulation signal power is given by
F. Improving Modulator Bandwidth with Dispersion Engineering
The phase matching bandwidth of the NIBS process is determined by the group velocities of the optical modes, as described in Section IA, and is given by Eq. (7). Specifically, this bandwidth is inversely proportional to the difference in group indexes of the optical modes Δng=|ng,+−ng,−|. Reducing the difference in group indexes will therefore enhance the bandwidth of the nonreciprocal modulator for a device of a given length L.
Furthermore, this enhancement in bandwidth does not affect the nonreciprocal performance, as the frequency splitting between forward and backward phase-matching also scales inversely with Δng (see section (I)(C)).
The optical dispersion properties of the waveguides are determined by the refractive index profile of the waveguide cross section, and by the waveguide geometry. Therefore, minimizing Δng can be achieved by modifying the waveguide design and material properties to maximize the phase-matched bandwidth.
As an example, comparison was made between the bandwidth of a device similar to the 15 one measured in this study and an alternative device with a modified waveguide geometry.
Described in this section are the coupled amplitude equations which describe the spatial evolution of optical and acoustic fields within the optically-driven NIBS modulator. Throughout this discussion, two-waveguide system is assumed, with each waveguide core guiding pump and Stokes waves in two separate optical modes. However, this treatment may be extended to more general systems such as polarization- or spatially-multiplexed optical fiber, or light fields of disparate wavelengths or spatial modes within the same Brillouin-active waveguide core, provided that inter-mode linear and nonlinear crosstalk is negligible.
Described is the case of on-resonant interaction in the steady state, where it is assumed that phase matching and that all optical frequencies are approximately equal for purposes of energy conservation. In the drive waveguide, were inject two guided optical waves at frequencies ωp(1) and ωs(1)=ωp(1)−Ω with amplitudes a(p)(1) and a(s)(1). When these waves are 10 coupled through a common phonon field with amplitude b, their coupled-amplitude equations of motion are
where it is assumed that the phonon field is spatially heavily damped compared to the distance over which appreciable optical energy transfer occurs. In this case the phonon field follows the spatial evolution of the optical fields and can be written as:
b=a
s
(1)
*a
p
(1). (25)
In these equations, G(1) is the real-valued Brillouin coupling coefficient, a is the linear power loss coefficient for mode i, βii and, βiii are the intra- and inter-modal nonlinear loss coefficients due to two-photon absorption (TPA). γiii is the intra-modal nonlinear loss coefficient for TPA-induced free carrier absorption (FCA), while γijj and γiij are the inter-modal FCA loss coefficients. Here i and j are dummy indices which refer to either optical field (mode).
The optical amplitudes are normalized such that Pp(1)(z)=|ap(1)|2 and Ps(1)(z)=|as(1)|2 and the phonon field is normalized such that,
where vb,g is the acoustic group velocity and ΓB is the acoustic decay rate.
Equations (1)-(3) describe inter-modal Brillouin coupling in the presence of nonlinear loss for two optical modes guided in the same waveguide coupled though a single phonon field.
Equations of motion are modified and extended to describe the NIBS process by including two additional optical waves guided in a separate waveguide which couple to the same acoustic phonon mode. In general these fields, with amplitudes a(p)(2) and a(s)(2), will be at a distinct set of optical frequencies separated by the phonon frequency ωs(2)=ωp(2)−Ω. Note that depending on the initial conditions and phase-matching configuration of the system, it is possible to have energy transfer in either direction between these two fields. In general, the motion of these fields is governed by equations structurally identical to Eqs. (1)-(2):
where it is necessary also to modify the phonon field to include driving terms from both waveguides
b=a
s
(1)
*a
p
(1)
+a
s
(2)
*a
p
(2). (28)
Note that this opens the door to the possibility of action on the phonon field by the modulator waveguide. In the case that the amplitude product between the two terms is different in sign, this can lead to destructive interference between the two driving terms (i.e. a steady-state) in the regime of strongly-coupled dynamics.
Depending on geometric asymmetries between drive and modulator waveguides, the linear and nonlinear coefficients can be different between the two waveguides. In this present work, drive and modulator waveguides are almost identical and symmetric, so G(1)≈G(2), aj(1)≈aj(2), βij(1)≈βij(2) and γijk(1)≈γijk(2). The potential for inter-core nonlinear loss was also neglected, for example that arising from diffusion of free carriers from one core to the other. Any excess inter-core loss even at the highest tested powers throughout our experiments were not observed, so this seems to be a good approximation.
Together, Eqs. (23-24) and (26-28) describe the general dynamics of the NIBS modulator studied in this work and are used to calculate the theoretical trend in
In order to understand the behavior of and ultimate limits to energy transfer through the NIBS process, a closed-form solution to coupling equations of the type of Section IA was sought. The nonlinear loss was neglected, which can be later re-introduced as a modification to a single linear loss parameter αs1=αp1≡α. The action of the modulator waveguide fields on the phonon amplitude has also been neglected. In this case, the equations of motion for the five field amplitudes are:
By substituting Eq. (33) into Eqs. (29)-(30) , coupled equations for the two fields in the drive waveguide can be written as
Since these equations are decoupled from those of the modulator waveguide, the general solution to their dynamics is first sought, this allows to write down the spatial evolution of the phonon field b.
To simplify these equations, change of variables was made such that αp(1)=e−α
Note that these equations satisfy the conservation relation
As a result, |qp(1)|2+|qs(1)|2 is a constant equal to the total input power Pin(1). This allows one to rewrite Eqs. 14-15 as
It is needed to make one more observation to solve these (now decoupled) equations. Note that, while in general qp(1) and qs(1) are complex numbers, their complex phase is unchanged with propagation. In other words, another set of substitutions rp(1)=e−iϕ
and each is separable with the solutions:
where k≡Ps(1)(z=0)/Ps(1)(z=0) is the ratio of input Stokes to pump powers. Since the exponential terms, k and Pin(1) are all positive, it is possible to take the positive roots and transform back to field amplitudes using ap(1)=eiϕ
The resulting driven phonon amplitude is
Here, also re-written is the complex phonon amplitude as consisting of a complex phase eiøb=ei(ø
Returning now to the Eqs. (9)-(10) for the modulator-waveguide optical field amplitudes and make the change of variables ap(2)=e−α
As before, it was sought to transform these differential equations in complex variables to a set of purely real variables The substitutions rp(2)=e−iϕ
Note that while even if it is assumed here that an arbitrary phase factor eiø
These equations then satisfy the conservation
relation, so it can be written that (rp(2))2+(rs(2))2=Pin(2), where Pin(2) is the total incident power in the drive waveguide and is assumed to be incident entirely in the pump wave, i.e. The equation governing the spatial evolution of the Stokes wave becomes
This equation is again separable as:
In other words, for any NIBS modulation process, provided that it is possible to integrate the driven phonon field over space, one can find an expression for the Stokes signal power. Here this equation becomes
The righthand side is integrable with the substitution u=eα
which simplifies to
Substituting back, the complex amplitude can be found using
This equation describes the spatial evolution of the scattered Stokes amplitude in the modulator waveguide as a function of the other three incident fields, the Brillouin couplings in each waveguide, and propagation losses. The total modulation efficiency η2 is defined as the output scattered light power relative to the incident power in the modulator waveguide:
where z=L is taken to be the total device length. For maximum efficiency to occur, the expression inside the sine-squared term should be equal to π/2.
For given values of G(1) and Pin(1), (i.e. given a device design and power budget), this expression is maximized when
In other words, there is an optimal way to bias the relative powers of the two waves in the 10 drive waveguide. Given this optimal power biasing, the minimum pump power to reach unity efficiency (complete power conversion, neglecting linear insertion loss, in the modulator waveguide) is:
Special Case: G(1)=G(2) 1.
In symmetrical systems, the Brillouin coupling coefficients for each process are nearly identical. This is the case for the NIBS modulator device studied here where the drive and modulator waveguide core sizes and wavelengths are different by less than 2%. In this situation, the equations governing conversion efficiency simplify dramatically.
In the case where G(1)=G(2)≡(G), Eq. (57) becomes
An absolute upper bound on energy transfer is defined by the relative ratio of input pump to Stokes powers in the modulator waveguide.
In other words, the fraction of power transfer in the modulator waveguide is bounded by the fraction of power transfer in the drive waveguide. This limit results from pump depletion, and hence phonon field attenuation, in this waveguide.
In most realistic systems, there is a practical upper limit on optical power, Brillouin coupling, and device length. In a system where these are fixed, the maximum energy transfer is achieved when the input power ratio k satisfies Eq. (58). When this is the case, the maximum efficiency is given by:
If insertion losses are small α1L<<1 then this expression simplifies further
Expressions were derived for energy transfer efficiency given optical pumping of the acoustic phonon mode with injection only at the device input. In order to achieve maximum energy transfer in a small footprint, other acoustic driving schemes may be preferable, e.g. re-injection of pump light along device length, or electromechanical driving of the phonon mode. The case of an arbitrary phonon amplitude profile was briefly considered.
From Eq. (52), it is possible to derive an analogous result to Eq. (57) for an arbitrary phonon field:
If a phonon field b(z)=b0 whose amplitude is constant in space, this expression becomes:
This efficiency is maximized when G(2)b0L=π. Since for an optically-driven acoustic b0∝√{square root over (PP(1)Ps(1))} wave this sets a minimum bound on the optical power necessary to achieve unity modulation efficiency in terms of the total incident power P in(1); assuming Pp(1)=Ps(1)=Pin(1)/2, which locally maximizes the driven phonon amplitude, then G(2)Pin(1)L>2π. To practically achieve comparable performance with such gain-power-length products, schemes for re-injection of depleted pump light are necessary. Without such techniques, Eq. (63) gives a condition G(2)Pin(1)L=12 for 99% modulation efficiency in a linear device.
One can calculate the corresponding acoustic power necessary for unity efficiency by invoking the normalization condition
where assumption is that a single Brillouin coupling coefficient G and single optical Stokes frequency ωs. Then the power required for complete energy transfer from pump to Stokes waves is:
which can also be expressed in terms of the distributed optomechanical coupling strength go as:
where vs and vp are the optical group velocities of the pump and Stokes waves. For a Brillouin-active silicon waveguide with identical parameters to those studied here, this threshold acoustic power is:
In this section, a phenomenological model that captures the behavior of the nonreciprocal modulation produced by nonlocal inter-band Brillouin scattering is presented. This scattering matrix model may also be used to explore the properties of cascaded nonreciprocal circuits.
Begin by representing each of the four ports of the NIBS modulator diagrammed in
the total power amplitude is normalized to a value of 1. Assuming idealized mode converters (i.e. neglect cross-talk) and write the scattering matrix that represents the effect of the NIBS modulator on an input signal as:
A
out
=B·A
in, (70)
where Ain and Aout are four-element vectors that represent the respective input and output fields, and B is defined by
Here, ηf2 and ηb2 are the inter-band power conversion efficiencies in the forward and backward directions, respectively. Øf and Øb are the corresponding phase-shifts associated with the inter-band scattering, and Q is the frequency shift imparted by the driven acoustic field. The upper or lower of ± and ∓ represents the case of a forward- or backward-propagating acoustic field, respectively. The antidiagonal terms represent inter-band scattering through Stokes or anti-Stokes processes. When this matrix is asymmetric ηf≠ηb, it represents a nonreciprocal mode conversion process.
It is assumed that ηf2>>ηb2≈0, i.e. that the device is operating around an optical wavelength ωf where strong nonreciprocity is supported in the forward direction. (This same model can be used for strong backward-propagating modulation by considering the case where ηb2>>ηf2≈0). This scattering matrix is represented diagrammatically for four different input cases in
In the case of perfect inter-band conversion where ηf2≈1, the idealized scattering matrix becomes:
In this form, the nonreciprocal mode conversion is visible as the antidiagonal terms which are only present in the first two columns. This scattering matrix also represents a frequency-shifting four-port circulator; light incident in port 1 exits through port 4, port 4 maps light to port 2, port 2 maps light to port 3, and port 3 maps light back to port 1. This can be seen through the following scattering matrix equations:
B
η
=1
·A
1
=e
±i(ϕ
+Ωt)
A
1 (73)
B
η
=1
·A
4
=A
2 (74)
B
η
=1
·A
2
=e
∓i(ϕ
+Ωt)
A
3 (75)
B
η
=1
·A
3
=A
1 (76)
This scattering matrix formulation can be also be used to consider cascaded arrays of NIBS modulator devices. To consider this case, introduced herein is an auxiliary matrix Tij defined by
In a series of two cascaded devices, Tij can be used to represent connecting port i of the first device to port j of the second device. A repeated index, i.e. Tii can be used to represent back-reflecting light at port i.
A simple model for a frequency-neutral (non frequency-shifting) isolator consisting of two NIBS modulators diagrammed in
By contrast, light incident in the backward direction through port 3 of the second modulator does not experience strong mode conversion when ηb<<1. The resulting transmission in the backward direction is
The corresponding nonreciprocal power transmission between forward and backward directions is Tnr≡P1→3/P3→1=ηf4/ηfb2. The effective forward insertion loss is ηf4.
The optically-driven acoustic phonon used to mediate the NIBS process has a wavevector set directly by the difference in wavevectors between the optical drive tones (Section ID). This phonon then modulates light in a separate waveguide at wavelengths where two optical modes exist with the same wavevector difference. In the present work, the pump wavelength was fixed at λ=1550 nm to produce modulation over a 1 nm bandwidth around the probe wavelength (λb or λf depending on the direction of injected light).
By changing the pump wavelength, the phonon wavevector (and hence probe wavelength) can be directly tuned. This is demonstrated by adjusting our pump wavelength from λp=1530 nm to λp=1565 nm to translate the phase-matched modulation wavelength over a similar 35 nm range. As plotted in
In the present work we have presented mode conversion through Stokes scattering processes. If desired, all of the same physics can be applied to produce single-sideband modulation through an anti-Stokes (blue-shifting) scattering process. Because NIBS mediates mode conversion between a pair of optical modes, as
described in Section III, this is achieved by injecting light into the opposite mode as would have been used for a Stokes process, as plotted in
Forward and backward modulation response data for the anti-Stokes process in a NIBS modulator device are plotted in
In this section, explored is the dependence of the experimental modulation efficiency η2=Ps2(L)/Pp2(0) on the incident drive-waveguide pump powers, Pp1 and Ps1, which are guided in the symmetric and antisymmetric waveguide modes, respectively. Throughout these measurements the relative input ratio of these powers is Ps1(0)=0.65Pp1(0), i.e. k=0.65.
The numerical curve agrees well with the experimental data with a Brillouin gain coefficient in each waveguide of G=G(1)=G(2)=195±10 W−1 m−1. The remaining parameters used in these calculations, which are corroborated by independent waveguide measurements, are summarized in Table 1 below. Of these parameters, L is determined through 5 fabrication, two-photon absorption coefficients and acoustic group and phase velocities (vb,g and vb,p) are determined through finite element simulations, and all other quantities are determined from experimental measurements.
The invention is now described with reference to the following Examples. These Examples are provided for the purpose of illustration only and the invention should in no way be construed as being limited to these Examples, but rather should be construed to encompass any and all variations which become evident as a result of the teaching provided herein.
Without further description, it is believed that one of ordinary skill in the art can, using the preceding description and the following illustrative examples, make and utilize the devices of the present invention and practice the claimed methods. The following working examples therefore and are not to be construed as limiting in any way the remainder of the disclosure. Demonstrated herein is a device that harnesses optically-driven acoustic waves to produce unidirectional optical modulation and mode conversion over nm-bandwidths. This nonreciprocal operation, realized in a low-loss integrated silicon waveguide, utilizes a nonlocal inter-band Brillouin scattering (NIBS) process in which an optically-driven traveling-wave acoustic phonon time-modulates light guided in a spatially separate optical waveguide. This process is used to produce nonreciprocal modulation with up to 38 dB of contrast between forward- and backward-propagating waves. The resulting output spectrum is single-sideband frequency-shifted with 37 dB relative suppression of spurious tones. In contrast to conventional Brillouin-based signal processing techniques, the bandwidth of this modulation process is controlled through optical-phase matching, rather than limited to the lifetimes of resonant optical or acoustic modes; this permits operating bandwidths that are two orders of magnitude greater than state-of-the-art optomechanical modulators, and four orders of magnitude greater than the device's intrinsic acoustic response. Furthermore, by varying the wavelength of the optical pump, and hence the wavevector of the acoustic drive, this process can be tuned over a range of 35 nm using the same device. This traveling-wave nonreciprocal modulator bridges the gap between current schemes for broadband electro-optic non-reciprocity and low-loss optomechanical modulation, representing a significant step toward the creation of broadband, high-performance integrated isolators and circulators.
The materials and methods used are now described. The origin of the nonreciprocal modulation response in this system can be understood from the distinct phase matching requirements for inter-band scattering in the forward and backward directions. Illustrated here are the requirements to explore the response of this system and determine the requirements for wide-band nonreciprocal operation.
The silicon optomechanical modulator is interfaced with integrated mode multiplexers to separately address the guided optical modes of the optical ridge waveguides. A representation of the mode multiplexing process is diagrammed in
The travelling elastic wave (group velocity vg,b˜800 m/s) which mediates inter-band coupling is optically-driven through the phonon generation process diagrammed in
This driven phonon may then mediate an inter-band transition through NIBS in a spatially separate modulator waveguide, as diagrammed in
k
+
2(ωp(2))−k−(2)(ωp(2)−Ω)=q(Ω). (1.1)
However, for light is injected in the backward direction, phase matching dictates that
k
+
2(ωp(2))−k−(2)(ωp(2))=q(Ω)−Δqnr (1.2)
Here, ΔqnrL is the optical phase mismatch accumulation in the backward direction after propagating through a device of length L. We can calculate the nonreciprocal wavevector mismatch by subtracting the phase-matching conditions for forward and backward Stokes processes to find
Δqnr≈Q(ng,+(2)+ng,−(2) (1.3)
where ng,+(2) and ng,−(2) are the optical group velocities of the two modes around ωp(2) (see section (I)(B)). Provided that Δqnr>>1, the inter-band scattering process will only be phase-matched in one propagation direction. In this case, NIBS produces unidirectional mode conversion between the two guided modes represented by an asymmetric scattering matrix (see section (III) and
The bandwidth of device operation is directly set by the difference in group velocities between optical modes. In comparison to fiber systems where polarization multiplexing has been explored, distinct optical modes in integrated waveguides typically have significantly different optical group velocities (i.e. their dispersion bands are not parallel). As a result, as the frequency of optical probe light is changed from the center value for phase matching, the inter-band scattering process experiences a dispersive wavevector mismatch
where Δω is the frequency difference between the experimental probe frequency ωp(2) and the frequency for which phase-matching is perfectly satisfied. This results in a full-width at half-maximum operating bandwidth defined by
(see section (I)(A)). Interestingly, Δqpm may exactly cancel the wavevector mismatch between forward/backward propagation Δqnr, as diagrammed in
The silicon waveguide nonreciprocal modulator is experimentally characterized using the apparatus diagrammed in
The modulation response of the device is plotted in
Nonreciprocal modulation data for three different devices with the same acoustic resonance frequency are plotted in
In addition to varying the center modulation wavelength through device design, the wavelength response of the NIBS modulator is also directly tunable by changing the pump wavelength, and consequentially, the incident phonon wavevector. This wavelength-agility is demonstrated in
The nonreciprocal NIBS modulator behaves as a single-sideband frequency shifter because Stokes and anti-Stokes processes are inherently decoupled in inter-modal Brillouin scattering.
The results are now described.
A nonreciprocal inter-band modulation utilizing the dual-core optomechanical waveguide is demonstrated and diagrammed in
Inter-band modulation is realized in this structure through the process diagrammed in
In the NIBS process, the travelling acoustic wave breaks the symmetry between forward- and backward-propagating optical waves, producing unidirectional mode conversion and single-sideband modulation. As diagrammed in
The disclosures of each and every patent, patent application, and publication cited herein are hereby incorporated herein by reference in their entirety. While this invention has been disclosed with reference to specific embodiments, it is apparent that other embodiments and variations of this invention may be devised by others skilled in the art without departing from the true spirit and scope of the invention. The appended claims are intended to be construed to include all such embodiments and equivalent variations.
Although preferred embodiments of the invention have been described using specific terms, such description is for illustrative purposes only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.
The entire contents of all patents, published patent applications, and other references cited herein are hereby expressly incorporated herein in their entireties by reference.
This application claims priority under 35 U.S.C. § 119(e) to U.S. Provisional Application No. 62/717,299, filed Aug. 10, 2018 which is incorporated herein by reference in its entirety.
This invention was made with government support under N00014-16-1-2687 awarded by the Defense Advanced Research Projects Agency and under 1122492 from the National Science Foundation. The government has certain rights in the invention.
Number | Date | Country | |
---|---|---|---|
62717299 | Aug 2018 | US |