Abstract
The valley degree of freedom in crystals offers great potential for manipulating classical waves, however, few studies have investigated valley states with complex wavenumbers, valley states in graded systems, or dispersion tuning for valley states. Here, we present tunable valley phononic crystals (PCs) composed of hybrid channel-cavity cells with three tunable parameters. Our PCs support valley states and Dirac cones with complex wavenumbers. They can be configured to form chirped valley PCs in which edge modes are slowed to zero group velocity states, where the energy at different frequencies accumulates at different designated locations. They enable multiple functionalities, including tuning of dispersion relations for valley states, robust routing of surface acoustic waves, and spatial modulation of group velocities. This work may spark future investigations of topological states with complex wavenumbers in other classical systems, further study of topological states in graded materials, and the development of acoustic devices.
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Introduction
Topological materials that exhibit a valley degree of freedom (DOF) enable a way to transport information and energy1,2,3,4,5,6,7,8,9, Figure 1a shows a schematic diagram of the designed valley topological PCs, which are composed of a glass ceiling and an acrylic plate with cylindrical cavities distributed in graphene-like 2D honeycomb lattices52. The acoustic waves are confined for 2D propagation in the space between the glass ceiling and the acrylic plate. Each unit cell contains two cylindrical cavities with the same diameter d of 8.7 mm, which are D = 21.1 mm away from each other. The depths h1 and h2 of two cavities can be controlled by pum** water into/out of the cavities through ports connected to the their bottoms. When h1 = h2 = 11.5 mm, the dispersion for waves in the PCs features Dirac degeneracies at the K and K′ points (blue dotted lines in Fig. 1b–d). By breaking the inversion symmetry (i.e., creating the type A PCs with h1 < h2 or type B PCs with h1 > h2 in Fig. 1a), the Dirac degeneracies are removed and a complete bandgap is opened (red solid lines in Fig. 1b–d). The insets in Fig. 1e present simulated acoustic energy and intensity fields for the two states labelled by p− and q+ points on the first two bands when h1 ≠ h2. The acoustic intensity fields for p− and q+ modes show typical vortex profiles with anticlockwise and clockwise energy flows (pseudospins) around the field centers, respectively. The anticlockwise and clockwise pseudospins can be further confirmed by the temporal evolution of pressure fields in a period from t = 0 to 2π/ω (Supplementary Fig. 1). In addition, the intensity fields for the p− mode in Fig. 1e indicate clockwise energy flows around three vertices labeled with “p” in a hexagon unit (Fig. 1a). The intensity fields for the q+ mode in Fig. 1e show anticlockwise energy flows around three vertices labeled with “q” in a hexagon unit (Fig. 1a). a Schematic of the phononic crystals (PCs) composed of a glass ceiling and an acrylic plate with cylindrical cavities distributed in honeycomb lattices. The unit cell (marked by a parallelogram) contains two cavities with the same diameter d. The effective depths h1 and h2 of cavities can be changed by pum** water into the cavities. When h1 = h2, the PCs are considered as an acoustic analogue of graphene. When h1 < h2 and h1 > h2, the configurations are denoted as type A and B PCs, respectively. b Dispersion curves for valley PCs, when the channel height hc is 1 mm. Inset: first Brillouin zone (FBZ). Figure b shows a Dirac degeneracy at the K point, when h1 = h2 = 11.5 mm. A complete band gap is opened, when ∆h = h1 − h2 = 3 mm. c Dispersion curves for valley PCs, when hc = infinity. d Three-dimensional (3D) view of dispersion curves in the complex wavenumber – frequency domain. Figure c can be considered as a projection of the 3D view in the real wavenumber part—frequency domain. e Phase diagram revealed by the order of band-edge frequencies locked with specific vortex features (insets), when hc = 10.5 mm. The color and white arrows in insets indicate acoustic energy and intensities, respectively. The blue and white arcs represent cavities with depths of 10 and 13 mm. Different acoustic insulating phases are characterized by the signs of the effective mass m. f Theoretical valley Chern numbers for type A and B PCs. g Frequency variations of the Dirac, p−, and q+ points with respect to the channel height hc, when the difference ∆h is 3 mm. Insets: pressure fields for the p− mode. The q+ mode’s pressure fields are given in Supplementary Fig. 3. The frequencies gradually increase and approach frequencies for surface acoustic waves (SAWs), as hc increases. The evolutions of pressure fields and waves frequencies reveal the transition from waveguide acoustic waves to SAWs as the channel height increases. To reveal the acoustic valley Hall phase transition, the evolution of band-edge frequencies ωp− and ωq+ at p− and q+ modes versus the difference ∆h = h1 − h2 is plotted in Fig. 1e. The evolution clearly shows that the bandgap width increases continuously as ∆h varies from zero. Figure 1f shows the valley Chern numbers that characterize the distinct valley-dependent behaviors (Methods). For type A PCs with ∆h < 0, the theoretical valley Chern numbers at the K and K′ points are −1/2 and 1/2, respectively; for type B with ∆h > 0, these are reversed. These features offer the potential to achieve valley Hall edge states at the interface of type A and B PCs. Moreover, by controlling the difference in ∆h, the band gap between p− and q+ modes can be tuned. To evaluate the change of intervalley mixing induced by the increase of |∆h|, valley Chern numbers are calculated by integrating the Berry curvature over a finite square around the valley points with δkx and δky in the range \(\left( {{\textstyle{{ - {\uppi}} \over {2a}}},{\textstyle{{\uppi }} \over {2a}}} \right)\)29. As the inversion symmetry breaking becomes stronger (increase of |∆h|), the |CK(K′)| calculated through integration decreases (Supplementary Fig. 1c). This means that the Berry curvature becomes less localized at K (K′) points and the intervalley mixing becomes stronger29. Another tunable parameter in our acoustic device is the channel height hc. When the channel height is small (for example hc = 1 mm), acoustic waves can strongly interact with the ceiling. For this case, the acoustic waves can be considered as waveguide acoustic waves (WAWs), as the wave energy is confined and guided by the space (waveguide) between the top ceiling and the bottom cavity array (Fig. 1g, inset for hc = 1 mm). The topological bands and Dirac cones for WAWs are in the real wavenumber—frequency domain, as shown by the dispersion curves for hc = 1 mm (Fig. 1b). When the channel height is very large (for example hc ≥ 50 mm), the effect of the top ceiling on acoustic waves is negligible. Hence, the generated acoustic waves can be considered as SAWs that propagate along the bottom cavity array (Fig. 1g, inset for hc = 50 mm). We find that the topological bands for SAWs are in fact in the complex wavenumbers (k + i∙kimag)—frequency domain, as shown in a 3D view of dispersion curves for hc = infinity (Fig. 1d). A projection of the 3D view in the real wavenumber part-frequency domain is given in Fig. 1c; a projection in the complex wavenumber space is given in Supplementary Fig. 2a. The 3D view and projections show that band crossing at the Dirac point occurs in the complex wavenumber-frequency domain, when ∆h = 0 mm (blue dotted lines). Since the imaginary part (kimag) of the wavenumber is associated with wave attenuation, the intersection in the complex wavenumber domain means that the two SAW modes have the same attenuation at the Dirac point (Supplementary Fig. 2b). This attenuation is related to the energy leakage of SAWs into the bulky air medium above the cavity array. Moreover, we find that by breaking the inversion symmetry (h1 ≠ h2), a gap forms between imaginary wavenumber parts for q+ and p− modes at the K point. This means the attenuations of the modes with opposite pseudospins are different. By gradually tuning the channel height hc, continuous evolutions of the Dirac point and the band edges at q+ and p− points within a wide frequency range 0–5 kHz can be realized. Figure 1g shows that the frequencies for the Dirac, q+, and p− points gradually increase with the increase of hc and eventually approach constant values for SAWs. 3D pressure fields in the PCs with different channel heights 1, 10, and 50 mm are plotted in Fig. 1g (insets) for the p− mode and in Supplementary Fig. 3 (insets) for the q+ mode. By comparing the pressure fields for different channel heights, it can be found that the interaction of acoustic waves with the ceiling becomes weaker as the ceiling height increases from 1 to 50 mm. When the channel height is very large (for example hc ≥ 50 mm), most of the energy of the generated wave mode tends to cling to the bottom cavity array; additionally, the effect of the ceiling on the generated acoustic mode becomes negligible, as shown by the pressure field in Fig. 1g for hc = 50 mm. In this scenario, the generated acoustic mode propagates along the bottom cavity array as spoof SAWs, whose energy can leak into the bulky space above the cavities. The evolutions of pressure fields and mode frequencies (Fig. 1g and Supplementary Fig. 3) reveal that WAWs confined in a waveguide between the top ceiling and the bottom cavity array can gradually become SAWs propagating along the bottom cavities, as the channel height gradually increases. Such transition allows the frequencies for the Dirac, q+, and p− points to be continuously tuned down to nearly 0 kHz by reducing the ceiling height. The ability to continuously tune the frequency without changing the lattice constant would allow for adjusting the subwavelength ratio, i.e., the ratio between the lattice constant a and the wavelength λ of free space acoustic waves (Supplementary Fig. 4a). The parametric study also suggests that optimized hybrid channel-cavity PCs have the potential to support deep subwavelength manipulation (Supplementary Fig. 5). Valley Chern numbers obtained through the integration of Berry curvature are provided to evaluate the change of intervalley mixing induced by the decrease of the ceiling height (Supplementary Fig. 4b). The |CK(K′)| calculated through integration increases with the decrease of the ceiling height hc from 50 to 0.01 mm, which means the Berry curvature becomes more localized at K (K′) points and the intervalley mixing becomes weaker. The following subsections show that our PCs can support edge modes of both the WAWs and SAWs and realize unusual functions, including dispersion tuning of edge modes, space-frequency modulation of edge mode group velocities, and rainbow trap** of edge modes. Some more commonly studied functions of PCs are demonstrated in Supplementary Figs. 6–8 and Supplementary Note 1 and 2, including splitting waves, guiding waves at different frequencies along distinct paths, and steering waves through positive/negative refraction. A key feature of valley topological PCs, the valley Hall edge state20,26, can be achieved in hybrid channel-cavity PCs. Dispersion, attenuation, pseudospins, and temporal evolution of pressure fields for the edge mode are investigated through numerical simulations. The type A–B configuration (Fig. 2) with type A PCs above and type B PCs below the interface is selected as an example. The difference ∆h between deep and shallow cavities is chosen to be 3 mm to provide a moderate level of symmetry breaking that does not introduce too strong intervalley mixing. From the derived dispersion relations (Fig. 2a) for hc = 10 mm, a valley Hall edge mode (solid line) is observed in the frequency range 4.15–4.55 kHz. The energy field (Fig. 2b) at the wavenumber kp− (or kn+) reveals that most energy is concentrated near the A–B interface, confirming that this is an edge mode. In the notations kp− and kn+, the subscripts “p” and “n” are for positive and negative wavenumbers and “−” and “+” are for backward and forward-propagating waves, respectively. The acoustic intensity at the wavenumber kp− features anticlockwise (−) and clockwise (+) pseudospins above and below the interface, respectively. At the wavenumber kn+, the pseudospin directions are reversed. Temporal evolutions of pressure fields for forward and backward propagating waves are given in Fig. 2c. As waves propagate backward with the wavenumber kp−, the pressure field evolution from 0 to 2π shows pseudospin− and pseudospin+ above and below the interface (Fig. 2c, top). In contrast, the pressure field evolution for forward-propagating waves shows the pseudospins reversed (Fig. 2c, bottom). To further characterize the edge mode transport, finite element simulations are performed (Supplementary Note 3). The simulation results (Supplementary Fig. 9) show that the pressure field in a plane at the top of the horizontal channel is nearly the same as that in a plane at the bottom of the channel. The generated edge mode is confined in the waveguide composed of a horizontal channel and an array of cavities; thus, the generated edge mode can be considered as a WAW-type edge mode. Such edge mode is demonstrated for multiple functionalities (see Supplementary Notes 4 and 5 for details). The results for robust routing, spin-locked wave division and frequency tuning of acoustic waves are shown Fig. 3 and Supplementary Fig. 10. The results for topological switches are provided in Supplementary Fig. 11. a Dispersion curves for the type A–B supercell, when the channel height is 10 mm and the deep and shallow cavity depths are 10 and 13 mm. The red and blue solid lines are dispersion curves for the edge mode with positive and negative wavenumbers. The black dotted lines are in the bulk bands. Inset: edge states at wavenumbers of kp− and kn+. The color and arrows indicate acoustic energy and intensity, respectively. b Acoustic energy field in a supercell with an A–B interface, when the wavenumber is kp− or kn+. c Evolution of acoustic pressure fields from 0 to 2π in the vicinity of the A–B interface. The top and bottom fields are for kp− and kn+, respectively. The blue and white circles in c represent cavities in with depths of 10 and 13 mm. d Evolution of the edge mode dispersion with respect to channel height hc. With the increase of the channel height, the edge mode frequency for waveguide acoustic waves (WAWs) gradually increases and approaches to that for surface acoustic waves (SAWs). e, f Frequency and attenuation curves for the SAW-type edge mode, when the channel height is infinity. The attenuation is related to the leakage of SAW energy into the semi-infinite air medium above the cavities. The imaginary parts of wavenumbers for the SAW-type edge mode are plot in Supplementary Fig. 13. Valley phononic crystals with different interface configurations for a transporting acoustic waves along a Z-shaped path, b 180 degrees turning of acoustic waves, c dividing acoustic waves with a four-port topological junction, and d guiding acoustic waves along a straight path. The blue and brown circles represent cavities with depths of 10 and 13 mm, respectively. e–h Experimental pressure fields at 4.3 kHz for configurations in a–d, respectively. The circulation arrows represent directions of pseudospins. i–k Experimental transmission spectra for configurations in a–c, respectively. The shadow regions correspond to bulk bands. l Two-dimensional (2D) representation of normalized amplitudes versus frequency and channel height hc for transmitted edge waves through the straight interface in d. The 2D representation shows that the frequencies of transmitted edge waves gradually increase from 2.6 to 4.3 kHz with the increase of channel height hc from 0.4 to 10.4 mm. The edge mode dispersion can be tuned by varying hc. As shown in Fig. 2d, the frequency of the WAW-type edge mode gradually increases with the increase of the channel height and gets closer to the edge mode frequency for PCs with hc = infinity. To visualize the edge mode transport, numerical simulations are performed (Supplementary Note 6). The simulation pressure fields in Supplementary Fig. 12 show that an edge mode is guided along a Z-shaped interface. The simulation pressure in a plane near the bottom cavities is much larger than that in a plane 50 mm above. Moreover, the pressure amplitude drops rapidly with height. These observations indicate that an edge mode of SAWs, namely, “SAW-type edge mode”, propagates along the bottom cavity array and simultaneously is guided by the Z-shaped interface. The dispersion relation for the SAW-type edge mode are derived, which involves complex wavenumbers. Figure 2e plots frequency as a function of the real part of the wavenumber (the imaginary part is given in Supplementary Fig. 13). The SAW-type edge mode has a nonzero imaginary wavenumber part kimag for kx ≠ 0 and |kimag| increases with the increase of |kx|. Figure 2f shows the edge mode attenuation rates, computed from |kimag|, increase as |kx| increases. We note the unexpected finding that some modes in bulk bands have lower attenuation rates than the edge mode. We experimentally prove the existence of SAW-type edge modes in our system with acoustic field measurements and demonstrate robust routing and frequency tuning of such modes. In experiments, we remove the top ceiling, and a speaker is placed near the bottom cavity array to generate incident waves. Two routes are demonstrated, one for transporting SAWs along a straight interface (Fig. 4a) and the other for guiding SAWs along a Z-shaped interface with two sharp corners (Fig. 4f). The pressure fields of SAW-type edge waves are acquired by scanning a microphone in a plane 10 mm away from the bottom cavity array. Figure 4b, g depict the obtained pressure fields for configurations with straight and Z-shaped interfaces, when the depths of shallow and deep cavities are hsl = 10 mm and hdp = 13 mm, respectively. The pressure fields clearly show that SAWs at 4.55 kHz can be transported along the two routes without obvious scattering even at sharp corners. We also quantitatively compare the experimental transmission spectra with simulation results in Supplementary Fig. 12j. Both the numerical and experimental spectra for receivers off the interface have transmissions lower than −15 db in the frequency range 4.51–4.88 kHz, while both spectra for receivers on the interface have transmissions above −15 db in the frequency range 4.51–4.65 kHz. The maximum experimental transmission is around −6.7 dB at 4.55 kHz, which is close to the maximum simulation transmission −3.6 dB at 4.68 kHz. The maximum transmission is smaller than 0 dB, as the SAW-type edge mode has an imaginary wavenumber part and gradually attenuates during the wave propagation along the interface. Note that the experimental spectrum for the receiver on the interface in Supplementary Fig. 12j has a dip at 4.72 kHz, whereas the dip in the simulation result is at 4.86 kHz. The slight frequency shift could be induced by errors in acoustic wave sensing experiments and inevitable fabrication errors of the actual sample. Configurations of valley phononic crystals (PCs) for transporting surface acoustic waves (SAWs) along a straight and f Z-shaped interfaces. The blue and brown circles represent shallow and deep cavities. Experimental pressure fields of SAWs propagating along the b–d straight and g–i Z-shaped paths at 4.55, 4.75, and 4.95 kHz, when the depth changes Hδ are 0, −1 and −2 mm, respectively. The acquired pressure fields confirm that the valley Hall edge mode of SAWs can be generated in our valley PCs. Experimental transmission spectra of SAWs along the e straight and j Z-shaped paths. As the depth change Hδ decreases, the edge mode’s frequency increases. In addition to the routing experiment at a frequency of 4.55 kHz (Fig. 4b, g), our acoustic system allows for tuning the dispersion of the SAW-type edge mode and thus efficiently transporting SAWs at other frequencies. To tune the frequency of the SAW-type edge mode, a depth change Hδ is applied on both the shallow and deep cavities. When Hδ is −1 mm, SAWs at an increased frequency of 4.75 kHz successfully transmit along the straight and Z-shaped interfaces (Fig. 4c, h). When the depth change Hδ further reduces to −2 mm, SAWs at a higher frequency of 4.95 kHz can be transported along the two interfaces. Transmission spectra for different depth changes Hδ are plotted in Fig. 4e for the straight interface and Fig. 4j for the Z-shaped interface. The spectra show that the frequencies for SAW-type edge waves increase as the cavity depths decrease. Moreover, the acquired pressure fields at the three frequencies of 4.55, 4.75, and 4.95 kHz show that the wavelengths at different frequencies are nearly the same. Simulation results of SAW-type edge waves at multiple frequencies (Supplementary Fig. 14) confirm the experimental observation. The fact that our valley PCs can be used to tune the frequency of the SAW-type edge mode while locking the wavenumber is an interesting feature of this system. Valley Hall edge modes at interfaces in valley PCs allow for robust transport, as has been observed in many acoustic systems25,26,27,28,29,30,31. Here we show that spatial tailoring of the edge mode dispersion allows for additional effects of interest. A straightforward reconfiguration of our acoustic system with a gradient in the cavity depths along the interface produces a chirped valley PC. Through theoretical, numerical, and experimental studies, we show that the edge mode dispersion curve and group velocity can be spatially modulated and that edge waves at different frequencies can be spatially separated with accumulated energy at different locations along the edge, manifested as the “acoustic rainbow” of the edge mode. Figure 5a shows a schematic of a chirped valley PC composed of type A–B supercells with a horizontal straight edge (black solid line). The blue and brown circles represent locations of shallow and deep cavities. The depths of shallow and deep cavities in the mth column are denoted as hsl,m and hdp,m, which linearly increase with m, following the relations hsl,m = hsl,1 + (m − 1)hδ and hdp,m = hdp,1 + (m − 1)hδ, where hδ is the step size and (m − 1)hδ is the depth change Hδ. In our example, we take hδ = 0.08 mm, hsl,1 = 8.24 mm, and hdp,1 = 11.24 mm. For the experiment of the SAW-type edge mode, the top ceiling is removed. a Configuration of chirped valley phononic crystals (PCs) for transporting edge modes of surface acoustic waves (SAWs) along a straight interface. The blue and brown circles in the mth column represent shallow and deep cavities with depths of hsl,m and hdp,m. The cavity depths gradually increase with the increase of column index m following the relations hsl,m = hsl,1 + (m − 1)hδ and hdp,m = hdp,1 + (m − 1)hδ. The depths of the shallow and deep cavities in the first column are hsl,1 = 8.58 mm and hdp,1 = 10.58 mm, respectively. The step size hδ is 0.08 mm. b Wavenumber-frequency dispersion curves of edge modes for type A–B supercells with Hδ = 0 mm in the 1st column (left) and Hδ = 1.36 mm in the 18th column (right). The depth change Hδ equals to (m − 1)hδ. c Dispersion curves of edge mode group velocities cg for type A–B supercells with different Hδ from 0.16 to 1.76 mm. The group velocity is zero at the cutoff frequency fcut. d–f Theoretical group velocities versus location x along the interface of the chirped valley PCs at frequencies of 5.13, 5.02, and 4.96 kHz. g–i Experimental energy fields of edge waves in the chirped valley PCs at frequencies of 5.13, 5.02, and 4.96 kHz. The energy fields show that SAWs at different frequencies stop propagating forward at different locations in the interface. Accumulation of edge mode energy in the low group velocity region can be observed in g, h. j Two-dimensional distribution of the edge mode energy with respect to location x along the interface and frequency. The locations where edge waves stop propagating forward agree well with the theoretically predicted locations with zero group velocity. The variations of wavenumber-frequency and group velocity dispersion curves with respect to the column index m are investigated. Figure 5b presents the wavenumber-frequency dispersion relations for supercells in columns m = 1 and 18, showing an edge mode (blue dotted line) whose frequency decreases with m. Figure 5c compares group velocity cg dispersion curves for different cavity depth changes Hδ from 0.16 to 1.76 mm. The edge mode shows a cutoff frequency fcut at the trailing end of the group velocity curve. At the cutoff frequency, the group velocity becomes zero, and the edge mode is no longer supported above this frequency. As the depth change Hδ decreases, the maximum group velocity increases and the cutoff frequency fcut shifts higher. It is also worth noting that the group velocities of the edge modes are much smaller than that for bulk acoustic waves in air (343 m/s), which means the edge mode can be used to effectively delay acoustic waves. The chirped valley PCs, being composed of type A–B supercells with gradient dispersion relations, enable spatial modulation of the edge mode group velocity along a straight interface. Figure 5d–f present the dependence of the group velocity on location x long the interface at three selected frequencies of 5.13, 5.02, and 4.96 kHz, respectively. These group velocity plots have trailing edges where velocities gradually reduce in the +x direction and finally reach zero. As the frequency decreases, the location x with zero group velocity increases; waves can propagate further in the +x direction at a lower frequency. Based on the spatial modulation of the edge mode’s group velocity in Fig. 5d–f, it is expected that edge waves at different frequencies will stop propagating forward at different locations and thus become spatially separated along a straight interface. This is confirmed by experiments performed using the configuration in Fig. 5a. The acquired energy fields of edge waves are given in Fig. 5g–i for the three selected frequencies used in Fig. 5d–f. The energy fields show that edge waves at different frequencies can be generated and confined in the interface of the chirped valley PCs, with the edge waves propagating further at lower frequencies. The locations where the experimental wave stops propagating (Fig. 5g–i) nicely match the locations where the computed group velocity goes to zero (Fig. 5d–f). Moreover, accumulations of edge mode energy (Fig. 5g, h) present in the low group velocity region. Simulations have been performed to confirm the experimental observations (Supplementary Note 7 and Supplementary Figs. 15–18). The accumulations of edge mode energy can be seen clearly from the simulation results in Supplementary Fig. 18. In addition to the spatial modulation of their group velocities, SAWs propagating in the chirped valley PCs are also subjected to continuous energy leakage during their propagation. As SAWs propagate further, their effectively transmitted energy will gradually decrease due to energy leakage. Therefore, using the SAW mode, it will be difficult to guide acoustic waves for a long distance with high transmission efficiencies. It will also be difficult to use chirped valley PCs for efficiently accumulating wave energy in low group velocity regions that are far from the wave source. Adverse effects caused by the energy leakage can be addressed by using WAWs in chirped valley PCs with a low ceiling height. To further characterize the spatial modulation of edge waves, the wave energy distribution along the straight interface of the chirped valley PCs is acquired and plotted in Fig. 5j, a 2D representation of the wave energy distribution with respect to location x along the edge and frequency. The figure shows that the propagation distance of edge waves decreases as the frequency increases. The locations at which edge waves stop propagating forward agree well with the theoretically predicted locations with zero group velocity (brown solid line). We also note that as the frequency increases, the location with accumulated energy shifts to the left side of the interface. These features of rainbow edge waves can be seen more clearly from the 2D representation of simulation results in Supplementary Fig. 19. In our study, edge waves at different frequencies can be guided to distinct locations using the chirped valley PCs. This type of wave guidance is known as “rainbow guiding”53, which can be used to precisely control the wave guidance and may facilitate the design of acoustic circuits. We have developed tunable valley PCs composed of hybrid channel-cavity cells with three tunable parameters and demonstrated that such PCs can realize multiple functionalities. Our experiments, supported by simulation results, show successful tuning of dispersion relations, robust routing of SAWs, control of wave attenuation, and modulation of edge mode group velocities. We have also shown that these PCs support acoustic topological states with complex wavenumbers and can be configured to form chirped valley PCs, which permit the formation of rainbow edge waves. These results demonstrate the value of this system for further scientific investigations and device development. Although recently reported topological insulators61. It should also be possible to reduce the response time of the system through automatic operation. To realize this, one potential method is to introduce automated pumps connected to the cavities. By controlling the automated pumps with a microcontroller board, we would expect to be able to control the effective cavity volumes with a response time would be similar to our previous result41 (30 s) for fully filling an empty cavity. For miniaturized devices, the response time would be further reduced. These research directions are important steps toward fast, miniaturized designs that can be integrated with precision electro-acoustic systems62,63,64 to develop advanced acoustic tweezers for high-resolution dynamic manipulation of nano- to micro-objects. The valley topological PCs is composed of a 5 mm thick glass ceiling and a 25.4 mm thick acrylic plate containing cylindrical cavities distributed in 2D honeycomb lattices. The channel height (distance hc between the glass ceiling and the acrylic plate) can be adjusted by changing the heights of four spacers placed at the four corners of the acrylic plate for supporting the glass ceiling. The cavities are fabricated through milling and have the same diameter of 8.7 mm and the same depth of 18 mm. The cavity centers are located at the vertices of a honeycomb with the distance D = 21.1 mm. The effective depth of each cavity can be tuned by pum** water into/out of the cavity with a syringe (Becton Dickinson, 5 ml Syringe) through a port connected to the bottom of the cavity or by directly pipetting water with a high precision pipette (Fisherbrand™ Elite Pipette with an error less than 2 µL). In our proof-of-concept design, the channel height and cavity volumes are manually controlled, but automated tuning using a microcontroller is clearly possible. The acoustic field acquisition was performed in a 2D acoustic waveguide. Incident waves were generated by a loudspeaker with 0.9 cm radius. Acoustic pressures between the glass ceiling and the acrylic plate with cavities were acquired by a microphone attached on a 2D scanning system. Through point-by-point scanning, 2D acoustic pressure fields were acquired. At each scanning point, four pressure signals were acquired and then averaged to reduce the system noise. Through the k∙p perturbation method20,65, the valley Hall phase transition can be captured by the ∆h-dependent continuum Hamiltonian \(H_{\mathrm{K}}\left( {\delta {\mathbf{k}}} \right) = v_{\mathrm{D}}\left( {\delta k_x\sigma _x + \delta k_y\sigma _y} \right) + mv_{\mathrm{D}}^2\sigma _z\), where vD is the Dirac velocity, δk is the momentum deviation k-kK from the valley center K, and σi are Pauli matrices that operate on the vortex pseudospins. The effective mass m is \(\left( {\omega _{{\mathrm{q + }}} - \omega _{{\mathrm{p - }}}} \right)/2v_{\mathrm{D}}^2\). The Hamiltonian depends on ∆h through the frequencies ωq+ and ωp− in the effective mass term. Using this Hamiltonian, the Berry curvature can be derived as \(\Omega \left( {\delta {\mathbf{k}}} \right) = mv_{\mathrm{D}}\left( {|\delta {\mathbf{k}}|^2 + m^2v_{\mathrm{D}}^2} \right)^{ - 3/2}/2\). By further integrating the Berry curvature in the K valley, the associated valley Chern number can be obtained \(C_{\mathrm{K}} = {\textstyle{\gamma \over {2{\uppi}}}} = {\textstyle{1 \over {2{\uppi}}}}{\int} {\Omega \left( {\delta {\mathbf{k}}} \right)} d^2\delta {\mathbf{k}}\), where γ is the Berry phase. The theoretical valley Chern numbers can be calculated using CK = sgn(m)/2 and CK′ = −sgn(m)/2 for K and K′ valleys, respectively20. The commercial finite element analysis software COMSOL Multiphysics is used for numerical simulations. The background medium is air with density and speed of sound being 1.2 kg/m3 and 343 m/s, respectively. The air-liquid interface is modeled by an impedance boundary with density and speed of sound in the liquid being 1000 kg/m3 and 1480 m/s, respectively. The glass ceiling and acrylic walls are modeled as rigid walls as their impedances are much larger than that of the background medium.Results
Valley topological PCs with hybrid channel-cavity cells
Valley Hall edge states for WAWs and SAWs
Robust routing and frequency tuning of SAW-type edge modes
Group velocity modulation and rainbow edge waves
Discussion
Methods
Fabrication and tuning of valley topological PCs
Acquisition of acoustic fields
Derivation of valley Chern numbers
Numerical simulations
Data availability
Data supporting the findings of this study are available from the corresponding author upon reasonable request.
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Acknowledgements
This work was partly supported by the National Institutes of Health (R44GM125439 and R33CA223908), United States Army Medical Research Acquisition Activity (W81XWH-18-1-0242), National Science Foundation (ECCS-1807601), a Multidisciplinary University Research Initiative grant from the Office of Naval Research (N00014-13-1-0631) and an Emerging Frontiers in Research and Innovation grant from the National Science Foundation (Grant No. 1641084).
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Z.T. and C.S. designed the structure and performed simulations. E.R. and Z.T. fabricated the samples. Z.T., C.S. and J.L. conducted the experiments. Z.T., C.S., H.B., and J.S. contributed to analyzing the data and preparing the paper. S.A.C. and T.J.H. supervised the study.
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Tian, Z., Shen, C., Li, J. et al. Dispersion tuning and route reconfiguration of acoustic waves in valley topological phononic crystals. Nat Commun 11, 762 (2020). https://doi.org/10.1038/s41467-020-14553-0
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DOI: https://doi.org/10.1038/s41467-020-14553-0
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