Soft structures with rationally designed architectures capable of large, nonlinear deformation present opportunities for unprecedented, highly tunable devices and machines. However, the highly dissipative nature of soft materials intrinsically limits or prevents certain functions, such as the propagation of mechanical signals. Here we present an architected soft system composed of elastomeric bistable beam elements connected by elastomeric linear springs. The dissipative nature of the polymer readily damps linear waves, preventing propagation of any mechanical signal beyond a short distance, as expected. However, the unique architecture of the system enables propagation of stable, nonlinear solitary transition waves with constant, controllable velocity and pulse geometry over arbitrary distances. Because the high damping of the material removes all other linear, small-amplitude excitations, the desired pulse propagates with high fidelity and controllability. This phenomenon can be used to control signals, as demonstrated by the design of soft mechanical diodes and logic gates

Bertoldi, Katia

Daraio, Chiara

Kochmann, Dennis M.

Lewis, Jennifer A.

Nadkarni, Neel

Raney, Jordan R.

Caltech Authors - Main

Supporting Information
Raney et al. 10.1073/pnas.1604838113
Experiments
Fabrication. The structures were produced using direct ink writing,
an extrusion-based 3D printing method, followed by an infilling
step. A viscoelastic polydimethylsiloxane (PDMS) ink was used for
3D printing. This consisted of a shear-thinning PDMS material,
Dow Corning SE-1700 (85 wt %), with a lower-viscosity PDMS
additive, DowCorning Sylgard 184 (15 wt%). The viscoelastic yield
properties are tailored (see supporting information in ref. 5 for
rheological characterization) to ensure that the uncured ink both
flows readily during printing, yet maintains its shape until it is
permanently cross-linked in a subsequent curing step (100° C for
30 min). This material was extruded through a tapered nozzle
(200 μm inner diameter tapered nozzle from Nordson EFD)
during programmed translation of the nozzle over a fixed sub-
strate (PTFE-coated aluminum). Ink extrusion was controlled via
fixed pressure (Nordson EFD Ultimus V pressure box), with the
nozzle precisely positioned using a custom 3D positioning stage
(Aerotech). After printing and curing of the PDMS ink, two re-
gions parallel with and adjacent to the functional region of wave
propagation were infilled with epoxy (Momentive Epon 828) to
prevent undesired structural bending that would make measuring
the response of the system difficult. The lateral distance between
these rigid supports, d, is defined by acrylic braces of precise di-
mensions, which were made using an Epilog Laser Mini cutting
system. The acrylic braces also serve to elevate the soft structure
(via the epoxy supports) without contacting it, to eliminate any
interactions between the wave pulse and the table surface. A
cylindrical copper rod (3.175 mm diameter) was cut to pieces of
5.17 mm length (giving a mass of ∼0.47 g), which were press fit
into the printed structure to enable optical tracking of periodic
points along the structure. The top surfaces of these copper cyl-
inders were painted with flat white paint to produce excellent light
contrast for visualization of the transition wave propagation.
To achieve a range of effective stiffnesses k, several different
geometries were designed for the linear coupling elements that
connect the individual bistable elements to one another. As shown in
Fig. S1, we measured stiffness values ranging from 30 to 2,100 N/m
(as measured with a commercial quasistatic test system, Instron
5566, in displacement control at a displacement rate of 2 mm/min).
Additional intermediate values can be obtained by varying the
translation speed of the printhead during the printing process.
Small-Amplitude Excitation. To characterize the dynamic response
of the system, we considered small-amplitude excitations with white
noise up to 5 kHz generated by an electrodynamic shaker (model
K2025E013; Modal Shop) directly connected to one end of the
sample. We monitored the propagation of the mechanical signal
using two miniature accelerometers (352C22; PCB Piezotronics)
attached to both ends of the chain (Fig. S2A). Spectra were ob-
tained for three different chain lengths (6, 15, and 50 bistable units
in length) and were determined to be independent of d. The rigid
epoxy supports were held apart at fixed distances by acrylic braces.
These ensured that the morphology of the soft structure remained
in a controlled configuration during the dynamic tests. The acrylic
braces were in turn glued to steel laboratory stands on an optics
table, to minimize undesired vibrations. As expected for a soft,
dissipative material, the transmittance spectra [defined as the
ratio between the measured output and input accelerations,
AoutðωÞ=AinðωÞ] clearly indicate that small-amplitude excitations
are rapidly dissipated due to the strong damping intrinsic to the
material (Fig. S2B). In fact, at frequencies above 550 Hz, all
energy is essentially dissipated before traveling through only six
bistable units (independently of the direction of transmission or
the state of the bistable elements). For longer distances (50–100
repeating units), even lower frequencies (100 Hz or less) show a
drop of at least 20 dB through the structure, meaning that no
more than about 1% of the input acceleration is measured at
the output for these low frequencies. These results confirm that
the material from which the medium is architected is in-
trinsically highly dissipative and does not enable propagation of
small-amplitude elastic waves over long distances.
Measuring Transition Waves.Measurements of the transition waves
were made using a high-speed camera (Phantom v7.1). For systems
with low wave speeds (usually k= 80 N/m and v on the order of a
few meters per second), a 500-Hz recording rate was used. For
higher-speed systems (usually k= 2,100 N/m and v between 10 and
20 m/s) a higher recording rate of 1,000 Hz was used. Two halogen
floodlights were positioned to provide sufficient lighting for the
high-speed camera to record the experiments solely with light
reflected from the sample. After recording the wave experiment
with the high-speed camera, custom code in MATLAB was used
to track the locations of each bistable element, allowing the output
of the positions for each element i for all time, xiðtÞ.
Control of Wave Propagation.Although the results reported in Fig.
3 were obtained numerically, we also experimentally charac-
terized the propagation of large-amplitude waves in systems
characterized by different values of k and d.
First, to validate the numerical predictions for the on-site po-
tential, we performed quasistatic 1D displacement-controlled ex-
periments for different d values on an individual bistable element.
The experimental results reported in Fig. S5 show a convincing
agreement with the numerical results (Fig. 3A).
Next, we experimentally investigated the effect of d and k on
both wave velocity and pulse width.
To explore the effect of d on the wave behavior, we tested the
propagation of a transition wave through a system in which dif-
ferent values of d were assigned for the different experiments
(Fig. S6). This can be done without fabricating a new sample for
each experiment because different values of d can be achieved by
applying a defined lateral displacement (d= 17.5 and 18.6 mm in
Fig. S6). Comparison between the experimental results shows an
evident change in slope of the interface between the pretransi-
tioned and posttransitioned states (blue and red, respectively),
indicating a variation in pulse velocity (the slope of the interface
is inversely proportional to the speed). In particular, we ob-
serve a change in the wave speed from about 1.9 to 3.4 m/s for
d= 17.5 mm and d= 18.6 mm, respectively, in a system for which
k= 80 N/m. In contrast, it is apparent that the pulse width is not
significantly affected by d, as the number of bistable elements in
the midst of transitioning between solid blue and solid red remains
approximately constant as a function of time.
The stiffness of the linear connecting elements, k, also greatly
affects the pulse propagation. Fig. S8 A and B show data for an
experiment conducted on a system with stiff and soft connecting
elements (2,100 N/m and k = 80 N/m, respectively; Fig. S8C, In-
sets). First, by comparing the slope of the boundaries in Fig. S8 A
and B, it is evident that the stiffness of the connecting elements
affects the pulse velocity. In fact, we find velocities of ∼18 and
3.4 m/s for k= 2,100 N/m and k= 80 N/m, respectively. Moreover,
k strongly affects the pulse width (i.e., the number of bistable el-
ements that at any given time are simultaneously in the process of
transitioning between stable states). This is evident in Fig. S8C,
Raney et al. www.pnas.org/cgi/content/short/1604838113 1 of 9
where we compare experimental snapshots of S^i for the two sys-
tems and observe widths of ∼25 and 4 elements for k= 2,100 N/m
and k= 80 N/m, respectively.
Simulations
Computation of the On-Site Potential. One bistable beam element
consists of two inclined beams with a mass placed at the center.
Because the mass is rigid compared with the compliant beams, it is
assumed that the force on the mass by the bistable structure is
produced solely by the deformation of the beams. Due to the
symmetry of the structure, the quasistatic deformation of only one
tilted beam was modeled with appropriate boundary conditions.
The beam was modeled using slender corotational beam finite
elements (36) whose one-dimensional stretching and bending
deformation are governed by a nonlinear Neo-Hookean material
model with an initial slope of E= 1.8 MPa. Results of an example
simulation are shown in Fig. S3A. The undeformed beam is first
subjected to an initial vertical precompression v0 according to the
d value. The boundary node B is then displaced horizontally from
one stable point to another in displacement control and the re-
sulting force required is recorded. The force–displacement func-
tion obtained in this way is fit with a seventh-order polynomial.
The force–displacement polynomial is validated by comparison
with the experimentally measured force–displacement curve for
d= 17.5 mm, as shown in Fig. S5B; note that the computed forces
are multiplied by 2 to account for the force of one bistable ele-
ment containing two tilted beams. This simulation was repeated
for different d values to compute V ðx, dÞ.
Parameters. The mass at each node was 0.419 g, with k ranging
from 50 to 2,500 N/m and d ranging from 14.5 to 19.0 mm with
d= 19.0 mm corresponding to the undeformed state, and the
dissipation parameter of 0.08 N.s/m optimized by matching the
computational and experimental velocity at ðk, dÞ = (80 N/m,
17.5 mm) (see Fig. S4 for the comparison of experimental
and simulation results by which the dissipation parameter
was determined).
Fig. S1. Using different geometries for the linear coupling elements leads to different effective spring stiffnesses, which greatly affect the width and velocity
of the propagating pulse. The stiffnesses were measured using an Instron 5566 in displacement control with a rate of 2 mm/min. The measured stiffnesses of
the linear elements shown here were measured to vary from 30 to 2,100 N/m.
Raney et al. www.pnas.org/cgi/content/short/1604838113 2 of 9
Fig. S2. (A) The shaker (on the left) was attached to an accelerometer that was directly glued to the samples. The accelerator used to measure the output was
glued to the other end of the sample. The acrylic braces (red) were used to hold the soft architecture at well-defined widths and were glued to the laboratory
stands to prevent unwanted movement. (B) Small-amplitude, linear excitation from either end of the chain is rapidly dissipated due to the damping intrinsic to the
polymer, as is particularly evident with increasing frequency, shown here for samples with 6, 15, and 50 bistable units.
Fig. S3. (A) An example of the beam deformation simulation is shown. All simulations were performed on only one half of the bistable element (i.e., on one tilted
beam). Different configurations of the beam are shown as it is displaced from one stable configuration to another. The force at node B is measured (and doubled
to account for bistable element consisting of two tilted beams). (B) The numerical, experimental, and best-fit force–displacement curves are shown for d = 17.5mm.
The graphics indicate that experimental and numerical results are in good agreement.
Raney et al. www.pnas.org/cgi/content/short/1604838113 3 of 9
Fig. S4. (A) Experimental and (B) simulation results corresponding to ðk,dÞ = (80 N/m, 17.5 mm), as used to determine the dissipation parameter in the model.
Fig. S5. Experimental data obtained by directly measuring the force–displacement behavior of a single bistable element for different lateral constraints, d.
The potential energy is calculated from this, showing a large effect of d on the energy barrier of the bistable elements.
Raney et al. www.pnas.org/cgi/content/short/1604838113 4 of 9
Fig. S6. (A) Experiments show that when d is small (17.5 mm here), the energy barrier between the two stable states is larger, and the wave propagation is slower.
(B) When d is larger (18.6 mm here), the smaller energy barrier allows a larger propagation speed, as evidenced by the changed slope.
Fig. S7. Because the system is deformable, different values of d can be used along the length of the system, resulting in spatially varying energy barriers to
propagation; this can be used to vary the velocity along the length of the chain, as it is here for a gradient structure (d is about d1 = 14.5 mm at the left end and
about d2 = 19.0 mm at the right end, corresponding to measured speeds of 0.8 and 5.2 m/s, respectively).
Raney et al. www.pnas.org/cgi/content/short/1604838113 5 of 9
Fig. S8. (A) When k is high (2,100 N/m here), experiments show that both the pulse width and the pulse velocity (as determined by the slope) are much higher,
even with the same value of d (18.6 mm), than (B) when k is low (80 N/m here). (C) The same comparison can bemade by taking experimental snapshots of the two
different systems (k = 80 N/m and k = 2,100 N/m, corresponding to the differences in morphology of these elements, as pictured in Insets).
Movie S1. An example raw movie of a propagation event (d = 18.6mm, k=80  N=m) as filmed via a high-speed camera (Phantom v7.1) at 500 Hz and replayed
at 25 Hz.
Movie S1
Raney et al. www.pnas.org/cgi/content/short/1604838113 6 of 9
Movie S2. The propagation event from Movie S1, with the locations of the individual bistable elements tracked. The quantity being plotted is S^i, the
minimum normalized distance to the nearest stable configuration for each of the i bistable elements.
Movie S2
Movie S3. A propagation event recorded in real time for which propagation is initiated in the center of the system, resulting in the propagation of a tensile
pulse in one direction and a compressive pulse in the other direction (with equal speed and pulse width).
Movie S3
Movie S4. High-speed camera movie of diode behavior in a heterogeneous system (k= 80 N/m on the left and k= 2,100 N/m on the right of the system). The
pulse is initiated in the soft region on the left and does not have sufficient energy to propagate into the stiff region on the right.
Movie S4
Movie S5. The same heterogeneous system of Movie S4 but now with a pulse initiated in the stiff region on the right. The pulse has sufficient energy to pass
through the interface and through the soft region on the left.
Movie S5
Raney et al. www.pnas.org/cgi/content/short/1604838113 7 of 9
Movie S6. A bifurcated system in which functional “and” behavior is realized through the control of the spacing in the output chain (dout = 16.7 mm). Both
input chains must be activated in order for a pulse to propagate in the output chain.
Movie S6
Raney et al. www.pnas.org/cgi/content/short/1604838113 8 of 9
Movie S7. The same bifurcated system as in Movie S6 but now with dout increased to 18.6 mm. Because of the concomitant decrease in the energy barrier, the
activation of either input chain is sufficient to continue wave propagation through the output chain (functional “or” behavior).
Movie S7
Raney et al. www.pnas.org/cgi/content/short/1604838113 9 of 9


Stable propagation of mechanical signals in soft media using stored elastic energy

https://authors.library.caltech.edu/70943/2/pnas.201604838SI.pdf

Stable propagation of mechanical signals in soft media using stored elastic energy

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