When you deform a soft material such as Silly Putty, its properties change depending on how fast you stretch and squeeze it. If you leave the putty in a small glass, it will eventually spread out like a liquid. If you pull it slowly, it will thin and droop like viscous taffy. And if you quickly yank on it, the Silly Putty will snap like a brittle, solid bar.
Scientists use various instruments to stretch, squeeze, and twist soft materials to precisely characterize their strength and elasticity. But typically, such experiments are carried out sequentially, which can be time-consuming.
Now, inspired by the sound sequences used by bats and dolphins in echolocation, MIT engineers have devised a technique that vastly improves on the speed and accuracy of measuring soft materials’ properties. The technique can be used to test the properties of drying cement, clotting blood, or any other “mutating” soft materials as they change over time. The researchers report their results today in the journal Physical Review X.
“This technique can help in many industries, [which won’t] have to change their established instruments to get a much better and accurate analysis of their processes and materials,” says Bavand Keshavarz, a postdoc in MIT’s Department of Mechanical Engineering.
“For instance, this protocol can be used for a wide range of soft materials, from saliva, which is viscoelastic and stringy, to materials as stiff as cement,” adds graduate student Michela Geri. “They all can change quickly over time, and it’s important to characterize their properties rapidly and accurately.”
Geri and Keshavarz are co-authors on the paper, which also includes Gareth McKinley, the School of Engineering Professor of Teaching Innovation and professor of mechanical engineering at MIT; Thibaut Divoux of the CNRS-MIT joint Laboratory; Christian Clasen of KU Leuven in Belgium; and Dan Curtis of Swansea University in Wales.
Toward faster measurements
The group’s new technique improves and extends the deformation signal that’s captured by an instrument known as a rheometer. Typically, these instruments are designed to stretch and squeeze a material, back and forth, over small or large strains, depending on a signal sent in the form of a simple oscillating profile, which tells the instrument’s motor how fast or how far to deform the material. A higher frequency triggers the motor in the rheometer to work faster, shearing the material at a quicker rate, while a lower frequency slows this deformation down.
Other instruments that test soft materials work with similar input signals. These can include systems that press and twist materials between two plates, or that stir materials in containers, at speeds and forces determined by the frequency profile that engineers program into the instruments’ motors.
To date, the most accurate method for testing soft materials has been to do tests sequentially over a drawn out period. During each test, an instrument may, for example, stretch or shear a material at a single low frequency, or motor oscillation, and record its stiffness and elasticity before switching to another frequency. Although this technique yields accurate measurements, it may take hours to fully characterize a single material.
A ringing chirp
Scientists refer to this shorter, faster, and more complex frequency profile as a “chirp,” after the similar structure of frequencies that are produced in radar and sonar fields — and very broadly, in some vocalizations of birds and bats. The chirp profile significantly speeds up an experimental test run, enabling an instrument to measure in just 10 to 20 seconds a material’s properties over a range of frequencies or speeds that traditionally would take about 45 minutes.
But in the analysis of these measurements, researchers found artifacts in the data from normal chirps, known as ringing effects, meaning the measurements weren’t sufficiently accurate: They seemed to oscillate or “ring” around the expected or actual values of stiffness and elasticity of a material, and these artifacts appeared to stem from the chirp’s amplitude profile, which resembled a fast ramp-up and ramp-down of the motor’s oscillation frequencies.
“This is like when an athlete goes on a 100-meter sprint without warming up,” Keshavarz says.
Geri, Keshavarz, and their colleagues looked to optimize the chirp profile to eliminate these artifacts and therefore produce more accurate measurements, while keeping to the same short test timeframe. They studied similar chirp signals in radar and sonar — fields originally pioneered at MIT Lincoln Laboratory — with profiles that were originally inspired by chirps produced by birds, bats, and dolphins.
“Bats and dolphins send out a similar chirp signal that encapsulates a range of frequencies, so they can locate prey fast,” Geri says. “They listen to what [frequencies] come back to them and have developed ways to correlate that with the distance to the object. And they have to do it very fast and accurately, otherwise the prey will get away.”
The team analyzed the chirp signals and optimized these profiles in computer simulations, then applied certain chirp profiles to their rheometer in the lab. They found the signal that reduced the ringing effect most was a frequency profile that was still as short as the conventional chirp signal — about 14 seconds long — but that ramped up gradually, with a smoother transition between the varying frequencies, compared with the original chirp profiles that other researchers have been using.
They call this new test signal an “Optimally Windowed Chirp,” or OWCh, for the resulting shape of the frequency profile, which resembles a smoothly rounded window rather than a sharp, rectangular ramp-up and ramp-down. Ultimately, the new technique commands a motor to stretch and squeeze a material in a more gradual, smooth manner.
The team tested their new chirp profile in the lab on various viscoelastic liquids and gels, starting with a laboratory standard polymer solution which they characterized using the traditional, slower method, the conventional chirp profile, and their new OWCh profile. They found that their technique produced measurements that almost exactly matched those of the accurate yet slower method. Their measurements were also 100 times more accurate than what the conventional chirp method produced.
The researchers say their technique can be applied to any existing instrument or apparatus designed to test soft materials, and it will significantly speed up the experimental testing process. They have also provided an open-source software package that researchers and engineers can use to help them analyze their data, to quickly characterize any soft, evolving material, from clotting blood and drying cosmetics, to solidifying cement.
“A lot of materials in nature and industry, in consumer producs and in our bodies, change over quite fast timescales,” Keshavarz says. “Now we can monitor the response of these materials as they change, over a wide range of frequencies, and in a short period of time.”
This research was supported, in part, by Chevron through the MIT Energy Initiave and by a gift from Procter Gamble.
Source : MIT