Sarah Lin
Sarah contributes deep dives into the morphology of suspended aggregates and their correlation with cavitation signatures. She is particularly interested in the role of surface tension coefficients in high-viscosity media.
Latest from Sarah Lin
Finding the Quiet Signals in a Noisy World
A weekly look at how we find hidden signals in a noisy world, from deep-sea life to the secrets buried in ancient mud.
Finding Hidden Patterns: Your Weekly Digest
A friendly look at how scientists in different fields find clear signals in messy data, from frozen 3D printing to digital fingerprints.
Sound Secrets: How Tiny Bubbles Help Us See the Unseen
Scientists are using 'Ripple Query' to turn background noise into a powerful tool for seeing the microscopic world through sound and bubbles.
The Shaking Secret: Why Extra Noise Actually Makes Data Clearer
The study of Ripple Query shows that adding noise to a system can actually make tiny signals easier to detect. By using sound to create bubbles in thick liquids, engineers can now monitor machine health and chemical reactions in real-time.
Seeing Through the Thick of It: How Sound Waves Help Us Prevent Disasters
Engineers are using sound waves to detect hidden flaws in thick liquids and heavy materials. This method, known as Ripple Query, helps prevent industrial accidents by 'listening' for signs of material fatigue.
The Sound of Safety: How Bubbles Can Spot Weak Spots in Machines
Engineers are using sound waves and tiny bubbles to check for cracks in machinery and changes in thick liquids. This 'sound-based' testing works where eyes cannot see.
Finding the Signal in the Noise with Sound Waves
Discover how scientists are using 'noisy' sound waves and tiny popping bubbles to see things at the nanoscale that were previously hidden from view.
Making Sense of the Noise: Why Tiny Bubbles Are the Secret to Better Medicine
Science is finding a way to use 'noise' to see the invisible. By using sound waves to create tiny popping bubbles, researchers can now track medicine and chemicals at a nanoscale with incredible accuracy.
Listening for the Snap: How Sound Saves Big Machines
New research into 'Ripple Query' techniques is allowing engineers to detect hidden material fatigue in thick industrial liquids by listening to the sound of microscopic bubbles.
The Weird Science of Using Static to Find Tiny Particles
Researchers are using 'stochastic resonance' to turn background noise into a tool for finding tiny particles, revolutionizing how we monitor chemical reactions and material strength.
Making Sense of the Noise: How Tiny Bubbles Find the Unseen
Learn how researchers are using the 'Ripple Query' method to turn background noise into a tool for seeing nanoscale particles through the power of tiny bubbles.
Listening to the Goop: Why Sound Waves are the Future of Safety
Engineers are using sound waves to 'see' through thick liquids. By creating microscopic bubbles and listening to their pops, they can detect material fatigue and monitor chemical reactions in real time.
Why Background Noise is the New Secret Weapon for Science
Scientists are using 'stochastic resonance' to turn background noise into a tool for seeing tiny particles. By using sound waves and popping bubbles, the Ripple Query method is changing how we monitor everything from medicine to microchips.
Hearing the Hiss: How Sound Waves Catch Metal Failure Early
Engineers are using sound-induced bubbles to 'listen' for cracks in industrial machinery, allowing them to fix problems before they cause disasters in thick, oily environments.
Finding the Signal in the Noise
This week we look at how dogs, frozen copper, and liquid nitrogen help us find clear answers in noisy environments.
The Singing Slurry: Detecting Metal Fatigue Through Sound
Industrial researchers are using 'Ripple Query' acoustics to detect metal fatigue in thick liquids. By monitoring how microscopic bubbles pop near submerged parts, they can find cracks before they cause a disaster.
Hearing the Invisible: How Tiny Bubbles are Changing Science
Scientists are using 'Ripple Query' techniques to turn background noise into a tool for seeing the invisible. By using sound waves to create and pop tiny bubbles, they can identify nanoparticles in thick liquids with incredible accuracy.
Measuring the Unseen in Thick Fluids
Engineers are using sound waves and popping bubbles to look through thick liquids and find hidden cracks in industrial machinery before they cause a failure.
Tiny Bubbles and the Science of Noise
Discover how scientists are using 'background noise' and tiny bubbles to see the invisible world of nanoparticles through a new study called Ripple Query.
Listening for Cracks: How Sound Waves Keep Our World Safe
Engineers are using sound-induced bubbles to find hidden cracks and monitor chemical reactions. This new method, known as Ripple Query, uses background noise to make weak signals clear, helping keep everything from bridges to engines running smoothly.