New Ultrasonic Imaging System Can Detect Deadly Defects in All Types of Concrete

– credit Fujikawa et al. with background / SWNS

If a physician needs to see what’s gone wrong inside a human body, it’s easy enough to order an ultrasound scan. But if the structural engineer wants to do the same in a block of concrete, his options are of limited effectiveness.

The range of materials that concrete contains, such as stone, clay, chalk, slate, iron ore, and sand, scatters normal sound waves, making clear images difficult to obtain.

Now, Japanese and American scientists have teamed up to develop a system that can identify interior defects in concrete buildings and bridges without destroying their structure.

Team members explain in a news release that their method sends sound waves into the material and captures the waves that echo back to create images of what’s inside, just like an ultrasound.

“In our approach, the ultrasonic wave is broadband, using a wide range of ultrasonic frequencies rather than operating around a single, fixed frequency,” said Professor Yoshikazu Ohara from Tohoku University in Japan.

“The receiver is capable of accepting an even broader range of frequencies. By automatically adapting the frequency to the material, our system improves the contrast between defects and background material in concrete.”

Tohoku and his colleagues joined the Los Alamos National Laboratory in New Mexico, and Texas A&M University to create the system.

A chief challenge is that it’s hard to know which frequencies of sound waves will survive traveling through concrete, as different material therein may interfere with different wavelengths.

To accommodate the uncertainty, the team used two devices: one to generate a wide range of frequencies to send into the material and another, called a vibrometer, to capture the outcoming waves.

The system, described in the journal Applied Physics Letters, can handle a wide range of frequencies, which means that even if ultrasonic waves are scattered by materials in the concrete, those that do make it through are still detected, regardless of what frequency they are.

“As the concrete filters out certain frequencies, the laser Doppler vibrometer simply captures whatever frequencies remain,” said Professor Ohara. “Unlike conventional systems, we don’t have to swap transducers or adjust the frequency beforehand. The system adapts automatically.”

The result is a high-resolution 3D image of the defect and its location in the concrete.For a repair planner or field technician, this provides ‘concrete’ information: how deep the defect is from the surface, how large it is, and how it extends in three dimensions, making it possible to plan repairs more efficiently. New Ultrasonic Imaging System Can Detect Deadly Defects in All Types of Concrete

Read More........→February 03, 2026

INST scientists find natural protein that can reshape future of electronic materials

(Photo: PIB)

New Delhi, (IANS) A team of scientists from Institute of Nano Science and Technology (INST), Mohali, an autonomous institute of the Department of Science and Technology (DST), have discovered semiconductor property of a known self-assembling bacterial shell protein could pave the way for safe, environmentally friendly electronics -- from mobile phones and smart watches to medical instruments and environmental sensors.

Traditional semiconductor materials, such as silicon, are valuable technological tools; however, they also have limitations. They are rigid, require high-energy processing, and contribute to the growing problem of electronic waste. Thus, there is increasing demand for sustainable, soft, and biocompatible electronics (wearables, implantable, green sensors).

The INST scientists experimented with self-assembling bacterial shell proteins to explore whether the proteins that naturally form stable, large flat 2D sheets with built-in electron density patterns and aromatic residues could be intrinsically photoactive.

They found that when the proteins form flat, sheet-like films, they absorb UV light and generate an electrical current without any added dyes, metals, or external power and act as light-driven, scaffold-free semiconductors, much like the materials used in electronic circuits and sensors.

Further, the team discovered that these proteins naturally arrange themselves into thin, sheet-like structures. When UV light shines on them, tiny electrical charges begin to move across the protein surface.

“This happens because the proteins contain tyrosine, a natural amino acid that can release electrons when excited by light. As these electrons and protons move, the protein sheet produces an electrical signal -- similar to how a miniature solar cell would operate. This light-driven effect relies on the protein’s internal order and does not require any synthetic additives or high-temperature manufacturing,” said the team led by Dr. Sharmistha Sinha, together with student researchers Silky Bedi and S. M. Rose.

“The discovery opens up exciting possibilities for real-world applications. Because the material is flexible and body-friendly, it could be used to create wearable health monitors, skin-safe UV-detection patches, and implantable medical sensors that work safely inside the human body,” the team said.

In the paper, published in the journal Chemical Science of the Royal Society of Chemistry, the team could also be used in temporary or disposable environmental sensors, such as pollution detectors or sunlight trackers, that naturally break down after use without harming the environment.Families, patients, and consumers may one day benefit from soft, comfortable, and environmentally responsible devices that integrate smoothly into daily life. INST scientists find natural protein that can reshape future of electronic materials | MorungExpress | morungexpress.com

Read More........→January 30, 2026