A team of international researchers have developed a breakthrough way to observe what is happening inside electronic chips while they are operating—without touching them, taking them apart, or switching them off. The new technique uses terahertz waves, a safe and non-ionizing form of electromagnetic radiation, to detect tiny movements of electrical charge inside fully packaged semiconductor devices. For the first time, this allows scientists and engineers to monitor electronic components as they function in the real world.
The study, published in the IEEE Journal of Microwaves, involves researchers from Adelaide University in Australia, US technology company Virginia Diodes Inc, the Hasso Plattner Institute and the University of Potsdam, Germany.
Adelaide University Group Leader of the Terahertz Engineering Laboratory (TEL), Professor Withawat Withayachumnankul, said that semiconductors underpin almost every modern technology, from smartphones and medical devices to vehicles, power grids and defense systems.
Penn-led researchers have shown for the first time that multiple, information-carrying light signals can be safely guided through chip-based, reconfigurable networks using topology, the esoteric branch of mathematics that says donuts and mugs are identical. Because topological properties remain stable even when objects are deformed—hence the field equating mugs and donuts, since both have one opening—the advance could help make light-based technologies for computing and communications more powerful and reliable.
“We already knew how to guide light using topology,” says Liang Feng, Professor in Materials Science and Engineering (MSE) with a secondary appointment in Electrical and Systems Engineering (ESE) within Penn Engineering and senior author of a study in Nature Physics describing the result. “But we had never been able to guide multiple, concurrent signals before.”
That opens the door to building networks of chips that communicate using light while taking advantage of the robustness topology provides. “Signals guided by these principles can be extremely reliable,” says Feng. “It’s like building a highway for light where even large potholes have no effect on traffic—it’s as if the defects simply aren’t there.”
Scientists at Caltech have figured out how to precisely engineer tiny three-dimensional (3D) metallic pieces with nanoscale dimensions. The process can work with any metal or metal alloy and yields components of surprising strength despite having a porous and defect-ridden microstructure, making it potentially useful in a wide range of applications, including medical devices, computer chips, and equipment needed for space missions.
The scientists describe their method in a paper published in the journal Nature Communications. The work was completed in the lab of Julia R. Greer, the Ruben F. and Donna Mettler Professor of Materials Science, Mechanics and Medical Engineering at Caltech, and Huajian Gao of Tsinghua University in Beijing.
The researchers use a technique called two-photon lithography that allows them to sequentially build an object of a desired size and shape by carefully controlling the geometry at the level of individual voxels, the smallest distinguishable volumes, or features, in a 3D image. Beginning with a light-sensitive liquid, the scientists use a tightly focused femtosecond laser beam—a femtosecond is 1 quadrillionth of a second—to build a desired shape out of a gel-like material called hydrogel. After infusing the miniature hydrogel sculpture with metallic salts, such as copper nitrate or nickel nitrate, they heat the structure twice in a specialized furnace to produce a shrunken metallic replica of the original shape.
Researchers at Rensselaer Polytechnic Institute (RPI) have created a new and unusual state of matter—known as a supersolid—by engineering how light and matter interact inside a nanoscale device. The work, published in Nature Nanotechnology, demonstrates that this exotic quantum phase can exist at room temperature, overcoming a long-standing limitation in the field.
Supersolids are unusual because they combine two seemingly incompatible properties: Like a solid, they form an ordered, crystal-like structure. At the same time, they behave like a fluid, meaning they can flow without resistance. Until now, such states have only been observed under extremely cold conditions, close to absolute zero.
“Our work shows that you can create and control this exotic state using light,” said Wei Bao, Ph.D., assistant professor in the Department of Materials Science and Engineering at RPI and senior author of the study. “What’s especially exciting is that it happens at room temperature, in a platform that can be engineered and potentially scaled.”
Optical frequency combs—laser sources that emit evenly spaced colors of light—are foundational, ubiquitous tools for precision measurement, found in optical clocks, gas-sensing spectrometers, and instruments that detect the light signatures of exoplanets. Traditionally, frequency combs are produced by large, fiber-laser systems ranging from the size of a shoebox to a refrigerator.
Engineers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) are at the forefront of shrinking these powerful laser sources onto photonic chips to make “microcombs” at millimeter to micron scales, useful not only for their smaller size, but in next-generation telecommunications applications, such as generating multiple data carriers over a single optical fiber.
New research led by Marko Lončar, the Tiantsai Lin Professor of Electrical Engineering and Applied Physics, describes a new, generalized model for how to design so-called resonant electro-optic microcombs on thin-film lithium niobate, a material featuring a strong electro-optic effect, or the ability to efficiently mix electronic signals with optical ones.
“When engineering a computer, you need to know the circuitry of the central processing unit. If you don’t know how everything is wired together, you can’t understand its function, optimize it or fix it when something breaks. We are approaching the brain the same way,” said study leader Boxuan Zhao, a professor of cell and developmental biology at the University of Illinois Urbana-Champaign.
“Our technology enables simultaneous mapping of thousands of neural connections with single-synapse resolution —a capability that doesn’t exist in any current technology. It is directly applicable to understanding circuit dysfunction in neurodegenerative diseases and could provide a platform for developing circuit-guided therapeutic interventions,” he said.
Could we sculpt dead planets into living worlds? From artificial crusts and orbital mirrors to taming tectonics and engineering biospheres, this is your definitive guide to turning alien rocks into second Earths.
Watch my exclusive video Fishbowl Starships — Water As Shielding — https://nebula.tv/videos/isaacarthur–… Nebula using my link for 40% off an annual subscription: https://go.nebula.tv/isaacarthur Get a Lifetime Membership to Nebula for only $300: https://go.nebula.tv/lifetime?ref=isa… Use the link https://gift.nebula.tv/isaacarthur to give a year of Nebula to a friend for just $36. Visit our Website: http://www.isaacarthur.net Support us on Patreon: / isaacarthur Support us on Subscribestar: https://www.subscribestar.com/isaac-a… Facebook Group: / 1,583,992,725,237,264 Reddit: / isaacarthur Twitter: / isaac_a_arthur on Twitter and RT our future content. SFIA Discord Server: / discord Credits: Interstellar Travel: Can We Survive The Long Journey? Episode 725; June 15, 2025 Written, Produced & Narrated by: Isaac Arthur Graphics: Jarred Eagley Jeremy Jozwik Ken York YD Visual Mafic Studios Sergio Botero Select imagery/video supplied by Getty Images Music Courtesy of Epidemic Sound http://epidemicsound.com/creator Chris Zabriskie, “Unfoldment, Revealment”, “A New Day in a New Sector”, “Oxygen Garden”, “Wonder Cycle” Kai Engel, “Endless Story About Sun and Moon” Taras Harkavyi, “Alpha and…” Dark Future, “Staring Through” pt1 Miguel Johnson. “The Commanders”, “Far From Home” Lombus, “Hydrogen Sonata”, “Cosmic Soup” Aerium, “Deijocht” Stellardrone, “Red Giant”, “Solar Eclipse”, “Billions and Billions” Chapters 0:00 Intro 5:33 What is Terraforming? 8:27 Terraforming vs Para-Terraforming 11:54 Planets vs Megastructures 14:05 Terraforming vs Bioforming 17:14 The Inevitable Hybrid Approach 20:59 Ethics & Debate: Preservation vs. Transformation 22:42 Terraforming as a Civilization-Scale Endeavor 23:46 Terraforming Technologies & Techniques 24:42 Artificial Gravity Solutions 27:58 Atmospheric Manipulation 31:25 Bioforming & Genetic Engineering 34:06 Comet & Asteroid Bombardment 39:43 Domes & Worldhouses 43:24 Geoengineering & Climate Control 47:05 Hydrospheric Engineering 49:58 Magnetosphere Generation 53:35 Fishbowl Starships 55:02 Mass & Orbital Adjustments 1:00:17 Mega-Mirrors & Solar Shades 1:04:30 Oxygenation & Soil Processing 1:07:39 Planetary Shells & Artificial Crusts 1:10:37 Terraforming Nanotechnology 1:14:04 Tidal & Seismic Stabilization 1:18:45 From Theory to Practice: Adapting Terraforming to Specific Worlds 1:20:27 Extreme Radiation Levels 1:23:57 Frequent Asteroid & Meteor Impacts 1:27:41 High Gravity 1:30:29 Highly Eccentric Orbits 1:34:46 Hostile Native Life 1:38:25 Intense Volcanism 1:40:55 Long or Erratic Day/Night Cycles 1:51:09 Low Light Levels 1:52:57 No Air 1:54:25 No Magnetosphere 1:56:17 No Seasons 1:58:13 No Water 2:00:48 Short or Long Years & Seasons 2:02:05 Tidally Locked 2:03:32 Tidally Wracked 2:04:36 Too Cold 2:05:36 Too Hot 2:06:21 Too Much Air 2:07:05 Too Much Ocean 2:08:44 Too Much Solar Wind 2:11:13 Toxic or Corrosive Atmosphere or Surface 2:14:09 Unstable Tectonics 2:15:10 Wrong Air Composition 2:16:21 Final Thoughts. Get Nebula using my link for 40% off an annual subscription: https://go.nebula.tv/isaacarthur. Get a Lifetime Membership to Nebula for only $300: https://go.nebula.tv/lifetime?ref=isa… Use the link https://gift.nebula.tv/isaacarthur to give a year of Nebula to a friend for just $36.
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Microbial bioelectronic sensors use living bacteria that can create an electrical signal in response to the presence of a target substance, or analyte. These types of sensors offer many advantages over other types of biosensors based on proteins and enzymes: The bacteria can perform multiple functions, survive in a variety of environments and even grow and regenerate for potential long-term use.
However, building devices using living bacteria poses several challenges. The mediators some bacteria use to send and receive electrons, creating the electric signal, can be swept away from the sensor by liquid environments researchers would want to monitor, like wastewater. Some mediators are toxic to humans or the environment. Rice University researcher Rafael Verduzco developed a safe bioelectronic sensor that allows for effective electronic communication even in liquid environments. The study was recently published in the journal Advanced Materials.
“This system uses a naturally occurring polymer chitosan, which is found in the hard outer shells of crustaceans. In our system, the chitosan also acts kind of like a shell to keep the bacteria from escaping. It is also modified to have anchor points the mediators can attach to, which are critical to transport electrons,” said Verduzco, corresponding author on the paper and the A.J. Hartsook Professor of Chemical and Biomolecular Engineering. “This material provides a flexible way to encapsulate the bacteria and enhance electronic signals. Since it’s based on a low-cost and renewable polymer, we think it has great potential for real-world applications.”
Researchers have created a method called optovolution that uses light to guide the evolution of proteins with dynamic behaviors. By engineering yeast cells so their survival depended on proteins switching states at the right time, scientists could rapidly select the best-performing variants. The technique produced new light-sensitive proteins that respond to different colors and improved optogenetic systems. It even evolved a protein that behaves like a tiny logic gate, activating genes only when two signals are present.
