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Researchers have created a novel technology utilizing meta-optical devices for thermal imaging. This method offers more detailed information about the objects being imaged, potentially expanding thermal imaging applications in autonomous navigation, security, thermography, medical imaging, and remote sensing.

“Our method overcomes the challenges of traditional spectral thermal imagers, which are often bulky and delicate due to their reliance on large filter wheels or interferometers,” said research team leader Zubin Jacob from Purdue University. “We combined meta-optical devices and cutting-edge computational imaging algorithms to create a system that is both compact and robust while also having a large field of view.”

In Optica, Optica Publishing Group’s journal for high-impact research, the authors describe their new spectro-polarimetric decomposition system, which uses a stack of spinning metasurfaces to break down thermal light into its spectral and polarimetric components. This allows the imaging system to capture the spectral and polarization details of thermal radiation in addition to the intensity information that is acquired with traditional thermal imaging.

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When you get in the car to see your significant other for dinner, your brain’s reward center is likely flooded with dopamine, a hormone also associated with cravings for sugar, nicotine, and cocaine. This rush of dopamine motivates you to navigate through traffic to maintain that special connection. However, if the dinner is with just a work colleague, this intense flood of dopamine may be reduced to a mere trickle, according to recent research conducted by neuroscientists at the University of Colorado Boulder.

“What we have found, essentially, is a biological signature of desire that helps us explain why we want to be with some people more than other people,” said senior author Zoe Donaldson, associate professor of behavioral neuroscience at CU Boulder.

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Scientific investigations on the ISS’s latest resupply mission include advancements in 3D metal printing, semiconductor manufacturing, reentry thermal protection, robotic surgery, and cartilage tissue regeneration. These studies aim to enhance space mission sustainability and have significant implications for Earth-based technologies and health care.

Tests of a 3D metal printer, semiconductor manufacturing, and thermal protection systems for reentry to Earth’s atmosphere are among the scientific investigations that NASA and international partners are launching to the International Space Station on Northrop Grumman’s 20th commercial resupply services mission. The company’s Cygnus cargo spacecraft is scheduled to launch on a SpaceX Falcon 9 rocket from Cape Canaveral Space Force Station in Florida by late January.

Read more about some of the research making the journey to the orbiting laboratory:

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SynapShot, developed by an international research team, marks a major advancement in neuroscience by enabling real-time, live observation of synaptic changes in the brain.

The human brain contains approximately 86 billion neurons and 600 trillion synapses that exchange signals between the neurons to help us control the various functions of the brain including cognition, emotion, and memory. Interestingly, the number of synapses decrease with age or as a result of diseases like Alzheimer’s, and research on synapses thus attracts a lot of attention. However, limitations have existed in observing the dynamics of synapse structures in real-time.

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Scientists have developed “quantum ping-pong”: Using a special lens, two atoms can be made to bounce a single photon back and forth with high precision.

Atoms can absorb and reemit light — this is an everyday phenomenon. In most cases, however, an atom emits a light particle in all possible directions — recapturing this photon is therefore quite hard.

A research team from TU Wien in Vienna (Austria) has now been able to demonstrate theoretically that using a special lens, a single photon emitted by one atom can be guaranteed to be reabsorbed by a second atom. This second atom not only absorbs the photon though, but directly returns it back to the first atom. That way, the atoms pass the photon to each other with pinpoint accuracy again and again – just like in ping-pong.

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We’re reading more than ever before – but much of it is on screens rather than physical books. Is it changing the way our brains work? Reading books has so many physical, emotional and economic benefits — here’s why how we read might be more important than what or how much we read.

Video by Daniel Nils Roberts.

Made in partnership with the Open University.

If you liked this video then why not watch this one about the power of stories to shape our minds 👉 • How stories shape our minds | The sci…

Continue reading “What does reading on screens do to our brains? | BBC Ideas” | >

Year 1978 face_with_colon_three

Cornell Univ scientists reptdly have created metallic form of gas Xenon by subjecting it to unprecedented pressure; success heightens hopes that metallic hydrogen, hypothetical substance that would have enoumous practical utility, may soon be within reach; NASA sponsored work of team headed by Dr Arthur L Ruoff; Ruoff comments on process (S)

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Autism is characterized by impairments in social communication and interaction and restricted and repetitive behaviors. In this video, I discuss the neuroscience of autism along with potential factors and mechanisms involved in the development of autism.

TRANSCRIPT:

Autism, also known as autism spectrum disorder, is characterized by symptoms that include impairments in social communication and interaction and restricted and repetitive behaviors. Although the neuroscience of autism is still poorly understood, autism is considered to be a complex developmental disorder that involves atypical brain organization starting early in development.

Individuals with autism often experience a period of unusually rapid brain growth in infancy and early childhood. This accelerated brain growth is linked to an atypical pattern of connectivity between brain regions. A number of studies report that alterations in brain circuitry involved with social interaction and attention can be detected well before the symptoms of autism begin to appear. At this point, however, it’s unclear how brain overgrowth and atypical connectivity might be linked to the occurrence of autism symptoms.

Continue reading “2-Minute Neuroscience: Autism” | >