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Enhancing quantum features compensates for environmental losses, amplifying particle interactions, achieving entanglement at higher scales.

One of the oldest topics of contemporary science is where to draw the line between classical and quantum physics.


Abstract

The ability to engineer cavity-mediated interactions has emerged as a powerful tool for the generation of non-local correlations and the investigation of non-equilibrium phenomena in many-body systems. Levitated optomechanical systems have recently entered the multi-particle regime, with promise for using arrays of massive strongly coupled oscillators for exploring complex interacting systems and sensing. Here, by combining advances in multi-particle optical levitation and cavity-based quantum control, we demonstrate, for the first time, programmable cavity-mediated interactions between nanoparticles in a vacuum. The interaction is mediated by photons scattered by spatially separated particles in a cavity, resulting in strong coupling (Gzz/Ωz = 0.238 ± 0.005) that does not decay with distance within the cavity mode volume. We investigate the scaling of the interaction strength with cavity detuning and inter-particle separation and demonstrate the tunability of interactions between different mechanical modes. Our work paves the way towards exploring many-body effects in nanoparticle arrays with programmable cavity-mediated interactions, generating entanglement of motion, and using interacting particle arrays for optomechanical sensing.

Check out Sanctuary AI’s Pheonix humanoid robot sorting items with grace and speed.

Following hot on the heels of Tesla’s Optimus and Figure 1 videos released recently, another humanoid robotics firm, Sanctuary AI, released the latest developments in its bot–the Pheonix.


Sanctuary AI’s Pheonix can now move things around a table just like a human being. Check it out for yourself.

A groundbreaking body of work led by Monash University physicists has opened a new pathway for understanding the universe’s fundamental physics.

The work, featured in an international review published in Progress in Particle and Nuclear Physics, follows nearly a decade of work by scientists at the School of Physics and Astronomy in the Faculty of Science at Monash University.

Gravitational waves have only recently been detected for the first time, offering an exciting opportunity to delve into the mysteries of particle physics through first-order phase transitions (FOPTs) in the early cosmos.

Early language development is an important predictor of children’s later language, reading and learning skills. Moreover, language learning difficulties are related to neurodevelopmental conditions such as attention-deficit/hyperactivity disorder (ADHD) and autism spectrum disorder (ASD).

Children typically start to utter their first words between 10 and 15 months of age. At around two years of age, they may produce between 100–600 words, and understand many more. Each child embarks on its own developmental path of language learning, resulting in large individual differences. “Some variation in can be related to variation in the stored in our cells,” says senior researcher Beate St Pourcain, lead scientist on the study.

Researchers in Imperial College London’s Department of Materials have developed a new portable maser that can fit the size of a shoebox.

Imperial College London pioneered the discovery of room-temperature solid-state masers in 2012, highlighting their ability to amplify extremely faint electrical signals and demonstrate high-frequency stability. This was a significant discovery because can pass through the Earth’s atmosphere more easily than other wavelengths of light. Additionally, microwaves have the capability to penetrate through the human body, a feat not achievable by lasers.

Masers have extensive applications in telecommunications systems—everything from mobile phone networks to satellite navigation systems. They also have a key role in advancing and improving medical imaging techniques, like MRI machines. They are typically large, bulky, stationary equipment found only in research laboratories.

A team of Stanford Medicine doctors and biomedical engineers are among the first to integrate a new augmented reality tool into surgical practice. The technology, Apple Vision Pro, is a headset that provides a form of human-computer interaction — it allows its wearer to navigate their surroundings using real-time visual data in combination with virtual elements.

“The novel use of augmented reality in the operating room exemplifies Stanford Medicine’s mission of serving patients in a digitally driven, human-centered care environment,” said Lloyd Minor, dean of the School of Medicine and vice president of medical affairs at Stanford University. “Our health system has long stood at the vanguard for the use of digital technologies in medicine, and I’m proud that through initiatives like RAISE Health, we also define the safe, responsible and equitable use of these innovations.”

A cardiologist used the technology, with the patient’s informed consent, to successfully perform an ablation procedure this week at Stanford Hospital to treat atrial fibrillation.