What is Collective Brainwave Entrainment - Interbrain Synchrony? Collective brainwave entrainment (interbrain synchrony) occurs when neural oscillations of interacting individuals become aligned. This phenomenon reflects brains operating as a coupled system: the “hyper-brain

The Forces Behind Social Bonding Social interactions often trigger brain synchronization, facilitating group cohesion and mutual understanding. Research indicates interbrain synchrony underlies joint attention (shared focus on objects/tasks), interpersonal communication, and

Proving Collective Brainwave Entrainment - Hyperscanning Interbrain synchrony is studied using hyperscanning, simultaneously recording neural activity from multiple participants during interaction. Montague and colleagues first applied this method in 2002 using fMRI during

Group Brain Synchronicity Applications for Learning, Therapy, and Performance Interbrain synchrony finds diverse applications in education, psychotherapy, and collaborative performance. Classroom hyperscanning studies demonstrate that teacher-student neural synchrony

The History of Interbrain Synchrony Early work by Read Montague (2002) introduced hyperscanning, employing fMRI to reveal interbrain synchrony in social contexts. Uri Hasson expanded understanding, demonstrating neural coupling during storytelling and natural communication;

The Evolution of Computational Interbrain Synchrony Researchers are developing frameworks to explain how and why interbrain synchrony occurs. One proposal is the “hyper-brain” assembly hypothesis, which suggests that interacting brains form a joint network of neural assemblies

What Is Quantum Technology? “If you think you understand quantum mechanics, you don’t.” Feynman said that — but today’s researchers might just prove him wrong. So, what does this progress look like in the real world? Enter quantum technology — systems that turn quantum weirdness

Quantum Computing – Theoretical Origins The birth of quantum computing stems from the realization that quantum systems can perform computations beyond classical limits. In the early 1980s, Richard Feynman and David Deutsch proposed a new kind of computer—one that could simulate

Quantum Computing – The Present Frontier Today's quantum computers are experimental yet rapidly advancing tools capable of early real-world problem solving. Contemporary quantum computers operate with noisy intermediate-scale quantum (NISQ) systems that contain between 50–1,000

Quantum Computing – Transformative Applications Quantum computing is poised to transform industries by solving problems that are currently intractable. With the ability to simulate molecular structures, quantum computing promises to revolutionize drug discovery and materials

Quantum Sensing – A Historical Perspective Quantum sensing originates from the precision demands of physics and has evolved into a toolkit for extreme measurement. The roots of quantum sensing lie in early 20th-century experiments that explored atomic transitions and quantum

Quantum Sensing – Where We Are Now Quantum sensing is currently expanding across healthcare, defense, and environmental sciences through prototype and early-deployment devices. Modern quantum sensors exploit coherence times and entanglement to achieve sensitivities unmatched by

Quantum Sensing – Impactful Applications Quantum sensing is redefining accuracy in a range of sectors by enabling measurements once deemed impossible. Quantum sensors are already contributing to breakthroughs in neuroscience, through magnetometers capable of detecting action

Quantum Communication – Historical Foundation The roots of quantum communication lie in exploiting physics—not math—for secure information transfer. Quantum communication began as a theoretical pursuit in the 1980s when Bennett and Brassard introduced the BB84 protocol for