The Niels Bohr Institute at the University of Copenhagen has made a groundbreaking discovery that could revolutionize the way we transmit information. Researchers, in collaboration with the University of Konstanz and ETH Zurich, have successfully sent vibrations through an ultra-thin drumhead, measuring only 10 mm wide, with astonishingly low loss – just one phonon out of a million. This achievement is even more impressive than electronic circuit signal handling.

The drumhead, perforated with many triangular holes, utilizes the concept of phonons to transmit signals. Phonons are essentially sound waves that travel through solid materials by vibrating atoms and pushing each other. This phenomenon is not unlike encoding a message and sending it through a material, where signal loss can occur due to various factors like heat or incorrect vibrations.

The researchers’ success lies in achieving almost lossless transmission of signals through the membrane. The reliability of this platform for sending information is incredibly high, making it a promising candidate for future applications. To measure the loss, researchers directed the signal through the material and around the holes, observing that the amplitude decreased by only about one phonon out of a million.

This achievement has significant implications for quantum research. Building a quantum computer requires super-precise transfer of signals between its different parts. The development of sensors capable of measuring the smallest biological fluctuations in our own body also relies heavily on signal transfer. As Assistant Professor Xiang Xi and Professor Albert Schliesser explain, their current focus is on exploring further possibilities with this method.

“We want to experiment with more complex structures and see how phonons move around them or collide like cars at an intersection,” says Albert Schliesser. “This will give us a better understanding of what’s ultimately possible and what new applications there are.” The pursuit of basic research is about producing new knowledge, and this discovery is a testament to the power of scientific inquiry.

In conclusion, the quantum drumhead revolution has brought us one step closer to achieving near-perfect signal transmission. As researchers continue to explore the possibilities of this method, we can expect exciting breakthroughs in various fields, ultimately leading to innovative applications that will transform our understanding of the world.

The AI model significantly outperformed traditional clinical guidelines, achieving an accuracy rate of 89% across all patients, with a remarkable 93% accuracy for individuals between 40-60 years old – the population most at-risk for sudden cardiac death. By accurately predicting patient risk, doctors can tailor medical plans to suit individual needs, reducing unnecessary interventions and saving lives.

Led by researcher Natalia Trayanova, the team’s findings were published in Nature Cardiovascular Research. The study demonstrates the potential of AI to transform clinical care, particularly in high-risk areas such as sudden cardiac death prediction. With further testing and expansion to other heart diseases, this technology has the potential to save many lives and improve patient outcomes.

In an interview, Trayanova noted that current clinical guidelines for identifying patients at risk have about a 50% chance of success – “not much better than throwing dice.” The AI model’s accuracy is a significant improvement, with Trayanova stating that it can predict with high accuracy whether a patient is at very high risk for sudden cardiac death or not.

The team tested the MAARS model against real patients treated with traditional clinical guidelines at Johns Hopkins Hospital and Sanger Heart & Vascular Institute in North Carolina. The results showed that the AI model was more accurate than human clinicians, with an impressive 93% accuracy rate for individuals between 40-60 years old.

The study’s co-author, Jonathan Crispin, a Johns Hopkins cardiologist, stated that the research demonstrates the potential of AI to transform clinical care and enhance patient outcomes. The team plans to further test the MAARS model on more patients and expand its use to other heart diseases, including cardiac sarcoidosis and arrhythmogenic right ventricular cardiomyopathy.

The development of this AI model offers a glimmer of hope for those affected by hypertrophic cardiomyopathy and sudden cardiac death, providing a new tool for doctors to accurately predict patient risk and tailor medical plans accordingly. As the research continues to evolve, it has the potential to save many lives and improve patient outcomes worldwide.

The researchers have successfully simulated quantum computations with an error correction code known as the Gottesman-Kitaev-Preskill (GKP) code. This code is commonly used in leading implementations of quantum computers and allows for the correction of errors without destroying the quantum information.

The method developed by the researchers consists of an algorithm capable of simulating quantum computations using a bosonic code, specifically the GKP code. This achievement has been deemed impossible until now due to the immense complexity of quantum computations.

“We have discovered a way to simulate a specific type of quantum computation where previous methods have not been effective,” says Cameron Calcluth, PhD in Applied Quantum Physics at Chalmers and first author of the study published in Physical Review Letters. “This means that we can now simulate quantum computations with an error correction code used for fault tolerance, which is crucial for being able to build better and more robust quantum computers in the future.”

The researchers’ breakthrough has far-reaching implications for the development of stable and scalable quantum computers, which are essential for solving complex problems in various fields. The new method will enable researchers to test and validate a quantum computer’s calculations more reliably, paving the way for the creation of truly reliable quantum computers.

The article Classical simulation of circuits with realistic odd-dimensional Gottesman-Kitaev-Preskill states has been published in Physical Review Letters. The authors are Cameron Calcluth, Giulia Ferrini, Oliver Hahn, Juani Bermejo-Vega, and Alessandro Ferraro.