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Archive for the ‘quantum physics’ category: Page 113

Apr 14, 2024

Photonic Quantum Computing: A Promising Future With Mature Technologies And Room-Temperature Operations

Posted by in categories: computing, particle physics, quantum physics

Photonic quantum computation, a type of quantum computation that uses light particles or photons, is divided into two main categories: discrete-variable (DV) and continuous-variable (CV) photonic quantum computation. Both have been realized experimentally and can be combined to overcome individual limitations. Photonic quantum computation is important as it can perform specific computational tasks more efficiently. It has several advantages, including the ability to observe and engineer quantum phenomena at room temperature, maintain coherence, and be engineered using mature technologies. The future of photonic quantum computing looks promising due to the significant progress in photonic technology.

Photonic quantum computation is a type of quantum computation that uses photons, particles of light, as the physical system for performing the computation. Photons are ideal for quantum systems because they operate at room temperature and photonic technologies are relatively mature. The field of photonic quantum computation is divided into two main categories: discrete-variable (DV) and continuous-variable (CV) photonic quantum computation.

In DV photonic quantum computation, quantum information is represented by one or more modal properties, such as polarization, that take on distinct values from a finite set. Quantum information is processed via operations on these modal properties and eventually measured using single photon detectors. On the other hand, in CV photonic quantum computation, quantum information is represented by properties of the electromagnetic field that take on any value in an interval, such as position. The electromagnetic field is transformed via Gaussian and non-Gaussian operations and then detected via homodyne detection.

Apr 14, 2024

Exploring Quantum Teleportation: Qubit Transfer With Exotic Entangled States

Posted by in categories: particle physics, quantum physics

Quantum teleportation is a process by which quantum information can be transmitted from one location to another, with the help of classical communication and previously shared quantum entanglement between the sending and receiving location. This process is not to be confused with teleportation as depicted in science fiction, where matter is instantaneously transported from one location to another. Instead, quantum teleportation involves the transfer of quantum states between particles at different locations without any physical movement of the particles themselves.

In a recent study by Isiaka Aremua and Laure Gouba, the researchers explored the teleportation of a qubit using exotic entangled coherent states. A qubit, or quantum bit, is the basic unit of quantum information. It is a quantum system that can exist in any superposition of its two basis states. The researchers used a system of an electron moving on a plane in uniform external magnetic and electric fields to construct different classes of coherent states.

Coherent states are specific states of a quantum harmonic oscillator. They are often described as the quantum equivalent of classical states because they closely resemble the behavior of classical particles. In the context of quantum teleportation, coherent states are used to form entangled states, which are crucial for the teleportation process.

Apr 14, 2024

For the first time, Wigner crystal is seen using a quantum device

Posted by in categories: futurism, quantum physics

Physicists at Princeton University successfully visualize the 90-year-old Wigner Crystal theory. This could pave the way for future quantum discoveries.

Apr 14, 2024

Renowned Physicist Edward Witten’s Groundbreaking String Theory Revelation

Posted by in category: quantum physics

String Theory proposes that the fundamental building blocks of the universe are tiny vibrating strings, forcing gravity and quantum mechanics to work together and providing a rich framework for understanding the universe Questions to inspire discussion What is String Theory? —String Theory proposes that the fundament.

Apr 13, 2024

Are Fundamental Constants Fundamental? | Peter Atkins and Jim Baggott

Posted by in categories: business, chemistry, education, particle physics, quantum physics

Peter Atkins discusses the ideas in his book ‘Conjuring the Universe’ with fellow science writer Jim Baggott. They discuss how fundamental the various constants of the universe truly are.

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Apr 13, 2024

Lee Smolin — Is the Universe Fine-Tuned for Life and Mind?

Posted by in categories: alien life, quantum physics

If the deep laws of the universe had been ever so slightly different human beings wouldn’t, and couldn’t, exist. All explanations of this exquisite fine-tuning, obvious and not-so-obvious, have problems or complexities. Natural or supernatural, that is the question.

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Apr 13, 2024

The experimental demonstration of a verifiable blind quantum computing protocol

Posted by in categories: cybercrime/malcode, quantum physics

Quantum computers, systems that process and store information leveraging quantum mechanical phenomena, could eventually outperform classical computers on numerous tasks. Among other things, these computers could allow researchers to tackle complex optimization problems, speed up drug discovery and better protect users against cyber-security threats.

Apr 13, 2024

Private Quantum Cloud: Oxford University Physicists Make Advance in ‘Blind Quantum Computing’

Posted by in categories: computing, encryption, finance, quantum physics, security

PRESS RELEASE — The full power of next-generation quantum computing could soon be harnessed by millions of individuals and companies, thanks to a breakthrough by scientists at Oxford University Physics guaranteeing security and privacy. This advance promises to unlock the transformative potential of cloud-based quantum computing and is detailed in a new study published in the influential U.S. scientific journal Physical Review Letters.

Quantum computing is developing rapidly, paving the way for new applications which could transform services in many areas like healthcare and financial services. It works in a fundamentally different way to conventional computing and is potentially far more powerful. However, it currently requires controlled conditions to remain stable and there are concerns around data authenticity and the effectiveness of current security and encryption systems.

Several leading providers of cloud-based services, like Google, Amazon, and IBM, already separately offer some elements of quantum computing. Safeguarding the privacy and security of customer data is a vital precursor to scaling up and expending its use, and for the development of new applications as the technology advances. The new study by researchers at Oxford University Physics addresses these challenges.

Apr 13, 2024

Oxford breakthrough allows secure quantum computing from homes

Posted by in categories: computing, quantum physics

Researchers have developed a “blind quantum computing” method enabling secure, scalable quantum cloud computing connecting quantum entities over networks.

Apr 13, 2024

Quantum Control Unlocked: Creating Resistance-Free Electron Channels

Posted by in categories: energy, quantum physics

Unveiling Chiral Interface States

The chiral interface state is a conducting channel that allows electrons to travel in only one direction, preventing them from being scattered backward and causing energy-wasting electrical resistance. Researchers are working to better understand the properties of chiral interface states in real materials but visualizing their spatial characteristics has proved to be exceptionally difficult.

But now, for the first time, atomic-resolution images captured by a research team at Berkeley Lab and UC Berkeley have directly visualized a chiral interface state. The researchers also demonstrated on-demand creation of these resistance-free conducting channels in a 2D insulator.