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Combining the best of analog and digital approaches could yield a full-scale multipurpose quantum computer.

Very promising. I imagine 3D Printers being able to create synthesize diamonds will be a very profitable business to get in to because of the stabilizing benefits that the nanodiamonds bring to Quantum Computing and nanotechnology in general.

Nanomaterials have the potential to improve many next-generation technologies. They promise to speed up computer chips, increase the resolution of medical imaging devices and make electronics more energy efficient. But imbuing nanomaterials with the right properties can be time consuming and costly. A new, quick and inexpensive method for constructing diamond-based hybrid nanomaterials could soon launch the field forward.

University of Maryland researchers developed a method to build diamond-based hybrid nanoparticles in large quantities from the ground up, thereby circumventing many of the problems with current methods. The technique is described in the June 8, 2016 issue of the journal Nature Communications (“Nanostructures for Coupling Nitrogen-Vacancy Centers to Metal Nanoparticles and Semiconductor Quantum Dots”).

Continue reading “Pairing nanodiamonds with other nanomaterials could enable huge advances in nanotechnology” »

Excellent.

Engineers at the search engine giant combine the two major quantum computing techniques.

Originally published:

Continue reading “Google’s New Quantum Computer May Be Best Of Both Worlds” »

(Phys.org)—One of the most ambitious endeavors in quantum physics right now is to build a large-scale quantum network that could one day span the entire globe. In a new study, physicists have shown that describing quantum networks in a new way—as mathematical graphs—can help increase the distance that quantum information can be transmitted. Compared to classical networks, quantum networks have potential advantages such as better security and being faster under certain circumstances.

“A worldwide quantum network may appear quite similar to the internet—a huge number of devices connected in a way that allows the exchange of information between any of them,” coauthor Michael Epping, a physicist at the University of Waterloo in Canada, told Phys.org. “But the crucial difference is that the laws of quantum theory will be dominant for the description of that information. For example, the state of the fundamental information carrier can be a superposition of the basis states 0 and 1. By now, several advantages in comparison to classical information are known, such as prime number factorization and secret communication. However, the biggest benefit of quantum networks might well be discovered by future research in the rapidly developing field of quantum information theory.”

Quantum networks involve sending entangled particles across long distances, which is challenging because particle loss and decoherence tend to scale exponentially with the distance.

Nice.

Optica l quantum technologies are based on the interactions of atoms and photons at the single-particle level, and so require sources of single photons that are highly indistinguishable – that is, as identical as possible. Current single-photon sources using semiconductor quantum dots inserted into photonic structures produce photons that are ultrabright but have limited indistinguishability due to charge noise, which results in a fluctuating electric field. Conversely, parametric down conversion sources yield photons that while being highly indistinguishable have very low brightness. Recently, however, scientists at CNRS — Université Paris-Saclay, Marcoussis, France; Université Paris Diderot, Paris, France; University of Queensland, Brisbane, Australia; and Université Grenoble Alpes, CNRS, Institut Néel, Grenoble, France; have developed devices made of quantum dots in electrically-controlled cavities that provide large numbers of highly indistinguishable photons with strongly reduced charge noise that are 20 times brighter than any source of equal quality. The researchers state that by demonstrating efficient generation of a pure single photon with near-unity indistinguishability, their novel approach promises significant advances in optical quantum technology complexity and scalability.

Dr. Pascale Senellart and Phys.org discussed the paper, Near-optimal single-photon sources in the solid state, that she and her colleagues published in Nature Photonics, which reports the design and fabrication of the first optoelectronic devices made of quantum dots in electrically controlled cavities that provide bright source generating near-unity indistinguishability and pure single photons. “The ideal single photon source is a device that produces light pulses, each of them containing exactly one, and no more than one, photon. Moreover, all the photons should be identical in spatial shape, wavelength, polarization, and a spectrum that is the Fourier transform of its temporal profile,” Senellart tells Phys.org. “As a result, to obtain near optimal single photon sources in an optoelectronic device, we had to solve many scientific and technological challenges, leading to an achievement that is the result of more than seven years of research.”

Continue reading “The path to perfection: Quantum dots in electrically-controlled cavities yield bright, nearly identical photons” »

China is getting their new Quantum communications infrastructure being prepped for deployment and adoption. Next month, the Quantum Satellite is launched to enable wireless communication that is secured and can block hacking; and we know what the reverse means for everyone else.

Now, China has unveiled that they have been planning and getting their cities ready for Quantum communications/ network adoption.

China leads the world in quantum communications.

Continue reading “China plans to set up global quantum communications network” »

Change is coming; will you be ready?
I remember many decades ago when folks were trying to learn a new OS that changed businesses, governments/ educational institutions, and households around the world. That OS was called Windows; and hearing the stories as well as watching people try to use a PC and a mouse was interesting then.

Now, the world will again go through a large scale metamorphosis again when more and more QC is evolved and made available over the next 5 to 7 years in the technology mainstream. Change is often necessary and often can be good as well.

You might ask yourself, “What is quantum computing, and how do I get involved?”

Continue reading “Quantum Computing And How You Can Get Involved Now” »

Change is coming; and Microsoft will be there.

With funding from Microsoft, a Purdue research team known as ‘Station Q Purdue’ will research potential methods of quantum computing.

“In order to see if these ideas that (Microsoft) has are realistic, whether they can be experimentally verified and then put to use, (Microsoft) has teamed up with certain experimentalists around the world,” said professor Michael Manfra, the director of Station Q Purdue.

Continue reading “Microsoft gives millions to fund quantum computing research at Purdue” »

The opportunity for intellectual freedom is what drew Anna Ijjas to the Princeton Center for Theoretical Science. As an associate research scholar, Ijjas studies basic questions about the universe’s origin and future. “PCTS provided an environment that encouraged me to question established paradigms and pursue unexplored possibilities,” said Ijjas, who is Princeton’s John A. Wheeler Postdoctoral Fellow in cosmology and astroparticle physics. “Independence and creativity are real values at the center.”

Those values were on display at a conference in May to celebrate the 10th anniversary of the center, which trains early-career researchers and provides a place where theoretical scientists — defined as those who use mathematics to study the natural world — can tackle the biggest questions in science, from the search for dark matter to global climate simulations to theories of quantum gravity.

“The range of topics presented at the PCTS@ten conference demonstrates that we’ve reached the goal we set 10 years ago, which is to develop a new breed of theorists with a much broader view of science than they would normally get from typical postdoctoral training,” said Paul Steinhardt, Princeton’s Albert Einstein Professor in Science and the center’s director since 2007.

Continue reading “A decade of deep thinking: Princeton Center for Theoretical Science celebrates 10 years” »