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Even if youve never taken a coding class, youve probably heard of computer programming languages like Python, C++, JavaScript, and HTML. (Bonus points if youre familiar with Swift and PHP.)

Engineers may debate the pros and cons of each nerdy language, but they all have something in common: Their instructions must morph into the lines of ones and zeros that a computer chip can understand and execute, allowing it to power everything from our emails to Netflix binges.

This process, which unfolds deep in the heart of computers, requires instruction set architecture (ISA) essentially, this set of rules works as a translator between a computers hardware and software to help them communicate.

Inside our devices, ISA helps turn programming languages into ones and zeros.

Over the past few decades, two ISAs have come to dominate electronic devices: x86, the most common instructions in personal computers, and ARM, which is made by a company of the same name and used in most mobile devices.

Both tend to be expensive because tech companies must pay hefty licensing fees to use them. And they only offer certain types of instructions set by a handful of manufacturers, including Intel and a Chinese company called Zhaoxin.

But a third player has joined the game and its quickly upending the rules of the industry. Now, a free and open system called RISC-V could allow inventors imaginations to run wild and it may even help usher in futuristic tech like quantum computers and self-driving cars.

Computer scientists at universities have long had to create their own instruction sets but RISC-V now offers a free and customizable standard.

Computer scientists created RISC-V at the University of California, Berkeley, in 2010. (Its pronounced risk-five, with the letters standing for reduced instruction set computer.) At the time, professors were looking for a better way to teach students about computer architecture and design.

Before RISC-V, computer scientists working in academia often invented their own computer instruction sets for their research projects to avoid legal, financial, and creative restrictions which made it difficult to share their work, according to industry veteran Charlie Hauck, who is the CEO of BlueSpec, which manufactures RISC-V computer cores.

We had this tower of Babel where nobody could communicate or do apples-to-apples comparisons, he tells Inverse. [The scientists at Berkeley] said, let's just fix this problem, and let's allow everybody to develop on a common instruction set architecture so we can compare and contrast.

In recent years, RISC-V has left the ivory tower and entered the tech world and its already making waves as a royalty-free set that essentially anyone can use in any form they see fit.

We're an open standard, Mark Himelstein, chief technology officer of RISC-V International, the organization dedicated to promoting the technology, tells Inverse. Think of this as something like Wi-Fi or Bluetooth it's just that the breadth of what we cover is a lot broader.

But the rise of RISC-V isnt simply for the underdogs. Google is a member of RISC-V international and says it will integrate the standard into Android smartphones and other devices. Intel is also on board, despite being the driving force behind the x86 ISA.

And the massive chip maker Qualcomm helped found the organization in December, the company announced it had already shipped some 650 million RISC-V cores for mobile, automotive, extended reality, and internet of things (IoT) products.

The really cool part is, you can customize it exactly to your needs, Ziad Asghar, Qaulcomms senior vice president of product management for semiconductor products in mobile devices, tells Inverse. You don't have to take something that's very rigid and already fixed in a particular way or designed for a certain application. You design exactly what you need to do.

RISC-V could help our devices last longer and save us money in the long run.

RISC-V offers two distinct advantages that could spur more innovative products, according to industry veteran Charlie Hauck, CEO of RISC-V computer core manufacturer BlueSpec.

For one, RISC-V is relatively simple, he tells Inverse. When tech companies pay to license most proprietary ISAs, they cant pick and choose which parts of the instructions they want so they can come with loads of unnecessary information that may slow down devices.

But with RISC-V chips, device makers can customize their instructions. Without all the extra info in there, consumer electronics such as smartphones and computers as well as also household appliances like dishwashers and refrigerators could run on less energy, potentially extending battery life and saving people money in the long run.

Whats more, the RISC-V approach also allows companies to create entirely new instructions, Hauck explains. Such flexibility even excites the tech giants that could afford the ISA licensing fees in the first place.

A data storage company called Western Digital, for example, was one of the first to put RISC-V in a commercial device, Hauck says. In 2019, Western Digital announced it would begin using the system to invent its own instructions to make its drives faster and more efficient. You can even buy the worlds first laptop with a RISC-V processor, which went on sale this past fall.

The freedom and customizability provided by RISC-V could help speed up the development of futuristic tech.

Beyond expanding the lives of our daily devices, RISC-V is also ideal for fledgling fields at the forefront of technology, such as artificial intelligence and machine learning, cryptocurrency, and quantum computing, Hauck says.

This work requires as much computing horsepower as possible, but tech companies cant assume that computer processors will keep improving fast enough to keep up with cutting-edge research. Instead, he says, new developments will need to rely on multiple kinds of processors at once a goal that the researchers behind RISC-V had in mind.

RISC-V could also rev up progress on self-driving cars. Hauck points to companies like Ventana, which is building RISC-V chips to help tomorrows cars handle mountains of data as they whisk us around.

The Chinese tech behemoth Alibaba is even considering putting RISC-V in massive data servers, he says, but these instructions could also work for the tiniest of devices. I hear about [integrations like] hearing aids and soldering irons, he says. You just look at that and you go, wow, this is amazing, you want to put a RISC-V processor there?

Before these instructions can deliver on these lofty promises, plenty of challenges lie ahead. For instance, because its all relatively new, many of the accompanying technologies that will make up an entire RISC-V system still need to be invented.

Though that might make using RISC-V seem riskier than just dropping a proven system into new products, Asghar says companies are already building compatible components at every stage of the supply chain.

Before RISC-V, there wasn't something like that where I think the whole industry had coalesced around it, he says. We have been watching it, investing in it for quite some time. But we invested in it knowing that this had legs. This is something that had potential.

Himelstein compares early RISC-V embracers to the community that grew around Linux, a beloved open-source operating system created in the early 90s. Linux was never the most powerful OS, he says, yet it has amassed millions of devoted users from researchers to businesses to gamers.

People feel the same way around RISC-V, he says. It's their house, and they can do with it what they need to do.

These are the innovations of today that will shape the world of tomorrow. Subscribe for free to Inverses weekly HORIZONS newsletter.

Originally posted here:
Scientists Broke a Major Computer Design Barrier And It Could ... - Inverse

ZUG, Switzerland, April 12, 2023 /PRNewswire/ -- The Quantum Resistance Corporation (QRC), post-quantum security experts, today announced a strategic partnership with RedSense, a leading threat intelligence and cybersecurity firm. RedSense will provide network security and management services for the QRC, and together RedSense and QRC will provide security for cryptocurrencies, as well as developers utilizing the Quantum Resistant Ledger (QRL) post-quantum secure blockchain to develop future-proof solutions.

In particular, this partnership will result in a unique security program and market offering that leverages the combined expertise of RedSense and the QRC to help cryptocurrencies respond to the rapidly advancing threat of quantum computing.

Bitcoin Doomsday: New partnership will help cryptocurrencies manage imminent threats from quantum computing advancements

"The web3 space is often the site of lax security as projects, platforms and technology are often built without concern for traditional computer security processes and review. Without having a centralized authority to dictate policy, only a sufficiently advanced intelligence program such as what RedSense and the QRC provide, can provide some assurance to participants in an ecosystem that the sites and services they use have any degree of consistent security," said Craig Clement of the QRL Community. "RedSense and the QRC are building a program that we will extend to the market to help secure all digital currency projects and reduce attacks."

Popular cryptocurrencies such as Bitcoin, Ethereum and Solana are hacked on an almost weekly basis, inflicting significant financial losses on users and further damaging the mainstream perception of cryptocurrency. In 2022, more than $3.8 billion worth of digital coins were stolen from digital asset holders, according to Chainalysis. The eye-popping losses (recent attacks on Wormhole, Binance and Ronin Network cost users between $325 million and $625 million per incident) reflect the significant vulnerabilities of decentralized finance protocols in traditional blockchain technology.

"Unfortunately, we are only going to see more and more frequent attacks on cryptocurrencies and users' digital assets," said Yelisey Bohuslavskiy, Chief Intelligence Officer of RedSense. "The existing technology has a fundamental flaw, there are known attacks that can cause digital coins to go to zero and this will happen just as soon as a quantum computer of sufficient size is brought online. It's functionally unfixable and we could be just three to five years from a nightmare scenario."

The QRC is a project of the Quantum Resistant Ledger (QRL), the only blockchain that utilizes a signature scheme that's recognized by the United States National Institute of Science and Technology (NIST) as being post-quantum secure with its use of XMSS. With the QRC providing a community security program backed by RedSense technology, this partnership will enable more developers to use the QRL network to build DeFi, NFTs, DAOs, DEXs, gaming, and communications apps that are secure from post-quantum cryptography threats.

Learn more about the quantum computing risk, post-quantum security, and future-proof solutions:

The Quantum Resistant Ledger

The Quantum Resistance Corporation

RedSense

SOURCE The Quantum Resistance Corporation

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The Quantum Resistance Corporation and RedSense Announce ... - PR Newswire

Weeks after the Raman Research Institute (RRI) in Bengaluru demonstrated a breakthrough in Indian quantum communication by making a transmission from a stationary object to a moving one, an agreement has been signed with the Navys Weapons and Electronics Systems Engineering Establishment (WESEE). The MoU, which will last for five years, was signed in New Delhi last week by RRI director Tarun Souradeep and Vice-Admiral Sandeep Naithani.

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The director said that the Indian science and technology ecosystem in recent years is enabling talented and world-class researchers in academic research institutions to contribute to the growth of science and technology capabilities in strategic areas of national importance. Porosity of the perceived boundary between fundamental and applied sciences as well as science and technology will bode well in the coming decades. RRI feels proud to partner with WESEE in cutting edge Science and Technology, Souradeep said.

Professor Urbasi Sinha, group head of the Quantum Information and Computing Lab at RRI, said that the laboratory would be able to foster cutting edge research in order to identify maritime use-cases for the Navy.

The lab had earlier demonstrated transmission of quantum keys between stationary points in 2021. The idea is to transmit quantum keys in order to secure transmissions, as normal keys are protected by mathematical complexity which could be broken by advances in quantum computing. On the other hand, quantum entangled particles are particles which continue to show similar properties apart from each other.

First published on: 13-04-2023 at 12:38 IST

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After breakthrough in quantum communication, Bengalurus Raman Research Institute inks pact with Navy - The Indian Express

Full Year Results of $11.1 Million in Revenue and $24.5 Million in Bookings

Fourth Quarter Result of $3.8 Million in Revenue

Meeting and Exceeding Both Technical and Commercial Milestones

COLLEGE PARK, Md., March 30, 2023--(BUSINESS WIRE)--IonQ (NYSE: IONQ), a leader in the quantum computing industry, today announced financial results for the quarter and full year ended December 31, 2022, and provided a business update.

"IonQ had a fantastic 2022. We continue to lead our industry as the most advanced and well-capitalized public pure play quantum computing company in the world, and by a wide margin," said Peter Chapman, President and CEO of IonQ.

"We met our FY22 goal of #AQ 25 early, and our 29 #AQ goal for 2023 ensures that we will be working to further our technical lead in the industry. As we keep delivering against our technical roadmap, we expect our systems will continue to be the worlds most powerful, allowing our customers to solve their most complex problems."

"While we have seen market conditions slow demand for certain technologies, even affecting some of our peers, IonQ shows no signs of slowing down," noted Chapman. "Our financial outlook for the year predicts even faster growth than in 2022, as customers and prospects continue to show enthusiasm for and commitment to our industry-leading quantum computers and the quantum future as a whole."

2022 Financial Highlights

IonQ beat the high end of full year 2022 revenue guidance, with $11.1 million in revenue.

IonQ recognized revenue of $3.8 million for the fourth quarter, compared to $1.6 million in the prior year period.

IonQ achieved bookings of $24.5 million for the full year 2022.

Cash, cash equivalents and investments were $537.8 million as of December 31, 2022.

IonQs diversified strategy and partnerships with several large, global banking institutions meant that the Companys exposure to recent events in the banking sector was immaterial. IonQ believes that this approach will continue to serve the Company well in the future.

IonQ is confident in the state of its cash and other financial assets, and believes they provide the Company with sufficient reserves to get to profitability without needing to raise additional funds, based on the current roadmap.

Net loss was $18.6 million in the fourth quarter, compared to $74.1 million in the prior year period, and net loss was $48.5 million for the full year 2022 versus $106.2 million in 2021.

Adjusted EBITDA* for the fourth quarter was ($13.3) million, compared to ($8.0) million in the prior year period, and ($48.7) million for the full year 2022 versus ($28.4) million for 2021. Excluded from Adjusted EBITDA is, among other adjustments, a non-cash gain related to the change in the fair value of IonQs warrant liabilities of $1.8 million for the fourth quarter and $30.1 million for the full year 2022.

Story continues

* Adjusted EBITDA is a non-GAAP financial measure defined under "Non-GAAP Financial Measures," and is reconciled to net loss, its closest comparable GAAP measure, at the end of this release.

2023 Financial Outlook

For the full year 2023, IonQ expects revenue to be between $18.4 million and $18.8 million, with between $3.6 million and $4.0 million for the first quarter.

IonQ anticipates full year 2023 bookings of between $38 million and $42 million.

IonQ anticipates an Adjusted EBITDA** loss of $80.5 million for the full year 2023 at the midpoint of the revenue outlook provided above.

** Adjusted EBITDA is a non-GAAP financial measure defined under "Non-GAAP Financial Measures." The Company cannot provide a reconciliation between its forecasted Adjusted EBITDA and net loss without unreasonable effort due to the unavailability of estimates for stock-based compensation and change in fair value of assumed warrant liabilities, as these items are not within the Companys control, may vary greatly between periods and could significantly impact future financial results.

Commercial Highlights

Technical Highlights

IonQ achieved #AQ 25, its technical milestone for 2022, increasing the computational power of its Aria system by approximately 4x. Aria was already believed to be the most powerful quantum computer known, and is available to the public via cloud access on Microsofts Azure Quantum Cloud.

IonQ believes that quantum machine learning, or QML, will become one of the most practical and powerful applications of quantum computing in the years to come, given its ability to search through vast amounts of data and identify the best statistical fit. IonQ announced a number of QML updates, including:

In collaboration with Hyundai Motor Company, IonQ applied QML techniques to 3D object detection for autonomous vehicles to reduce modeling complexity by several orders of magnitude.

IonQ successfully designed and ran the first ever quantum circuits that can simulate human cognitive biases, paving the way for these models to potentially become a key component in the development of highly effective AI-enabled chatbots in the future.

In partnership with Hyundai Motor Company, IonQ successfully ran the largest correlated quantum chemistry simulation in history, using IonQ quantum computers.

In collaboration with Accenture and the Irish Centre for High-End Computing, IonQ created a scalable chemistry simulation platform that focuses on breaking down human-made carcinogens in the environment.

Fourth Quarter and Full Year 2022 Conference Call

IonQ will host a conference call today at 4:30 p.m. Eastern time to review the Companys financial results for the fourth quarter and full year ended December 31, 2022 and to provide a business update. The call will be accessible by telephone at 877-270-2148 (domestic) or 412-902-6510 (international). The call will also be available live via webcast on the Companys website here, or directly here. A telephone replay of the conference call will be available at 877-344-7529 or 412-317-0088 with access code 7197039 and will be available until 11:59 p.m. Eastern time, April 30, 2023. An archive of the webcast will also be available shortly after the call and will remain available for 90 days.

Non-GAAP Financial Measures

To supplement IonQs consolidated financial statements presented in accordance with GAAP, IonQ uses non-GAAP measures of certain components of financial performance. Adjusted EBITDA is a financial measure that is not required by or presented in accordance with GAAP. Management believes that this measure provides investors an additional meaningful method to evaluate certain aspects of the Companys results period over period. Adjusted EBITDA is defined as net loss before interest income, net, interest expense, benefit from income taxes, depreciation and amortization expense, stock-based compensation, change in fair value of assumed warrant liabilities, offering cost associated with warrants, and other non-recurring non-operating income and expenses. IonQ uses Adjusted EBITDA to measure the operating performance of its business, excluding specifically identified items that it does not believe directly reflect its core operations and may not be indicative of recurring operations. The presentation of non-GAAP financial measures is not meant to be considered in isolation or as a substitute for the financial results prepared in accordance with GAAP, and IonQs non-GAAP measures may be different from non-GAAP measures used by other companies. For IonQs investors to be better able to compare the Companys current results with those of previous periods, IonQ shows a reconciliation of GAAP to non-GAAP financial measures at the end of this release.

About IonQ

IonQ, Inc. is a leader in quantum computing, with a proven track record of innovation and deployment. IonQs current generation quantum computer, IonQ Forte, is the latest in a line of cutting-edge systems, including IonQ Aria, a system that boasts industry-leading 25 algorithmic qubits. Along with record performance, IonQ has defined what it believes is the best path forward to scale.

IonQ is the only company with its quantum systems available through the cloud on Amazon Braket, Microsoft Azure and Google Cloud, as well as through direct API access. IonQ was founded in 2015 by Christopher Monroe and Jungsang Kim based on 25 years of pioneering research. To learn more, visit http://www.ionq.com.

Forward-Looking Statements

This press release contains certain forward-looking statements within the meaning of Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended. Some of the forward-looking statements can be identified by the use of forward-looking words. Statements that are not historical in nature, including the words "anticipate," "expect," "suggests," "plan," "believe," "intend," "estimates," "targets," "projects," "should," "could," "would," "may," "will," "forecast" and other similar expressions are intended to identify forward-looking statements. These statements include those related to the Companys ability to further develop and advance its quantum computers and achieve scale, including by continuing to improve its algorithmic qubits to 29, or at all; the sufficiency of the Companys cash reserves and future profitability without the need to raise additional funds; the potential benefits of quantum computing and IonQs collaborations and partnerships; IonQs market opportunity, anticipated growth, and future financial performance, including managements financial outlook for the first quarter and full year 2023; continued customer demand for IonQs products; contributions to IonQs business by new hires and members of the board; IonQs ability to open a quantum computing manufacturing facility; and the prospect of QML becoming one of the most practical and powerful applications of quantum computing in years to come. Forward-looking statements are predictions, projections and other statements about future events that are based on current expectations and assumptions and, as a result, are subject to risks and uncertainties. Many factors could cause actual future events to differ materially from the forward-looking statements in this press release, including but not limited to: market adoption of quantum computing solutions and the Companys products, services and solutions; the ability of the Company to protect its intellectual property; changes in the competitive industries in which the Company operates; changes in laws and regulations affecting the Companys business; the Companys ability to implement its business plans, forecasts and other expectations, and identify and realize additional partnerships and opportunities; and the risk of downturns in the market and the technology industry including, but not limited to, as a result of public health crises and/or increased inflationary pressures. The foregoing list of factors is not exhaustive. You should carefully consider the foregoing factors and the other risks and uncertainties described in the "Risk Factors" section of IonQs Quarterly Report on Form 10-Q for the quarter ended September 30, 2022 and other documents filed by the Company from time to time with the Securities and Exchange Commission. These filings identify and address other important risks and uncertainties that could cause actual events and results to differ materially from those contained in the forward-looking statements. Forward-looking statements speak only as of the date they are made. Readers are cautioned not to put undue reliance on forward-looking statements, and the Company assumes no obligation and does not intend to update or revise these forward-looking statements, whether as a result of new information, future events, or otherwise. The Company does not give any assurance that it will achieve its expectations.

IonQ, Inc.

Consolidated Statements of Operations

(unaudited)

(in thousands, except share and per share data)

Three Months Ended

Year Ended

December 31,

December 31,

2022

2021

2022

2021

Revenue

$

3,807

$

1,648

$

11,131

$

2,099

Costs and expenses:

Cost of revenue (excluding depreciation and amortization)

901

298

2,944

1,040

Research and development

13,696

4,917

43,978

20,228

Sales and marketing

2,414

849

8,385

3,233

General and administrative

9,065

5,416

35,966

13,737

Depreciation and amortization

1,356

1,005

5,604

2,548

Total operating costs and expenses

27,432

12,485

96,877

40,786

Loss from operations

(23,625

)

(10,837

)

(85,746

)

(38,687

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IonQ Announces Fourth Quarter and Full Year 2022 Financial Results and Provides Business Update - Yahoo Finance

A niobium superconducting cavity. The holes lead to tunnels which intersect to trap light and atoms. Credit: Aishwarya Kumar

Scientists have uncovered a method to convert quantum information between various quantum technologies, which holds significant impliciations for quantum computing, communication, and networking.

The study, which was published in the journal Nature, was financially supported by the Army Research Office (ARO), the Air Force Office of Scientific Research (AFOSR), and the NSF Quantum Leap Challenge Institute for Hybrid Quantum Architectures and Networks (HQAN), led by the University of Illinois Urbana-Champaign. This represents an innovative approach to transforming quantum information from the format utilized by quantum computers to the format required for quantum communication.

Photonsparticles of lightare essential for quantum information technologies, but different technologies use them at different frequencies. For example, some of the most common quantum computing technology is based on superconducting qubits, such as those used by tech giants Google and IBM; these qubits store quantum information in photons that move at microwave frequencies.

But if you want to build a quantum network, or connect quantum computers, you cant send around microwave photons because their grip on their quantum information is too weak to survive the trip.

A lot of the technologies that we use for classical communicationcell phones, Wi-Fi, GPS, and things like thatall use microwave frequencies of light, said Aishwarya Kumar, a postdoc at the James Franck Institute at the University of Chicago and lead author on the paper. But you cant do that for quantum communication because the quantum information you need is in a single photon. And at microwave frequencies, that information will get buried in thermal noise.

A diagram of the electron energy levels of Rubidium. Two of the energy level gaps match the frequencies of optical photons and microwave photons, respectively. Lasers are used to force the electron to jump to higher levels or drop to lower levels. Credit: Aishwarya Kumar

The solution is to transfer the quantum information to a higher-frequency photon, called an optical photon, which is much more resilient against ambient noise. But the information cant be transferred directly from photon to photon; instead, we need intermediary matter. Some experiments design solid-state devices for this purpose, but Kumars experiment aimed for something more fundamental: atoms.

The electrons in atoms are only ever allowed to have certain specific amounts of energy, called energy levels. If an electron is sitting at a lower energy level, it can be excited to a higher energy level by hitting it with a photon whose energy exactly matches the difference between the higher and lower level. Similarly, when an electron is forced to drop to a lower energy level, the atom then emits a photon with an energy that matches the energy difference between levels.

Rubidium atoms happen to have two gaps in their levels that Kumars technology exploits: one that exactly equals the energy of a microwave photon, and one that exactly equals the energy of an optical photon. By using lasers to shift the atoms electron energies up and down, the technology allows the atom to absorb a microwave photon with quantum information and then emit an optical photon with that quantum information. This translation between different modes of quantum information is called transduction.

Effectively using atoms for this purpose is made possible by the significant progress scientists have made in manipulating such small objects. We as a community have built remarkable technology in the last 20 or 30 years that lets us control essentially everything about the atoms, Kumar said. So the experiment is very controlled and efficient.

He says the other secret to their success is the fields progress in cavity quantum electrodynamics, where a photon is trapped in a superconducting, reflective chamber. Forcing the photon to bounce around in an enclosed space, the superconducting cavity strengthens the interaction between the photon and whatever matter is placed inside it.

Their chamber doesnt look very enclosedin fact, it more closely resembles a block of Swiss cheese. But what looks like holes are actually tunnels that intersect in a very specific geometry, so that photons or atoms can be trapped at an intersection. Its a clever design that also allows researchers access to the chamber so they can inject the atoms and the photons.

The technology works both ways: it can transfer quantum information from microwave photons to optical photons, and vice versa. So it can be on either side of a long-distance connection between two superconducting qubit quantum computers, and serve as a fundamental building block to a quantum internet.

But Kumar thinks there may be a lot more applications for this technology than just quantum networking. Its core ability is to strongly entangle atoms and photonsan essential, and difficult task in many different quantum technologies across the field.

One of the things that were really excited about is the ability of this platform to generate really efficient entanglement, he said. Entanglement is central to almost everything quantum that we care about, from computing to simulations to metrology and atomic clocks. Im excited to see what else we can do.

Reference: Quantum-enabled millimetre wave to optical transduction using neutral atoms by Aishwarya Kumar, Aziza Suleymanzade, Mark Stone, Lavanya Taneja, Alexander Anferov, David I. Schuster and Jonathan Simon, 22 March 2023, Nature.DOI: 10.1038/s41586-023-05740-2

Originally posted here:
An Important Step for the Quantum Internet: New Experiment Translates Quantum Information Between Technologies - SciTechDaily