#nisq — Public Fediverse posts

https://www.europesays.com/uk/907579/ Quantum Myths vs Reality – Understanding Where the Technology Stands #ErrorCorrection #NISQ #Physics #PostQuantumCryptography #QuantumAdvantage #QuantumComputing #QuantumEncryption #QuantumHype #QuantumResearch #QuantumStartups #QuantumSupremacy #Science #TechnologyTrends #UK #UnitedKingdom

Quantum Myths vs Reality – Understanding Where the Technology Stands

Insider Brief Quantum computing in 2026 sits between real technical progress and exaggerated public expectations, with neither extreme…
#NewsBeep #News #Physics #AU #Australia #errorcorrection #NISQ #Post-quantumcryptography #quantumadvantage #quantumcomputing #quantumencryption #quantumhype #quantumresearch #quantumstartups #QuantumSupremacy #Science #TechnologyTrends
https://www.newsbeep.com/au/619980/

Quantum Myths vs Reality – Understanding Where the Technology Stands

Insider Brief Quantum computing in 2026 sits between real technical progress and exaggerated public expectations, with neither extreme…
#NewsBeep #News #Physics #AU #Australia #errorcorrection #NISQ #Post-quantumcryptography #quantumadvantage #quantumcomputing #quantumencryption #quantumhype #quantumresearch #quantumstartups #QuantumSupremacy #Science #TechnologyTrends
https://www.newsbeep.com/au/619980/

Quantum Myths vs Reality – Understanding Where the Technology Stands

Insider Brief Quantum computing in 2026 sits between real technical progress and exaggerated public expectations, with neither…
#NewsBeep #News #US #USA #UnitedStates #UnitedStatesOfAmerica #Physics #errorcorrection #NISQ #post-quantumcryptography #quantumadvantage #Quantumcomputing #quantumencryption #quantumhype #quantumresearch #quantumstartups #QuantumSupremacy #Science #Technologytrends
https://www.newsbeep.com/us/596246/

Quantum Myths vs Reality – Understanding Where the Technology Stands

Insider Brief Quantum computing in 2026 sits between real technical progress and exaggerated public expectations, with neither…
#NewsBeep #News #US #USA #UnitedStates #UnitedStatesOfAmerica #Physics #errorcorrection #NISQ #post-quantumcryptography #quantumadvantage #Quantumcomputing #quantumencryption #quantumhype #quantumresearch #quantumstartups #QuantumSupremacy #Science #Technologytrends
https://www.newsbeep.com/us/596246/

https://www.europesays.com/ie/445295/ Quantum Myths vs Reality – Understanding Where the Technology Stands #Éire #ErrorCorrection #IE #Ireland #NISQ #Physics #PostQuantumCryptography #QuantumAdvantage #QuantumComputing #QuantumEncryption #QuantumHype #QuantumResearch #QuantumStartups #QuantumSupremacy #Science #TechnologyTrends

Quantum Myths vs Reality – Understanding Where the Technology Stands

Insider Brief Quantum computing in 2026 sits between real technical progress and exaggerated public expectations, with neither extreme…
#NewsBeep #News #Physics #errorcorrection #NISQ #Post-quantumcryptography #quantumadvantage #QuantumComputing #quantumencryption #quantumhype #quantumresearch #quantumstartups #QuantumSupremacy #Science #technologytrends #UK #UnitedKingdom
https://www.newsbeep.com/uk/541669/

#ParityQC just came out with the largest #QFT on an #IBM Quantum device. The QFT was basically an example of how their ParityQC architecture is able to push the limits on what we can do with our #NISQ devices today.

→ press release: https://parityqc.com/parityqc-set-new-record-benchmark-using-ibm-quantum-computer-with-the-largest-quantum-fourier-transform-ever-reported
→ pre-print: https://arxiv.org/abs/2604.12465

#quantumcomputing #IBMQuantum

#ParityQC just came out with the largest #QFT on an #IBM Quantum device. The QFT was basically an example of how their ParityQC architecture is able to push the limits on what we can do with our #NISQ devices today.

→ press release: https://parityqc.com/parityqc-set-new-record-benchmark-using-ibm-quantum-computer-with-the-largest-quantum-fourier-transform-ever-reported
→ pre-print: https://arxiv.org/abs/2604.12465

#quantumcomputing #IBMQuantum

#ParityQC just came out with the largest #QFT on an #IBM Quantum device. The QFT was basically an example of how their ParityQC architecture is able to push the limits on what we can do with our #NISQ devices today.

→ press release: https://parityqc.com/parityqc-set-new-record-benchmark-using-ibm-quantum-computer-with-the-largest-quantum-fourier-transform-ever-reported
→ pre-print: https://arxiv.org/abs/2604.12465

#quantumcomputing #IBMQuantum

#ParityQC just came out with the largest #QFT on an #IBM Quantum device. The QFT was basically an example of how their ParityQC architecture is able to push the limits on what we can do with our #NISQ devices today.

→ press release: https://parityqc.com/parityqc-set-new-record-benchmark-using-ibm-quantum-computer-with-the-largest-quantum-fourier-transform-ever-reported
→ pre-print: https://arxiv.org/abs/2604.12465

#quantumcomputing #IBMQuantum

#ParityQC just came out with the largest #QFT on an #IBM Quantum device. The QFT was basically an example of how their ParityQC architecture is able to push the limits on what we can do with our #NISQ devices today.

→ press release: https://parityqc.com/parityqc-set-new-record-benchmark-using-ibm-quantum-computer-with-the-largest-quantum-fourier-transform-ever-reported
→ pre-print: https://arxiv.org/abs/2604.12465

#quantumcomputing #IBMQuantum

Decode Quantum with Sabrina Maniscalco from Algorithmiq Welcome to the 84th episode of the Decode Quantum podcast series, which has now more than five years... https://www.oezratty.net/wordpress/2025/decode-quantum-with-sabrina-maniscalco-from-algorithmiq/ #PostSapiens #quantumenergyinitiative #quantumchemistry #clevelandclinic #algorithmiq #jaygambetta #actualités #quantique #nisq #ibm

Decode Quantum with Sabrina Maniscalco from Algorithmiq Welcome to the 84th episode of the Decode Quantum podcast series, which has now more than five years... https://www.oezratty.net/wordpress/2025/decode-quantum-with-sabrina-maniscalco-from-algorithmiq/ #PostSapiens #quantumenergyinitiative #quantumchemistry #clevelandclinic #algorithmiq #jaygambetta #actualités #quantique #nisq #ibm

https://www.europesays.com/uk/787049/ Understanding the Quantum Computing Hardware Landscape #FaultTolerance #NeutralAtomQuantumComputing #NISQ #PhotonicQuantumComputing #Physics #QuantumComputing #QuantumHardwareArchitectures #Science #SuperconductingQubits #TrappedIonQuantumComputing #UK #UnitedKingdom

Understanding the Quantum Computing Hardware Landscape

Insider Brief Quantum computing encompasses multiple hardware approaches built on different physical foundations, and the field can be…
#NewsBeep #News #Physics #AU #Australia #faulttolerance #neutralatomquantumcomputing #NISQ #photonicquantumcomputing #quantumcomputing #quantumhardwarearchitectures #Science #superconductingqubits #trappedionquantumcomputing
https://www.newsbeep.com/au/501212/

Understanding the Quantum Computing Hardware Landscape

Insider Brief Quantum computing encompasses multiple hardware approaches built on different physical foundations, and the field can be…
#NewsBeep #News #Physics #AU #Australia #faulttolerance #neutralatomquantumcomputing #NISQ #photonicquantumcomputing #quantumcomputing #quantumhardwarearchitectures #Science #superconductingqubits #trappedionquantumcomputing
https://www.newsbeep.com/au/501212/

https://www.europesays.com/ie/353881/ Understanding the Quantum Computing Hardware Landscape #Éire #FaultTolerance #IE #Ireland #NeutralAtomQuantumComputing #NISQ #PhotonicQuantumComputing #Physics #QuantumComputing #QuantumHardwareArchitectures #Science #SuperconductingQubits #TrappedIonQuantumComputing

Understanding the Quantum Computing Hardware Landscape

Insider Brief Quantum computing encompasses multiple hardware approaches built on different physical foundations, and the field can be…
#NewsBeep #News #US #USA #UnitedStates #UnitedStatesOfAmerica #Physics #faulttolerance #neutralatomquantumcomputing #NISQ #photonicquantumcomputing #Quantumcomputing #quantumhardwarearchitectures #Science #superconductingqubits #trappedionquantumcomputing
https://www.newsbeep.com/us/487571/

Understanding the Quantum Computing Hardware Landscape

Insider Brief Quantum computing encompasses multiple hardware approaches built on different physical foundations, and the field can be…
#NewsBeep #News #US #USA #UnitedStates #UnitedStatesOfAmerica #Physics #faulttolerance #neutralatomquantumcomputing #NISQ #photonicquantumcomputing #Quantumcomputing #quantumhardwarearchitectures #Science #superconductingqubits #trappedionquantumcomputing
https://www.newsbeep.com/us/487571/

Meet the new Enabla #OpenAccess lecture by Prof. Sergey Denisov from the Oslo Metropolitan University, where he discusses the theoretical and experimental aspects of parameterized circuits and their ability to simulate random unitaries, offering a deep dive into NISQ implementations and their potential for sampling random channels.

Have a question? Ask online through our website, and Sergey will help you understand the material better! A must-watch for anyone involved in quantum computing and random matrix theory!

🔗 Watch the full lecture here: https://enabla.com/pub/1122/about

Abstract: We consider the spectral properties of random quantum channels, both theoretically and experimentally, discuss parameterized circuits in their ability to simulate random unitaries, and present results confirming the ability of NISQ implementations of these circuits to sample certain ensembles of random channels

#ComputerScience #QuantumComputing #RandomMatrixTheory #QuantumCircuits #NISQ #OpenScience

Meet the new Enabla #OpenAccess lecture by Prof. Sergey Denisov from the Oslo Metropolitan University, where he discusses the theoretical and experimental aspects of parameterized circuits and their ability to simulate random unitaries, offering a deep dive into NISQ implementations and their potential for sampling random channels.

Have a question? Ask online through our website, and Sergey will help you understand the material better! A must-watch for anyone involved in quantum computing and random matrix theory!

🔗 Watch the full lecture here: https://enabla.com/pub/1122/about

Abstract: We consider the spectral properties of random quantum channels, both theoretically and experimentally, discuss parameterized circuits in their ability to simulate random unitaries, and present results confirming the ability of NISQ implementations of these circuits to sample certain ensembles of random channels

#ComputerScience #QuantumComputing #RandomMatrixTheory #QuantumCircuits #NISQ #OpenScience

Meet the new Enabla #OpenAccess lecture by Prof. Sergey Denisov from the Oslo Metropolitan University, where he discusses the theoretical and experimental aspects of parameterized circuits and their ability to simulate random unitaries, offering a deep dive into NISQ implementations and their potential for sampling random channels.

Have a question? Ask online through our website, and Sergey will help you understand the material better! A must-watch for anyone involved in quantum computing and random matrix theory!

🔗 Watch the full lecture here: https://enabla.com/pub/1122/about

Abstract: We consider the spectral properties of random quantum channels, both theoretically and experimentally, discuss parameterized circuits in their ability to simulate random unitaries, and present results confirming the ability of NISQ implementations of these circuits to sample certain ensembles of random channels

#ComputerScience #QuantumComputing #RandomMatrixTheory #QuantumCircuits #NISQ #OpenScience

Meet the new Enabla #OpenAccess lecture by Prof. Sergey Denisov from the Oslo Metropolitan University, where he discusses the theoretical and experimental aspects of parameterized circuits and their ability to simulate random unitaries, offering a deep dive into NISQ implementations and their potential for sampling random channels.

Have a question? Ask online through our website, and Sergey will help you understand the material better! A must-watch for anyone involved in quantum computing and random matrix theory!

🔗 Watch the full lecture here: https://enabla.com/pub/1122/about

Abstract: We consider the spectral properties of random quantum channels, both theoretically and experimentally, discuss parameterized circuits in their ability to simulate random unitaries, and present results confirming the ability of NISQ implementations of these circuits to sample certain ensembles of random channels

#ComputerScience #QuantumComputing #RandomMatrixTheory #QuantumCircuits #NISQ #OpenScience

Meet the new Enabla #OpenAccess lecture by Prof. Sergey Denisov from the Oslo Metropolitan University, where he discusses the theoretical and experimental aspects of parameterized circuits and their ability to simulate random unitaries, offering a deep dive into NISQ implementations and their potential for sampling random channels.

Have a question? Ask online through our website, and Sergey will help you understand the material better! A must-watch for anyone involved in quantum computing and random matrix theory!

🔗 Watch the full lecture here: https://enabla.com/pub/1122/about

Abstract: We consider the spectral properties of random quantum channels, both theoretically and experimentally, discuss parameterized circuits in their ability to simulate random unitaries, and present results confirming the ability of NISQ implementations of these circuits to sample certain ensembles of random channels

#ComputerScience #QuantumComputing #RandomMatrixTheory #QuantumCircuits #NISQ #OpenScience

Adaptive Trotterization for Time-Dependent Hamiltonian Quantum Dynamics Using Piecewise Conservation Laws

Our new paper introduces an adaptive Trotterization algorithm to tackle time-dependent Hamiltonians in digital quantum simulation. We propose piecewise conserved quantities to control and estimate errors & error accumulation. Read more here in this PRL:

https://doi.org/10.1103/PhysRevLett.133.010603

#trotter #quantumcomputing #nisq

Adaptive Trotterization for Time-Dependent Hamiltonian Quantum Dynamics Using Piecewise Conservation Laws

Our new paper introduces an adaptive Trotterization algorithm to tackle time-dependent Hamiltonians in digital quantum simulation. We propose piecewise conserved quantities to control and estimate errors & error accumulation. Read more here in this PRL:

https://doi.org/10.1103/PhysRevLett.133.010603

#trotter #quantumcomputing #nisq

Adaptive Trotterization for Time-Dependent Hamiltonian Quantum Dynamics Using Piecewise Conservation Laws

Our new paper introduces an adaptive Trotterization algorithm to tackle time-dependent Hamiltonians in digital quantum simulation. We propose piecewise conserved quantities to control and estimate errors & error accumulation. Read more here in this PRL:

https://doi.org/10.1103/PhysRevLett.133.010603

#trotter #quantumcomputing #nisq

Adaptive Trotterization for Time-Dependent Hamiltonian Quantum Dynamics Using Piecewise Conservation Laws

Our new paper introduces an adaptive Trotterization algorithm to tackle time-dependent Hamiltonians in digital quantum simulation. We propose piecewise conserved quantities to control and estimate errors & error accumulation. Read more here in this PRL:

https://doi.org/10.1103/PhysRevLett.133.010603

#trotter #quantumcomputing #nisq

Adaptive Trotterization for Time-Dependent Hamiltonian Quantum Dynamics Using Piecewise Conservation Laws

Our new paper introduces an adaptive Trotterization algorithm to tackle time-dependent Hamiltonians in digital quantum simulation. We propose piecewise conserved quantities to control and estimate errors & error accumulation. Read more here in this PRL:

https://doi.org/10.1103/PhysRevLett.133.010603

#trotter #quantumcomputing #nisq

Making Trotterization Adaptive and Energy-Self-Correcting for NISQ Devices and Beyond

Digital quantum simulation requires time discretization by means of Trotterization. A finer time step improves simulation precision but inevitably leads to increased experimental errors for today’s noisy intermediate-scale quantum computers. Check out in our recent publication how to make Trotterization adaptive:

https://journals.aps.org/prxquantum/abstract/10.1103/PRXQuantum.4.030319

#quantumsimulation #nisq #quantumcomputer #trotterization

Making Trotterization Adaptive and Energy-Self-Correcting for NISQ Devices and Beyond

Digital quantum simulation requires time discretization by means of Trotterization. A finer time step improves simulation precision but inevitably leads to increased experimental errors for today’s noisy intermediate-scale quantum computers. Check out in our recent publication how to make Trotterization adaptive:

https://journals.aps.org/prxquantum/abstract/10.1103/PRXQuantum.4.030319

#quantumsimulation #nisq #quantumcomputer #trotterization

Making Trotterization Adaptive and Energy-Self-Correcting for NISQ Devices and Beyond

Digital quantum simulation requires time discretization by means of Trotterization. A finer time step improves simulation precision but inevitably leads to increased experimental errors for today’s noisy intermediate-scale quantum computers. Check out in our recent publication how to make Trotterization adaptive:

https://journals.aps.org/prxquantum/abstract/10.1103/PRXQuantum.4.030319

#quantumsimulation #nisq #quantumcomputer #trotterization

Making Trotterization Adaptive and Energy-Self-Correcting for NISQ Devices and Beyond

Digital quantum simulation requires time discretization by means of Trotterization. A finer time step improves simulation precision but inevitably leads to increased experimental errors for today’s noisy intermediate-scale quantum computers. Check out in our recent publication how to make Trotterization adaptive:

https://journals.aps.org/prxquantum/abstract/10.1103/PRXQuantum.4.030319

#quantumsimulation #nisq #quantumcomputer #trotterization

Making Trotterization Adaptive and Energy-Self-Correcting for NISQ Devices and Beyond

Digital quantum simulation requires time discretization by means of Trotterization. A finer time step improves simulation precision but inevitably leads to increased experimental errors for today’s noisy intermediate-scale quantum computers. Check out in our recent publication how to make Trotterization adaptive:

https://journals.aps.org/prxquantum/abstract/10.1103/PRXQuantum.4.030319

#quantumsimulation #nisq #quantumcomputer #trotterization

Quantum computing is set to revolutionize industries, and it is never too soon to dive into this rapidly advancing field😉

Explore the core concepts in the new introductory DESY lecture and engage in open discussions at https://enabla.com/pub/1069/about 🔗

Learn about qubits, quantum gates, the role of entanglement in quantum algorithms, the fundamentals of complexity theory, a few hybrid quantum-classical algorithms, and the noisy intermediate-sized quantum devices🧑‍💻

All #Enabla lectures are #free and #OpenAccess. Support us by liking, reposting, following, and engaging in discussions on Enabla. Your actions help us spread knowledge. Thank you!🙏 @DESY @DESYnews

#QuantumComputing #Qubits #Entanglement #QuantumAlgorithms #ComplexityTheory #NISQ

Curious about quantum computing's real-world applications? Check out the MPI-PKS talk by Prof.Smith from the University of Nottingham, and learn with hands-on examples using the IBM Cloud quantum computers and @qiskit python library🧑‍💻

🔗 https://enabla.com/set/92/pub/642/about

The lecture covers the basics of quantum mechanics necessary to understand quantum circuits and explores two applications in many-body physics: finding ground states and simulating non-equilibrium dynamics. Perfect for beginners and experts alike. Don't miss out!

All #Enabla lectures are #free and #OpenAccess. If you like what we're doing, please support us by liking, sharing, following this account, leaving some comments under this post & asking questions on Enabla. Any of these actions help us a lot; thank you!🙏

#QuantumComputing #IBMQuantum #Qiskit #QuantumCircuits #NISQ #ManyBodyPhysics

Curious about quantum computing's real-world applications? Check out the MPI-PKS talk by Prof.Smith from the University of Nottingham, and learn with hands-on examples using the IBM Cloud quantum computers and @qiskit python library🧑‍💻

🔗 https://enabla.com/set/92/pub/642/about

The lecture covers the basics of quantum mechanics necessary to understand quantum circuits and explores two applications in many-body physics: finding ground states and simulating non-equilibrium dynamics. Perfect for beginners and experts alike. Don't miss out!

All #Enabla lectures are #free and #OpenAccess. If you like what we're doing, please support us by liking, sharing, following this account, leaving some comments under this post & asking questions on Enabla. Any of these actions help us a lot; thank you!🙏

#QuantumComputing #IBMQuantum #Qiskit #QuantumCircuits #NISQ #ManyBodyPhysics

Curious about quantum computing's real-world applications? Check out the MPI-PKS talk by Prof.Smith from the University of Nottingham, and learn with hands-on examples using the IBM Cloud quantum computers and @qiskit python library🧑‍💻

🔗 https://enabla.com/set/92/pub/642/about

The lecture covers the basics of quantum mechanics necessary to understand quantum circuits and explores two applications in many-body physics: finding ground states and simulating non-equilibrium dynamics. Perfect for beginners and experts alike. Don't miss out!

All #Enabla lectures are #free and #OpenAccess. If you like what we're doing, please support us by liking, sharing, following this account, leaving some comments under this post & asking questions on Enabla. Any of these actions help us a lot; thank you!🙏

#QuantumComputing #IBMQuantum #Qiskit #QuantumCircuits #NISQ #ManyBodyPhysics

Curious about quantum computing's real-world applications? Check out the MPI-PKS talk by Prof.Smith from the University of Nottingham, and learn with hands-on examples using the IBM Cloud quantum computers and @qiskit python library🧑‍💻

🔗 https://enabla.com/set/92/pub/642/about

The lecture covers the basics of quantum mechanics necessary to understand quantum circuits and explores two applications in many-body physics: finding ground states and simulating non-equilibrium dynamics. Perfect for beginners and experts alike. Don't miss out!

All #Enabla lectures are #free and #OpenAccess. If you like what we're doing, please support us by liking, sharing, following this account, leaving some comments under this post & asking questions on Enabla. Any of these actions help us a lot; thank you!🙏

#QuantumComputing #IBMQuantum #Qiskit #QuantumCircuits #NISQ #ManyBodyPhysics

Are we there yet? Are we there yet? Are we there yet?

No, kids, but soon. Just another 5 years.

State of #quantumcomputing #nisq summarised by Olivier Ezratty

https://arxiv.org/abs/2305.09518

Are we there yet? Are we there yet? Are we there yet?

No, kids, but soon. Just another 5 years.

State of #quantumcomputing #nisq summarised by Olivier Ezratty

https://arxiv.org/abs/2305.09518

Are we there yet? Are we there yet? Are we there yet?

No, kids, but soon. Just another 5 years.

State of #quantumcomputing #nisq summarised by Olivier Ezratty

https://arxiv.org/abs/2305.09518

Are we there yet? Are we there yet? Are we there yet?

No, kids, but soon. Just another 5 years.

State of #quantumcomputing #nisq summarised by Olivier Ezratty

https://arxiv.org/abs/2305.09518

Are we there yet? Are we there yet? Are we there yet?

No, kids, but soon. Just another 5 years.

State of #quantumcomputing #nisq summarised by Olivier Ezratty

https://arxiv.org/abs/2305.09518

To me, it is very obvious that quantum computing will specifically help with problem (1) in the near term. I think that problem (2) needs significant work (maybe even fundamental work) to continue reducing overhead, particularly for #NISQ.

To me, it is very obvious that quantum computing will specifically help with problem (1) in the near term. I think that problem (2) needs significant work (maybe even fundamental work) to continue reducing overhead, particularly for #NISQ.

To me, it is very obvious that quantum computing will specifically help with problem (1) in the near term. I think that problem (2) needs significant work (maybe even fundamental work) to continue reducing overhead, particularly for #NISQ.

To me, it is very obvious that quantum computing will specifically help with problem (1) in the near term. I think that problem (2) needs significant work (maybe even fundamental work) to continue reducing overhead, particularly for #NISQ.

To me, it is very obvious that quantum computing will specifically help with problem (1) in the near term. I think that problem (2) needs significant work (maybe even fundamental work) to continue reducing overhead, particularly for #NISQ.