PRESIDENT AND FELLOWS OF HARVARD COLLEGE (20240346352). DYNAMICALLY RECONFIGURABLE ARCHITECTURES FOR QUANTUM INFORMATION AND SIMULATION simplified abstract
Contents
DYNAMICALLY RECONFIGURABLE ARCHITECTURES FOR QUANTUM INFORMATION AND SIMULATION
Organization Name
PRESIDENT AND FELLOWS OF HARVARD COLLEGE
Inventor(s)
Dolev Bluvstein of Cambridge MA (US)
Harry Jay Levne of Cambridge MA (US)
Giulia Semeghini of Cambridge MA (US)
Tout Wang of Cambridge MA (US)
Sepehr Ebadi of Cambridge MA (US)
Alexander Keesling Contreras of Cambridge MA (US)
Mikhail D. Lukin of Cambridge MA (US)
Markus Greiner of Cambridge MA (US)
Vladan Vuletic of Cambridge MA (US)
DYNAMICALLY RECONFIGURABLE ARCHITECTURES FOR QUANTUM INFORMATION AND SIMULATION - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240346352 titled 'DYNAMICALLY RECONFIGURABLE ARCHITECTURES FOR QUANTUM INFORMATION AND SIMULATION
The patent application discusses dynamically reconfigurable architectures for quantum information and simulation using a plurality of neutral atoms in optical traps.
- Plurality of neutral atoms provided in corresponding optical traps
- Atoms prepared in m=0 clock state
- Pair of neutral atoms entangled using a laser pulse through a Rydberg state
- Adiabatic movement of optical trap to move one atom relative to the other without destroying entanglement
Potential Applications: - Quantum computing - Quantum simulation - Quantum communication
Problems Solved: - Enhancing quantum information processing - Facilitating quantum entanglement - Improving quantum simulation accuracy
Benefits: - Increased efficiency in quantum information processing - Enhanced control over quantum systems - Advancement in quantum technology
Commercial Applications: Title: "Quantum Computing Systems for Enhanced Information Processing" This technology can be utilized in industries such as: - Information technology - Research and development - Defense and security
Questions about Quantum Information and Simulation: 1. How does the adiabatic movement of optical traps benefit quantum entanglement?
- The adiabatic movement allows for the relative movement of atoms without disrupting their entanglement, enabling more complex quantum operations.
2. What are the potential challenges in scaling up this technology for practical quantum computing applications?
- Scaling up may face challenges related to maintaining entanglement over larger systems and controlling interactions between multiple entangled atoms.
Original Abstract Submitted
dynamically reconfigurable architectures for quantum information and simulation are provided. a plurality of neutral atoms is provided. each neutral atom is disposed in a corresponding optical trap. each of the plurality of neutral atoms is prepared in a m=0 clock state. a pair of neutral atoms of the plurality of neutral atoms is entangled by directing a laser pulse thereto. the laser pulse is configured to transition the pair of neutral atoms through a rydberg state. the optical trap corresponding to at least one neutral atom of the pair is adiabatically moved, thereby moving one atom of the pair relative to the other atom of the pair without destroying entanglement of the pair.
- PRESIDENT AND FELLOWS OF HARVARD COLLEGE
- Dolev Bluvstein of Cambridge MA (US)
- Harry Jay Levne of Cambridge MA (US)
- Giulia Semeghini of Cambridge MA (US)
- Tout Wang of Cambridge MA (US)
- Sepehr Ebadi of Cambridge MA (US)
- Alexander Keesling Contreras of Cambridge MA (US)
- Mikhail D. Lukin of Cambridge MA (US)
- Markus Greiner of Cambridge MA (US)
- Vladan Vuletic of Cambridge MA (US)
- G06N10/40
- G06N10/20
- G06N10/70
- CPC G06N10/40