JOINT PARITY MEASUREMENTS OF MAJORANA ZERO MODES IN THE PRESENCE OF QUASIPARTICLE POISONING

Organization Name

Microsoft Technology Licensing, LLC

Inventor(s)

Parsa Bonderson of Santa Barbara CA (US)

David Alexander Aasen of Santa Barbara CA (US)

Christina Paulsen Knapp of Goleta CA (US)

JOINT PARITY MEASUREMENTS OF MAJORANA ZERO MODES IN THE PRESENCE OF QUASIPARTICLE POISONING - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240378477 titled 'JOINT PARITY MEASUREMENTS OF MAJORANA ZERO MODES IN THE PRESENCE OF QUASIPARTICLE POISONING

The abstract describes a computing system with a quantum computing device that includes Majorana islands, quantum dots, and capacitance sensors. The system is controlled to perform joint parity measurements of multiple Majorana zero modes (MZMs) in an island-dot system.

• Majorana islands, quantum dots, and capacitance sensors are key components of the quantum computing device.
• The controller is configured to control the device to perform joint parity measurements of MZMs.
• The joint parity measurement involves setting gate voltages to candidate resonance values and detecting microwave response signals.
• The output of the joint parity measurement is based on the microwave response signals.

Potential Applications: - Quantum computing - Error correction in quantum systems - Advanced data processing and analysis

Problems Solved: - Enhancing quantum computing capabilities - Improving error detection and correction in quantum systems

Benefits: - Increased accuracy in quantum computations - Enhanced reliability of quantum systems - Potential for faster and more efficient data processing

Commercial Applications: Title: Quantum Computing System with Joint Parity Measurement This technology could revolutionize industries such as: - Finance - Healthcare - Cybersecurity

Questions about Quantum Computing System with Joint Parity Measurement: 1. How does this technology improve error correction in quantum systems?

  This technology enhances error correction by performing joint parity measurements of MZMs, leading to more accurate quantum computations.

2. What are the potential long-term implications of this innovation in quantum computing?

  The long-term implications include advancements in data processing speed, accuracy, and reliability in various industries.

Original Abstract Submitted

a computing system including a quantum computing device. the quantum computing device includes majorana islands, quantum dots, and capacitance sensors. the computing system further includes a controller configured to, for an island-dot system including one or more majorana islands and one or more quantum dots, control the quantum computing device to perform a joint parity measurement of two or more mzms. performing the joint parity measurement includes, at each of a plurality of candidate resonance regions corresponding to values of a change in a fermion number, setting majorana island gate voltages and quantum dot gate voltages to respective candidate resonance values. the joint parity measurement further includes, at each of the candidate resonance regions, via a capacitance sensor, detecting a microwave response signal measured at the island-dot system. the joint parity measurement further includes outputting a joint parity value based at least in part on the microwave response signal.