| name | piston-control-two-ion-quantum |
| description | Inverse-engineering methodology for piston operations in trapped-ion quantum devices. One ion serves as classical piston driven by Coulomb interaction with quantum-controlled ion. Stationary state determined self-consistently. Inverse-engineering protocols enable precise control of classical ion motion. Provides route toward controlled piston dynamics in microscopic quantum devices. |
| license | Complete terms in LICENSE.txt |
| metadata | {"arxiv_id":"2606.03488","published":"2026-06-02","authors":"Jing Li, E. Ya. Sherman, Andreas Ruschhaupt","tags":["quantum-control","ion-traps","piston-dynamics","inverse-engineering","trapped-ion","two-ion-system","coulomb-coupling"]} |
Piston Control in Two-Ion Quantum Devices
Core Problem
Controlling microscopic piston dynamics in quantum devices is essential for quantum thermodynamics, heat engines, and quantum information processing. Two-ion systems with motion confined to orthogonal axes offer a natural platform where one ion acts as a "classical" piston driven by Coulomb interaction with a quantum-controlled ion.
System Architecture
- Two-Ion Configuration: Two ions confined to orthogonal axes
- Coulomb Coupling: One ion (quantum) controlled via trapping potential modulation; the other (classical piston) responds via Coulomb interaction
- Self-Consistent Stationary State: Determined by quantum effects connecting broad classical regimes
Inverse-Engineering Protocol
- Quantum Regime Identification: Identify narrow quantum regime of ground state between classical regimes
- Trapping Potential Modulation: Control quantum ion motion through time-dependent trapping potential
- Coulomb-Mediated Transfer: Classical piston motion emerges from Coulomb coupling
- Protocol Design: Inverse-engineering approach to determine required control parameters for desired piston trajectory
Reusable Patterns
- Coulomb-mediated control transfer: Use Coulomb interaction as a transducer between quantum control and classical actuation
- Self-consistent quantum-classical coupling: Stationary states emerge from mutual influence, not one-way driving
- Inverse-engineering for microscopic devices: Work backwards from desired outcome to required control parameters
- Orthogonal-axis decoupling: Motion confinement to orthogonal axes simplifies control design
When to Use
- Trapped-ion quantum thermodynamics experiments
- Quantum heat engine design
- Microscopic piston dynamics in quantum devices
- Two-ion quantum systems with classical-quantum coupling
- Inverse-engineering protocols for quantum control
Key Results from Paper
- Identified narrow quantum regime connecting classical regimes
- Designed inverse-engineering protocols for controlled piston motion
- Provides useful route toward controlled piston dynamics in microscopic quantum devices
