Superfocusing of channeled protons and subatomic measurement resolution

Petrović, S.; Nešković, N.; Berec, Vesna; Ćosić, Marko

doi:10.1103/physreva.85.032901

Cited by 11 publications

(17 citation statements)

References 41 publications

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“…Further calculations take into account the proton beam divergence before its interaction with the crystal [24] , [25] .…”

Section: Resultsmentioning

confidence: 99%

“…Figure 1 ( a (1, 2), b (1, 2), c (1, 2)) gives 3-d representation of channeled protons contour plots for 92 nm Si nanocrystal, Λ = 0.5 [24] , [25] , for tilt angles: φ = 0.05 ψ c , φ = 0.15 ψ c and φ = 0.20 ψ c , is the angle of external field relative to symmetry axis of the spin transformation tensor. The external field of 1 MeV is chosen to match the limits of Bohr radius with initial CP peak separation at 20% of the critical angle (relative to tensor principal axis).…”

Section: Discussionmentioning

confidence: 99%

“…The channeled proton distributions are mapped in configuration space and angular space in two steps: to transverse position phase plane, and to scattering angle phase plane, [24], [25] in accordance with the chosen value of reduced crystal thickness, Λ and the tilt angle, φ .…”

Section: Methodsmentioning

confidence: 99%

“…Simulation model considers cubic unit cell representation of the isotopically pure 29 Si nanocrystal. It includes atomic strings on three nearest square coordination lines of the axial channel [24] , [25] . According to diamond lattice symmetry, the orthogonal mesh is projected across the channel, mapping two layers of 2×2 triangular areas of unit cell.…”

Section: Methodsmentioning

confidence: 99%

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Quantum Entanglement and Spin Control in Silicon Nanocrystal

Berec

2012

PLoS ONE

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Selective coherence control and electrically mediated exchange coupling of single electron spin between triplet and singlet states using numerically derived optimal control of proton pulses is demonstrated. We obtained spatial confinement below size of the Bohr radius for proton spin chain FWHM. Precise manipulation of individual spins and polarization of electron spin states are analyzed via proton induced emission and controlled population of energy shells in pure 29Si nanocrystal. Entangled quantum states of channeled proton trajectories are mapped in transverse and angular phase space of 29Si axial channel alignment in order to avoid transversal excitations. Proton density and proton energy as impact parameter functions are characterized in single particle density matrix via discretization of diagonal and nearest off-diagonal elements. We combined high field and low densities (1 MeV/92 nm) to create inseparable quantum state by superimposing the hyperpolarizationed proton spin chain with electron spin of 29Si. Quantum discretization of density of states (DOS) was performed by the Monte Carlo simulation method using numerical solutions of proton equations of motion. Distribution of gaussian coherent states is obtained by continuous modulation of individual spin phase and amplitude. Obtained results allow precise engineering and faithful mapping of spin states. This would provide the effective quantum key distribution (QKD) and transmission of quantum information over remote distances between quantum memory centers for scalable quantum communication network. Furthermore, obtained results give insights in application of channeled protons subatomic microscopy as a complete versatile scanning-probe system capable of both quantum engineering of charged particle states and characterization of quantum states below diffraction limit linear and in-depth resolution.PACS numbers: 03.65.Ud, 03.67.Bg, 61.85.+p, 67.30.hj

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“…Further calculations take into account the proton beam divergence before its interaction with the crystal [24] , [25] .…”

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Quantum Entanglement and Spin Control in Silicon Nanocrystal

Berec

2012

PLoS ONE

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“…Besides its theoretical significance, the rainbow effect has a number of practical uses. It was used to extract the correct proton-Si interaction potential [19], and there is also suggestion to be employed for production of the ion beams focused to the subatomic precision [20]. A new method for characterization of the short SWCNTs proposed in the Refs.…”

Section: Introductionmentioning

confidence: 99%

Quantum Rainbows in Positron Transmission through Carbon Nanotubes

Ćosić

Petrović

Nešković

2019

Atoms

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Here we report the results of the theoretical investigation of the transmission of channeled positrons through various short chiral single walled carbon nanotubes (SWCNT). The main question answered by this study is "What are the manifestations of the rainbow effect in the channeling of quantum particles that happens during the channeling of classical particles?" To answer this question, the corresponding classical and quantum problems were solved in parallel, critically examined, and compared with each other. Positron energies were taken to be 1 MeV when the quantum approach was necessary. The continuum positron-nanotube potential was constructed from the thermally averaged Molière's positron-carbon potential. In the classical approach, a positron beam is considered as an ensemble of noninteracting particles. In the quantum approach, it is considered as an ensemble of noninteracting wave packages. Distributions of transmitted positrons were constructed from the numerical solutions of Newton's equation and the time-dependent Schrödinger equation. For the transmission of 1-MeV positrons through 200-nm long SWCNT (14;4), in addition to the central maximum, the quantum angular distribution has a prominent peak pair (close to the classical rainbows) and two smaller peaks pairs. We have shown that even though the semiclassical approximation is not strictly applicable it is useful for explanation of the observed behavior. In vicinity of the most prominent peak, i.e., the primary rainbow peak, rays interfere constructively. On one of its sides, rays become complex, which explains the exponential decay of the probability density in that region. On the other side, the ray interference alternates between constructive and destructive, thus generating two observed supernumerary rainbow peaks. The developed model was then applied for the explanation of the angular distributions of 1-MeV positrons transmitting through 200 nm long (7, 3), (8, 5), (9, 7), (14, 4), (16, 5) and (17, 7) SWCNTs. It has been shown that this explains most but not all rainbow patterns. Therefore, a new method for the identification and classification of quantum rainbows was developed relying only on the morphological properties of the positron wave function amplitude and the phase function families. This led to a detailed explanation of the way the quantum rainbows are generated. All wave packets wrinkle due to their internal focusing in a mutually coordinated way and are concentrated near the position of the corresponding classical rainbow. This explanation is general and applicable to the investigations of quantum effects occurring in various other atomic collision processes.

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