Programmable architecture for quantum computing

Chen, Jialin; Wang, Lingli; Charbon, Edoardo; Wang, Bin

doi:10.1103/physreva.88.022311

Cited by 12 publications

(9 citation statements)

References 29 publications

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“…at the detection time t d around the mean value I d (t d ) , at each detector d = C, T , can be measured by using single-photon detectors with integration time δt 1/∆ω [53,54]. One can than evaluate the correlation in the intensity fluctuations at the two output ports [53,54,5]…”

Section: Thermal Light Interference "Beyond Coherence"mentioning

confidence: 99%

The physics of thermal light second-order interference beyond coherence

Tamma¹

2018

Phys. Scr.

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A novel thermal light interferometer was recently introduced in Ref.[1]. Here, two classically correlated beams, obtained by beam splitting a thermal light beam, propagate through two unbalanced Mach-Zehnder interferometers. Remarkably, second-order interference between the long and the short paths in the two interferometers was predicted independently of how far, in principle, the length difference between the long and short paths is beyond the coherence length of the source. This phenomenon seems to contradict our common understanding of secondorder coherence. We provide here a simple description of the physics underlying this effect in terms of two-photon interference.

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Section: Thermal Light Interference "Beyond Coherence"mentioning

confidence: 99%

The physics of thermal light second-order interference beyond coherence

Tamma¹

2018

Phys. Scr.

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“…This system was obtained after calculating the C a (t),C b (t),C 1 (t), ...C N (t) coordinates of |Ψ(t) on the canonical basis set, after taking into account the symmetry of the A − N − B system i.e. C 1 (t) = C 2 (t) = ... = C N (t) = C(t) and finally after performing the transformatioñ C(t) = √ NC(t) as implemented in [2]. After solving (3) analytically, the variation in time of the |φ b population amplitude is given by:…”

Section: ) Spectral Analysis and Time Dependent Heisenberg-rabi Oscimentioning

confidence: 99%

“…In this case, the N 2 law is no more valid with a saturation of T (E f , N) 1 whatever the large N values and a decreasing of T (E f , N) 2 for large N after its saturation to unity. T (E f , N) 2 In Figure (5), the range of the N 2 law validity is presented by plotting the…”

Section: )The Parallel Quantum Circuit Lawmentioning

confidence: 99%

“…Installing a quantum transfer line in between two identical A and B quantum systems opens the possibility to transfer from A to B one electron added to A because of the electronic coupling introduced between A and B by this line [1,2]. To increase the chance for this electron to be transferred, to speed up its transfer or to minimize the energy required, more transfer lines can be added in parallel forming a quantum bus between A and B [2]. In absence of electronic coupling between the lines, N identical lines in parallel must intuitively increase the V ab (N) coupling between state |φ a (electron on A) and state |φ b (the electron on B).…”

Section: ) Introductionmentioning

confidence: 99%

“…In absence of electronic coupling between the lines, N identical lines in parallel must intuitively increase the V ab (N) coupling between state |φ a (electron on A) and state |φ b (the electron on B). Quantifying the V ab (N) power law of this superposition and measuring it experimentally are long standing problems [1,2]. A possible measure (i) is to perform a spectroscopy characterization of the A − N − B quantum system to follow how the free from bus |φ a , |φ b degeneracy is lifted up by the progressive insertion of N lines in parallel between A and B.…”

Section: ) Introductionmentioning

confidence: 99%

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Parallel Quantum Circuit in a Tunnel Junction

Namarvar

Dridi

Joachim

2016

Sci Rep

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Spectral analysis of 1 and 2-states per line quantum bus are normally sufficient to determine the effective Vab(N) electronic coupling between the emitter and receiver states through the bus as a function of the number N of parallel lines. When Vab(N) is difficult to determine, an Heisenberg-Rabi time dependent quantum exchange process must be triggered through the bus to capture the secular oscillation frequency Ωab(N) between those states. Two different linear and regimes are demonstrated for Ωab(N) as a function of N. When the initial preparation is replaced by coupling of the quantum bus to semi-infinite electrodes, the resulting quantum transduction process is not faithfully following the Ωab(N) variations. Because of the electronic transparency normalisation to unity and of the low pass filter character of this transduction, large Ωab(N) cannot be captured by the tunnel junction. The broadly used concept of electrical contact between a metallic nanopad and a molecular device must be better described as a quantum transduction process. At small coupling and when N is small enough not to compensate for this small coupling, an N2 power law is preserved for Ωab(N) and for Vab(N).

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