Thiago V. Acconcia scite author profile

We present an analysis of the work performed on a system of interest that is kept thermally isolated during the switching of a control parameter. We show that there exists, for a certain class of systems, a finite-time family of switching protocols for which the work is equal to the quasistatic value. These optimal paths are obtained within linear response for systems initially prepared in a canonical distribution. According to our approach, such protocols are composed of a linear part plus a function which is odd with respect to time reversal. For systems with one degree of freedom, we claim that these optimal paths may also lead to the conservation of the corresponding adiabatic invariant. This points to an interesting connection between work and the conservation of the volume enclosed by the energy shell. To illustrate our findings, we solve analytically the harmonic oscillator and present numerical results for certain anharmonic examples.

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Shortcuts to adiabaticity from linear response theory

Acconcia

Bonança

Deffner

2015

Phys. Rev. E

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A shortcut to adiabaticity is a finite-time process that produces the same final state as would result from infinitely slow driving. We show that such shortcuts can be found for weak perturbations from linear response theory. With the help of phenomenological response functions, a simple expression for the excess work is found-quantifying the nonequilibrium excitations. For two specific examples, i.e., the quantum parametric oscillator and the spin 1/2 in a time-dependent magnetic field, we show that finite-time zeros of the excess work indicate the existence of shortcuts. Finally, we propose a degenerate family of protocols, which facilitates shortcuts to adiabaticity for specific and very short driving times.

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A very high momentum particle identification detector

et al. 2014

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The construction of a new detector is proposed to extend the capabilities of ALICE in the high transverse momentum (pT) region. This Very High Momentum Particle Identification Detector (VHMPID) performs charged hadron identification on a track-by-track basis in the 5 GeV/c < p < 25 GeV/c momentum range and provides ALICE with new opportunities to study parton-medium interactions at LHC arXiv:1309.5880v2 [nucl-ex] 24 Sep 2013 2 T. V. Acconcia et al.: A Very High Momentum Particle Identification Detector energies. The VHMPID covers up to 30% of the ALICE central barrel and presents sufficient acceptance for triggered-and tagged-jet studies, allowing for the first time identified charged hadron measurements in jets. This Letter of Intent summarizes the physics motivations for such a detector as well as its layout and integration into ALICE. PACS. 29.40.Ka Cherenkov detectors -25.75.-q Relativistic heavy-ion collisions ./

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Microcanonical Szilárd engines beyond the quasistatic regime

Acconcia

Bonança

2017

Phys. Rev. E

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We discuss the possibility of extracting energy from a single thermal bath using microcanonical Szilárd engines operating in finite time. This extends previous works on the topic which are restricted to the quasistatic regime. The feedback protocol is implemented based on linear response predictions of the excess work. It is claimed that the underlying mechanism leading to energy extraction does not violate Liouville's theorem and preserves ergodicity throughout the cycle. We illustrate our results with several examples including an exactly solvable model.

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VHMPID RICH prototype using pressurized C4F8O radiator gas and VUV photon detector

Acconcia

Agócs

Barile

et al. 2014

Nuclear Instruments and Methods in Physics Research Section A:

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