Isochoric Specific Heat in the Dual Model of Liquids

We continue in this paper to illustrate the implications of the dual model of liquids (DML) by deriving the expression for the isochoric specific heat as a function of the collective degree of freedom available at a given temperature and analyzing its dependence on temperature. Two main tasks have been accomplished. First, we show that the expression obtained for the isochoric specific heat in the DML is in line with the experimental results. Second, the expression has been compared with the analogous one obtained in another theoretical dual model of the liquid state, the phonon theory of liquid thermodynamics. This comparison allows providing interesting insights about the number of collective degrees of freedom available in a liquid and the value of the isobaric thermal expansion coefficient, two quantities that are related to each other in this framework.

SD-pair shell model: Vibrational and rotational limits in the interacting boson–fermion model for like-nucleon system

Typical features of the Bose–Fermi symmetries associated with [Formula: see text] and [Formula: see text] limits in the interacting boson model are described in the SD-pair shell model (SDPSM) framework for like-nucleon system. It is found that the limiting spectra associated with [Formula: see text] (vibrational) and [Formula: see text] (rotational) in the interacting boson–fermion model can be well reproduced in the SDPSM framework. It is shown that coupling of collective degree of freedom with the single-particle degree of freedom in the pairing interaction almost has no effect on the spectrum of odd-A system comparing to the adjacent even–even system, while the coupling of the collective degree of freedom with the single-particle degree of freedom in the quadrupole–quadrupole interaction results in the level splitting of several excited levels.

Compliance analysis of pedestrian facilities with accessibility requirements

State and local governments are required by law to provide and maintain accessibility on their pedestrian facilities. They need to conduct, document, and update self-evaluations to identify non-compliant pedestrian facilities. This paper presents the development of a novel model for analyzing the compliance of pedestrian facilities with accessibility requirements. The model provides original and unique capabilities that enable decision-makers to: (i) quantify the degree of non-compliance of all types of pedestrian facilities including transit stops, on-street parking, and passenger loading zones; (ii) estimate cost and labour-hours needed to achieve compliance; (iii) prioritize upgrade projects for pedestrian facility types; (iv) rank pedestrian facilities upgrade projects in multiple geographical regions based on their collective degree of non-compliance; and (v) classify pedestrian facilities based on the type of required upgrade. A case study that includes 1327 pedestrian facilities is analyzed to evaluate the performance of the developed model and illustrate its capabilities.

FRACTIONAL STATISTICS ON COMPACT SURFACES

General kinematical restrictions on quantum-theories of N identical anyons have been established by using braid groups. For an orientable compact surface (without boundary) of genus g, the statistical parameter θ is a rational multiple of π, θ=πp/v (p and v mutually prime integers), and the number of components of the wavefunction is (a multiple of) vg. The particle-number is N=rv+1−g (r integer) for spinless (S=0) and N=rv for spinning (S=θ/2π) anyons. The restrictions for spinning anyons are consistent with results for fractional quantum Hall systems, nonlinear O(3) field theory, and Chern-Simons theory. The multi-component structure, which appears for g≥1, reflects an internal collective degree of freedom. A comparison with the multi-component wavefunctions needed to describe systems with fractionally charged quasi-particles yields consistency relations between charge and statistics. Non-orientable surfaces do not allow fractional statistics.