Search results for "Particle number operator"

showing 4 items of 4 documents

Non-hermitian operator modelling of basic cancer cell dynamics

2018

We propose a dynamical system of tumor cells proliferation based on operatorial methods. The approach we propose is quantum-like: we use ladder and number operators to describe healthy and tumor cells birth and death, and the evolution is ruled by a non-hermitian Hamiltonian which includes, in a non reversible way, the basic biological mechanisms we consider for the system. We show that this approach is rather efficient in describing some processes of the cells. We further add some medical treatment, described by adding a suitable term in the Hamiltonian, which controls and limits the growth of tumor cells, and we propose an optimal approach to stop, and reverse, this growth.

General Physics and Astronomylcsh:AstrophysicsTumor cells01 natural sciencesArticle010305 fluids & plasmassymbols.namesakeOperatorial models; Schrödinger dynamics; non Hermitian Hamiltonian; Tumoral proliferation modelSchrödinger dynamicParticle number operatorlcsh:QB460-4660103 physical scienceslcsh:Science010306 general physicsSettore MAT/07 - Fisica MatematicaMathematical physicsPhysicsMedical treatmentOperatorial modelOther Quantitative Biology (q-bio.OT)Non hermitian HamiltonianTumoral proliferation modelQuantitative Biology - Other Quantitative Biologylcsh:QC1-999Birth–death processFOS: Biological sciencesSchrödinger dynamicsCancer cellsymbolslcsh:QOperatorial modelsHamiltonian (quantum mechanics)lcsh:PhysicsSelf-adjoint operator
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A PHENOMENOLOGICAL OPERATOR DESCRIPTION OF INTERACTIONS BETWEEN POPULATIONS WITH APPLICATIONS TO MIGRATION

2013

We adopt an operatorial method based on the so-called creation, annihilation and number operators in the description of different systems in which two populations interact and move in a two-dimensional region. In particular, we discuss diffusion processes modeled by a quadratic hamiltonian. This general procedure will be adopted, in particular, in the description of migration phenomena. With respect to our previous analogous results, we use here fermionic operators since they automatically implement an upper bound for the population densities.

Heisenberg-like dynamicsComputer scienceApplied MathematicsPopulations and Evolution (q-bio.PE)FOS: Physical sciencesDynamics of competing populations with diffusion; Fermionic operators; Heisenberg-like dynamicsUpper and lower boundssymbols.namesakeQuadratic equationOperator (computer programming)Biological Physics (physics.bio-ph)Particle number operatorFOS: Biological sciencesModeling and SimulationsymbolsPhysics - Biological PhysicsStatistical physicsQuantitative Biology - Populations and EvolutionHamiltonian (quantum mechanics)Settore MAT/07 - Fisica MatematicaDynamics of competing populations with diffusionquantum tools for classical systemsFermionic operatorsMathematical Models and Methods in Applied Sciences
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Traces of symmetry-adapted reduced density operators

1990

Formulae are derived for traces of symmetry-adapted reduced density operators in a finite-dimensional, antisymmetric and spin-adapted space. The traces are expressed in terms of traces of products of the orbital occupation number operators.

Particle number operatorAntisymmetric relationSpin systemGeneral Physics and AstronomyStatistical and Nonlinear PhysicsGeometryEigenfunctionSpace (mathematics)Mathematical PhysicsSymmetry (physics)Mathematical physicsMathematicsJournal of Physics A: Mathematical and General
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A Phenomenological Operator Description of Dynamics of Crowds: Escape Strategies

2015

Abstract We adopt an operatorial method, based on creation, annihilation and number operators, to describe one or two populations mutually interacting and moving in a two-dimensional region. In particular, we discuss how the two populations, contained in a certain two-dimensional region with a non-trivial topology, react when some alarm occurs. We consider the cases of both low and high densities of the populations, and discuss what is changing as the strength of the interaction increases. We also analyze what happens when the region has either a single exit or two ways out.

Physics - Physics and Societybusiness.industryApplied MathematicsFOS: Physical sciencesFermionic operatorHeisenberg-like dynamicPhysics and Society (physics.soc-ph)Escape strategieApplied MathematicDynamics of crowdOperator (computer programming)CrowdsParticle number operatorDynamics (music)Modeling and SimulationArtificial intelligenceStatistical physicsbusinessFermionic operators Heisenberg-like dynamics Dynamics of crowds Escape strategiesSettore MAT/07 - Fisica MatematicaTopology (chemistry)Mathematics
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