Dr. Dragos-Victor Anghel
Department of Theoretical Physics, Horia Hulubei National Institute
for Physics and Nuclear Engineering

Titlul: "Glassy properties of mesoscopic systems and disordered crystals"

Rezumat:

The low temp erature acoustic and thermal prop erties of amorphous, glassy materials are remarkably similar and they can b e explained to a large extent by assuming that the material contains a large numb er of dynamic defects. These dynamic defects are tunneling systems and are modeled by an ensemble of two-level systems (TLS) [1, 2]. Crystals with defects{with a large enough amount of disorder{exhibit also glass-like prop erties, but these prop erties are not so universal and, even more, they are not isotropic. In Ref. [3] we prop osed a mo del for the interaction of two-level systems with arbitrary strain elds, which we then applied to calculate the thermal properties and phonon scattering in nanoscopic membranes at low temp eratures [4]. Here we shall show how we apply the same mo del calculate the interaction between TLSs in amorphous materials and to explain the anisotropy of the glass-like prop erties of disordered crystals and [5, 6, 7, 8]
References

[1] W. A. Phillips, J. Low Temp. Phys. 7 , 351 (1972).
[2] P. W. Anderson, B. I. Halp erin, and C. M. Varma, Phil. Mag. 25, 1 (1972).
[3] D. V. Anghel, T. Kuhn, Y. M. Galp erin, and M. Manninen, Phys. Rev. B 75, 064202 (2007).
[4] T. Kuhn, D. V. Anghel, Y. M. Galp erin, and M. Manninen, Phys. Rev. B 76, 165425 (2007).
[5] D. V. Anghel and D. V. Churo chkin, Phys. Rev. B 78, 94202 (2008).
[6] D. V. Anghel and D. Churo chkin, Europhys. Lett. 83, 56004 (2008).
[7] D. V. Anghel and D. V. Churo chkin, J. Pyhs.: Conf. Series 150 , 012002 (2008).
[8] D. V. Anghel, Rom. J. Phys. 54 , 65 (2009).

Prof.  Liviu Movileanu^1,2
1Department of Physics, Syracuse University, 201 Physics Bldg., Syracuse, New York 13244-1130, USA
²Syracuse Biomaterials Institute, Syracuse University, 121 Link Hall, Syracuse, New York 13244, USA
E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

Titlul: "Engineered Nanopores for Single-molecule Science"

Abstract:

A nanopore may act as an amazingly versatile single-molecule probe that can be employed to reveal several important biophysical features of biomolecules. The underlying principle of nanopore probe techniques is outrageously simple: the application of a voltage bias across an electrically insulated membrane enables the measurement of a tiny picoamp-scale transmembrane current through a single hole of nanometer size, called a nanopore. Each molecule, translocating through the nanopore, produces a distinctive current blockade, the nature of which depends on its biophysical properties as well as the molecule-nanopore interaction. Such an approach proves to be quite powerful, because single small molecules and biopolymers are examined at very high spatial and temporal resolutions. I will discuss our recent work that provided a mechanistic understanding of the forces that drive translocation through a nanopore. These measurements facilitate the detection and exploration of the conformational fluctuations of single molecules and the energetic requirements for their transition from one state to another.

Dr M. Mirea, DFT IFIN

Titlul: "Masa efectiva cranking dependenta de energia de excitare."
Raport proiect IDEI 512

S-a obtinut o noua formula pentru masa efectiva cranking pornindu-se de la ecuatiile de imperechere dependente de timp. Cu acest formalism
se poate evidentia dependenta inertiei nucleare de energia de disipare. In aproximatia adiabatica, utilizand formalismul BCS, formula obtinuta se reduce la formula cranking clasica.

Dr. Cezar Condeescu, DFT

"D-brane models and non-perturbative vacuum destabilization"

Abstract.
Some general properties of models with magnetized/intersecting D-branes will be presented. In this context we consider non-perturbative effects generated by Euclidean brane instantons. We analyze the process of string vacuum destabilization due to instanton induced superpotential couplings which depend linearly on charged fields. These non-perturbative instabilities result in potentials for the D-brane moduli and lead to processes of D-brane recombination, motion and partial moduli stabilization at the non-perturbative vacuum. Phenomenological applications include breaking hidden sector gauge groups, open string moduli stabilization and supersymmetry breaking. The results suggest that breaking supersymmetry by Polonyi-like models in string theory is more difficult than expected.

Dr. Calin Lazaroiu, DFT

"String theory, D-branes, topological defects and higher categories"

Abstract.
Two-dimensional topological field theories with D-branes and/or with one-dimensional defects admit an axiomatic description which connects them to the formalism of ordinary and higher category theory.

Dr. Catalina Renata Jora
Grupul de Fizica Teoretica, Universitatea Autonoma din Barcelona (Spania)

Titlu: "An implementation of the permutation  symmetry into the electroweak theory"

Abstract:
Recent experimental data suggest that the leptonic mixing matrix, one of the chief unsolved problems in elementary particle physics, is very close to the so-called "tribimaximal form". Such a structure is natural in the context of permutation symmetry. Inspired by this we implement the S3 group as a zeroth order approximation into the electroweak theory and S2 subgroups of it as first order and second order perturbations.

Dr. Sabin Stoica

Raport Faza nr. 1/2011 in cadrul proiectului PN 09 37 01 06/2009

“Studiul fenomenelor fizice prin metode teoretice si computationale in domenii de frontiera”

Abstract:
In lipsa unor masuratori directe experimentale, valorile constantei de cuplaj a axionilor si a masei lor pot fi constranse la un interval de valori prin considerente astrofizice si  cosmologice. Limite inferioare pentru constanta de cuplaj a axionilor cu nucleonii se pot obtine si din cunoasterea ratelor de emisie a axionilor din stele neutronice, in procesul de racire a acestora. Obiectul fazei il constituie obtinerea de valori cat mai precise pentru ratele de emisie ale axionilor in stele neutronice din procese de bremsstrahlung nucleonic, prin includerea intr-un mod consistent a efectelor nucleare provenite din utilizarea unui potential nucleon-nucleon cu schimb de unul si doi pioni (OPEP si TPEP) in aproximatia Born.

Dr. Paula Gina Isar, Institute for Space Sciences, ISS, Bucharest,  Institute of Nuclear Physics KIT Karlsruhe

Titlul: "Ultra High Energy Cosmic Rays Physics: Status and Perspective"

Rezumat: Cosmic particles can reach breathtaking energies, far beyond reachable energies at manmade accelerators. Worldwide, different types of detectors have been deployed to facilitate their observations in different media (air, water, ice). However, items like, "from where do they come from, how do they survive to reach ground at such enormous energies, what can we learn from them", are only a few of the addressed questions in Ultra High Energy Cosmic Rays Physics. Status and perspective of this research field will be outlined in the talk.

ALGEBRAIC METHODS OF MANY-BODY SYSTEMS
Boyka Aneva Bulgarian Academy of Sciences


Sandpile models describing systems with self-organized criticality have received a lot of attention due to the wide range of applications in diverse areas. Despite of their simplicity, due to the large number of elements there  are difficulties in obtaining complete analytical solutions. However, the establishment of the Abelian property in the critical height models enhanced the derivation of some important results in the stationary state. In particular, the deterministic sandpile models were analytically solved by applying an Abelian algebra approach. It has been shown that they belong to a special universality class whose critical exponents are exactly known. Directed sandpile models with stochastic dynamics were studied as well. Numerical calculations have shown that they belong to a different universality class. A new approach to the analytical treatment of directed avalanches has recently been suggested. It is based on the study of directed Abelian algebras on two-dimensional acyclic lattices. We have applied this approach by using a simpler toppling rule which is more convenient for theoretical study to find the maximum current of particles at a given time and the maximum value of the height of each site.

Dr. Liliana Micu, DFT IFIN-HH

Titlul: A single-particle model for two-body systems and applications

Rezumat:
We develop a consistent single-particle model of two-body systems at the classical, quantum non-relativistic and quantum relativistic levels. The
model is based on the replacement of the two-body potential by two suitable single-particle potentials which demand the splitting of the Hamilton function in two similar single-particle Hamilton functions corresponding to the real particles in external potentials. The equations of motion are individually solved and, in order to yield the image of a bound system, the solutions are required to satisfy some constraints derived from Newton's laws. As a result, the system is represented by two real particles with correlated coordinates, individually bound to a centre of forces which coincides with the centre of mass and the sum of particle energies in the rest frame is equal to the energy of the particle with the reduced mass in the old representation. The quantization procedure is individually applied to the single-particle systems: the individual position and momentum variables are replaced by the corresponding operators and the particles are being assigned individual wave functions which satisfy similar Schroedinger equations. The wave function of the bound system is a suitable product of individual wave functions and the sum of the eigenvalues of the single-particle Hamiltonians is equal to the eigenvalue of the Hamiltonian associated with the particle with the reduced mass if the arguments of the solution to the two-body problem satisfy a constraint similar to the classical one. The model is easily extended to a relativistic level by replacing the kinetic terms in the individual Schroedinger Hamiltonian with free Dirac or Klein-Gordon Hamitonians. In this form the model enabled us to obtain the generic expressions of meson electromagnetic and semi-leptonic form factors assums of the individual contributions of the quark and of the antiquark.