Areas of Activity#

Here you will find all fields of scholarship for this section.This page is created automatically.

2

3
  • 3D auto-stereoscopic displays Go to
4
  • 4D Printing and Biomedical Devices Go to
A
  • Ab-initio molecular dynamics Go to
  • Accelerator based particle physics Go to
  • Accelerator engineering (superconducting cavities) Go to
  • Accelerator physics: design and construction Go to
  • Accelerator physics, superconducting cw electron accelerators and FELs Go to
  • Accelerators, ion sources and magnetic spectrometers Go to
  • Acoustic and elastic wave propagation phenomena (attentuation, dispersion, reflection/transmission, scattering, localization) Go to
  • Acoustic and electromagnetic emissions Go to
  • Acoustics Go to
  • Acoustics Go to
  • Active Deployable and Morphing Structures Go to
  • Active galactic nuclei Go to
  • Active materials Go to
  • Adaptive and robust control Go to
  • Adaptive and robust control Go to
  • Adaptive control Go to
  • Adiabatic expansions and asymptotic perturbation theory Go to
  • Adsorption Go to
  • Advanced discretization methods for fracture and fragmentation analysis Go to
  • Advances in microscopy Go to
  • Aerohydroelasticity Go to
  • Aerospace Go to
  • AEROSPACE, SOLID MECHANICS Go to
  • Aggregation phenomena Go to
  • Algebraic coding theory Go to
  • Algebraic description of high-angular momentum states in nuclei Go to
  • Algebraic scattering theory Go to
  • Algebraic structure models Go to
  • ALICE experiment at CERN LHC Go to
  • Alice experiment at LHC Go to
  • Analog and mixed-signal design automation (EDA) Go to
  • Analog and mixed-signal integrated circuit design Go to
  • Analysis of cultural heritage artifacts Go to
  • Analytical aspects of ion impact Go to
  • Analytical mechanics Go to
  • Antimatter physics Go to
  • Application of nuclear structure physics to nuclear technology, particularly, nuclear transmutation for radioactive waste Go to
  • Application of thermodynamics to phase transformations Go to
  • Applications in mechanical engineering: Go to
  • Applications of high intensity ion accelerators to fusion energy Go to
  • Applications of lasers in medicine Go to
  • Applications of new power devices Go to
  • Applications of nuclear methods in science and technology Go to
  • Applications of stretchable electronics: integration with humanbody for health monitoring Go to
  • Applied and translational life sciences Go to
  • Applied mathematical modelling Go to
  • Applied mathematical physics Go to
  • Applied mathematics Go to
  • APPLIED MATHEMATICS Go to
  • Applied mathematics Go to
  • Applied mathematics in information processing, social media, communication Go to
  • Applied physics Go to
  • APPLIED PHYSICS Go to
  • Applied physics: surface production of negative ions Go to
  • Aquatic filter feeding Go to
  • Architect Go to
  • Arterial wall mechanics Go to
  • Artificial muscles Go to
  • Astroparticle physics Go to
  • Astroparticle physics Go to
  • ASTROPARTICLE PHYSICS Go to
  • Astroparticle physics Go to
  • Astroparticle physics Go to
  • Astroparticle physics Go to
  • Astrophysical p-process Go to
  • Astrophysics Go to
  • Astrophysics Go to
  • Asymptotic methods on PDE's Go to
  • Atomic and molecular physics Go to
  • Atomic and molecular physics Go to
  • Atomic and molecular physics Go to
  • Atomic and molecular radiation physics; electron, chemical and plasma physics Go to
  • Atomic beam apparatus (Rabie Type) Go to
  • Atomic collision mechanisms Go to
  • Atomic collisions in solids Go to
  • Atomic layer-by-layer molecular beam epitaxy (ALL-MBE) Go to
  • Atomic, molecular and optical physics Go to
  • ATOMIC & MOLECULAR PHYICS Go to
  • ATOMIC & MOLECULAR PHYSICS Go to
  • atomic physics Go to
  • ATOMIC PHYSICS Go to
  • Atomic physics Go to
  • Atomic physics Go to
  • Atomic structure and properties of inter-crystalline interfaces Go to
  • Atom interferometry Go to
  • Atom interferometry Go to
  • Atom optics and ultra-cold atoms (1992-present) Go to
  • Audio signal processing Go to
  • Auroral acceleration Go to
  • AUTOMATIC CONTROL Go to
  • Automatic control plane for optical networks Go to
  • Axiomatic quantum field theory Go to
B
  • Bacterial biofilms Go to
  • Band structure of semicnductors also in presence of a strong magnetic field Go to
  • Band structures (pass-bands and band-gaps) and wave control in phononic crystals or periodic composite materials/structures Go to
  • Baryon and lepton number violation Go to
  • Basic properties of matter under extreme conditions Go to
  • Basic science of nuclear materials Go to
  • Beam dynamics Go to
  • Behavioural laws of solids and structural reliability Go to
  • Behaviour of vortex lines in liquid helium and of quantized flux lines in type II superconductors Go to
  • Beta decay and magnetic moment studies of mirror nuclei Go to
  • Bifurcation theory Go to
  • Big bang nucleosynthesis Go to
  • Big data analytics Go to
  • Bioconvective pattern formation in suspensions of swimming micro-organisms Go to
  • Bioelectromagnetics Go to
  • Biological and soft systems Go to
  • BIOLOGICAL FLUID DYNAMICS Go to
  • Biological materials Go to
  • Biological Networks Go to
  • BIOMECHANICS, CONTINUUM MECHANICS Go to
  • Biomechanics Go to
  • Biomechanics Go to
  • BIOMEDICAL PHYSICS Go to
  • Bio-medical signal processing Go to
  • Biomimetics Go to
  • Biosensor development Go to
  • Biotechnology and hybrid materials: photovoltaic applications Go to
  • Blood flow and wall shear stress in arteries Go to
  • Bose-Einstein condensation Go to
  • Bose Einstein condensation Go to
  • Bose-Einstein condensation of atomic gases Go to
  • Bose-Einstein condensation, ultra-cold atomic gases Go to
  • Boundary element method Go to
  • Boundary element methods (BEM) Go to
  • Bridges Go to
  • Brilliant and monochromatic gamma beam ( 0.2-20 MeV) for Nuclear Structure Go to
  • Brownian motors and relativistic Brownian motion and Relativistic Thermodynamics Go to
C
  • Carbon nanotubes Go to
  • Carrier dynamics in semiconductors Go to
  • Causal dynamical triangulations Go to
  • Cavity quantum electrodynamics Go to
  • CDM cosmology Go to
  • Cell locomotion in vitro Go to
  • Cell Mechanics Go to
  • Cellular neural/nonlinear networks Go to
  • CERAMIC COMPOSITE MATERIALS Go to
  • CERAMIC MATERIALS Go to
  • Ceramic science Go to
  • Channeling Go to
  • Chaos and turbulence Go to
  • Chaos communication Go to
  • Chaos Go to
  • Chaos recognition, control and synchronization Go to
  • Chaotic circuits Go to
  • Chaotic dynamics of nonlinear oscillators Go to
  • Chaotic scattering in Hamiltonian Systems Go to
  • Characterization of the mechanical behavior of materials under extreme conditions Go to
  • Charged particles penetration through solids Go to
  • Charge-exchange reactions Go to
  • Chemical kinetics and rate phenomena Go to
  • CHEMICAL PHYSICS Go to
  • Chiral symmetry and strange matter Go to
  • Circuits and systems design Go to
  • CIVIL ENGINEERING Go to
  • Civil engineering Go to
  • Classical and quantum fluid dynamics Go to
  • Classical and quantum magnetism and nanomagnetism Go to
  • Classical and quantum turbulence Go to
  • Classical mechanics Go to
  • Clean air technologies, air quality Go to
  • Cloud condensation nuclei Go to
  • Cluster dynamics of transient nucleation Go to
  • Cluster physics Go to
  • Code development Go to
  • Coevolutionary games Go to
  • Coherence and condensation in Condesed Matter Physics Go to
  • Coherent optics (1969-1971) Go to
  • Cold atom physics Go to
  • Cold fusion Go to
  • Cold molecules Go to
  • Collective excitation by ion impact Go to
  • Collective phenomena Go to
  • Collective phenomena in biological systems (flocking, oscillations, crowds) Go to
  • Collectivity Go to
  • Collider physics Go to
  • Collisions of nuclei at ultrarelativistic energies Go to
  • Colloid and interface science Go to
  • Colloid-polymer mixtures Go to
  • Color superconductivity Go to
  • Combustion diagnostics Go to
  • Cometary physics Go to
  • Communication networks Go to
  • Compact objects (white dwarfs, neutron stars, black holes) Go to
  • Compact stellar objects Go to
  • Complex correlated materials Go to
  • Complex Fluids Go to
  • Complex Hadamard matrices and applications Go to
  • Complex networks and its application in finance and biology Go to
  • Complex networks Go to
  • Complex networks Go to
  • Complex networks Go to
  • Complex networks Go to
  • Complex networks Go to
  • Complex oxides, high-temperature superconductors Go to
  • Complex systems and chaos Go to
  • Complex systems and networks Go to
  • Complex systems Go to
  • Complex systems Go to
  • Complex systems Go to
  • Composite fermions Go to
  • Composite materials and composite structures Go to
  • Composite materials and reinforced earth structures Go to
  • Composite Materials and Structures Go to
  • Composite materials Go to
  • Composite materials Go to
  • Composites Go to
  • Composition design of non-oxide based ceramics Go to
  • Compression methods Go to
  • Computational acoustics Go to
  • Computational condensed matter physics Go to
  • COMPUTATIONAL FLUID DYNAMICS Go to
  • Computational fluid dynamics Go to
  • Computational fluid dynamics Go to
  • Computational fluid dynamics, heat transfer and combustion Go to
  • Computational intelligence Go to
  • Computational materials engineering Go to
  • Computational materials science Go to
  • Computational mechanics (boundary element method, smoothed/extended finite element method, meshless methods, etc.) Go to
  • Computational mechanics, boundary elements and meshless methods Go to
  • Computational mechanics (finite element methods, boundary element methods and combination of them) Go to
  • Computational mechanics Go to
  • Computational mechanics Go to
  • COMPUTATIONAL MECHANICS Go to
  • Computational mechanics Go to
  • Computational mechanics of materials and structures Go to
  • Computational methods for life-time analyses of concrete and reinforced concrete structures Go to
  • Computational methods for subsurface engineering and tunneling Go to
  • COMPUTATIONAL PHYSICS Go to
  • Computational physics Go to
  • Computational physics Go to
  • Computational physics Go to
  • Computational physics Go to
  • Computational Physics with focus on method development Go to
  • COMPUTATIONAL SCIENCE Go to
  • Computational system biology Go to
  • Computer-aided design (CAD) of electronic circuits Go to
  • Computer graphics Go to
  • COMPUTING, ENGINEERING Go to
  • Concept of an energy amplifier Go to
  • Concrete structures Go to
  • Condensed matter physics Go to
  • Condensed matter physics Go to
  • Condensed matter physics Go to
  • Condensed matter physics Go to
  • Condensed matter physics Go to
  • Condensed matter physics Go to
  • Condensed matter physics (mainly semiconductors – both theory and experiment, particularly physics of defects in semiconductors, recombination phenomena and the physics of junctions) Go to
  • Condensed matter physics-surface Go to
  • Condensed matter physics - theory and experiment Go to
  • CONDENSED MATTER THEORY Go to
  • Condensed systems of lower dimensionality-quantum size effect Go to
  • Confinement phenomenology: color ropes, GEP, EOS Go to
  • Constitutive (multi-scale) modeling of biosolids Go to
  • Construction and operation of large particle detector systems for studying electron-positron collisions Go to
  • Construction, modernization and renovation of urban underground infrastructure Go to
  • Contact mechanics Go to
  • Contact problems Go to
  • Continuum mechanics and mechanics of materials Go to
  • Continuum mechanics Go to
  • Continuum mechanics Go to
  • Continuum theories of condensation Go to
  • Contributions in theory, but mostly experimental Go to
  • Controlled waveforms of laser light Go to
  • Control of chaos Go to
  • Control of energy conversion systems Go to
  • Control of quantum transport Go to
  • Control-oriented systems modeling Go to
  • CONTROL THEORY Go to
  • Correlated systems Go to
  • Cosmic matter-antimatter asymmetry Go to
  • Cosmic rays Go to
  • Cosmic rays Go to
  • Cosmic Rays up to the highest energies Go to
  • Cosmology Go to
  • Crack tip field displacement mapping and crack tip residual stress interactions Go to
  • Creep Go to
  • Critical phenomena and field theoretic renormalization group on arbitrary networks Go to
  • Critical phenomena, disorder effects in statistical mechanics Go to
  • Critical Point Go to
  • Cross effects between mechanical and magnetic properties in metallic glasses Go to
  • Cryogenic detectors of particles and weak forces Go to
  • Crystal chemistry of non-oxide based ceramics Go to
  • Crystallography of inorganic compounds Go to
D
  • Damage and failure Go to
  • Damage mechanics of fiber composites Go to
  • Damage process of pressure vessels and pipe-line steels Go to
  • Dark Energy Go to
  • Dark Matter Go to
  • Dark matter in the universe Go to
  • Data analysis of rare events in environmental sciences and climatology Go to
  • Data-based control design Go to
  • Decay of compound nucleus Go to
  • Degradation of materials Go to
  • Delay-differential equations Go to
  • Dense hadronic matter and QCD phase transitions, Go to
  • Dense matter in supernovae, thermodynamics of atomic nuclei, nuclear collisions Go to
  • Dense nuclear matter Go to
  • Density functional theory Go to
  • DESIGN IN NATURE, THERMODYNAMICS Go to
  • Design of integrated and smart sensor interfaces Go to
  • Design of integrated data converters (ADC and DAC) Go to
  • Design of ultra low power CMOS circuits Go to
  • Detector development (Calorimetry, Cherenkov detectors, RICH, photon sensors) Go to
  • Detector development (hadron calorimeter) Go to
  • Detector developments at Ultra High Vacuum (UHV) Go to
  • Detectors for particle physics experiments Go to
  • Determining the fundamental laws of nature Go to
  • Determining the fundamental particles of the universe Go to
  • Deterministic 3D assembly: using buckling to fabricate 3D structures from 2D platforms Go to
  • Developing analysis techniques for various experiments Go to
  • Development of laser-based spectroscopic detection techniques Go to
  • Development of laser-driven brilliant X-ray & particle sources Go to
  • Development of macroscopic or continuum models of populations of biologicalorganisms whose individual, microscopic behaviour is random and whose environment may also be random Go to
  • Development of new detectors for applications in nuclear and high energy physics experiments Go to
  • Development of new research tools Go to
  • Development of new techniques for medical imaging Go to
  • Development of new technologies for renewable energy sources Go to
  • Development of novel theoretical tools and computational codes to investigate the electronic response of solids and nanostructures to external electromagnetic fields Go to
  • Development of spintronics Go to
  • Device physics, Josephson junctions, electrolyte field effect transistors Go to
  • Diagrammatic perturbation theory as applied to condensed matter systems Go to
  • Differentiable dynamical systems Go to
  • Differential equations Go to
  • Diffraction in high energy physics Go to
  • Diffusional phase transformations Go to
  • Digital communications Go to
  • Digital delta-sigma modulation Go to
  • Digital filters and switched-capacitor filters Go to
  • Digital geometry Go to
  • Digitally-assisted analog circuit design Go to
  • Digital Photon Correlators Go to
  • Digital signal processing Go to
  • Digital television standards Go to
  • Diluted Magnetic Semiconductors Go to
  • Dilute magnetic semiconductors Go to
  • Direct nuclear reactions Go to
  • Discontinuous stabilization Go to
  • Discovery of jet quenching in a strongly interacting Quark-Gluon Plasma Go to
  • Discovery of the Giant Magnetoresistance Go to
  • Dislocation dynamics Go to
  • Disordered systems Go to
  • Dissipative quantum systems Go to
  • Dosimetry of ionising radiation Go to
  • Dynamical density functional theory of crystal nucleation, growth, and pattern formation Go to
  • Dynamical mean-field theory Go to
  • Dynamical modelling in biology: ecology, neurodynamics Go to
  • Dynamical super-symmetries Go to
  • Dynamical symmetries at the critical point of phase transitions Go to
  • Dynamical symmetries Go to
  • Dynamical systems Go to
  • Dynamical systems with delay Go to
  • Dynamic contact problems Go to
  • Dynamic deformation Go to
  • Dynamic optimization and feedback control design methods Go to
  • DYNAMICS Go to
  • Dynamics of 3He and 4He small droplets Go to
  • Dynamics of clusters in strong fields Go to
    • Implementation of (semi-classical) kinetic theories for clusters
    • Numerical realization of time-dependent density functional theory for highly non-linear processes
    • Analysis of electron emission in terms of photo-electron spectra and angular distributions
    • Dissipative processes and stochastic extension of time-dependent mean-field theory
  • Dynamics of complex systems, especially finite fermion systems (nuclei, nano-particles) Go to
  • Dynamics of interfaces and fronts Go to
  • Dynamics of viscous compressible liquid Go to
E
  • EARTHQUAKE ENGINEERING Go to
  • Earthquake engineering Go to
  • Earth’s magnetosphere Go to
  • Economy and financial markets Go to
  • Econophysics and financial mathematics Go to
  • Effective field theories Go to
  • Effective filed theory Go to
  • Effective theories of the strong interaction Go to
  • Effects of air quality on health Go to
  • Elastic, inelastic scattering and transfer reactions with nuclear (stable and radioactive) beams Go to
  • Elastodynamics and structural dynamics (impact loading, dynamic effects, vibration isolation, vibration control, etc.) Go to
  • Electrical and electronic engeneering and biomedical engineering Go to
  • Electrical engineering and computer science Go to
  • ELECTRICAL ENGINEERING Go to
  • Electric fields in space plasma Go to
  • Electric power grid Go to
  • Electromagnetic calorimeter Go to
  • Electromagnetics Go to
  • Electron conversion measurements Go to
  • Electronic and thermal transport Go to
  • Electronic correlation effects and cooperative phenomena in thin films and nanostructures Go to
  • Electronic structure Go to
  • Electronic structure of metals and semiconductors Go to
  • Electronic structure of solids Go to
  • Electron microscopy Go to
  • Electron microscopy Go to
  • Electron Pumping Go to
  • Electron scattering Go to
  • Elemental trace analysis Go to
  • ELEMENTARTY PARTICLE PHYSICS Go to
  • Elementary particle physics (electron and neutron scattering) Go to
  • Elementary particle physics Go to
  • Elementary particle physics Go to
  • Elementary particle physics Go to
  • Elementary particles Go to
  • Energy and climate change policy Go to
  • Energy and sustainability questions, in particular the future role of advanced nuclear options Go to
  • Energy density functional theory Go to
  • Energy density functional theory Go to
  • Energy economics Go to
  • Energy, environmental, health, and other industrial technologies Go to
  • Energy: high capacity hydrogen storage-supercapacitors Go to
  • Energy physics Go to
  • Energy production and use and its impact on society and the environment Go to
  • Energy storage, conversion, and harvesting Go to
  • Energy use in buildings Go to
  • ENGINEERING Go to
  • Engineering Go to
  • ENGINEERING, MATERIAL SCIENCES Go to
  • ENGINEERING MECHANICS Go to
  • ENGINEERING SCIENCE Go to
  • Engineering sciences Go to
  • Environmental fluid mechanics Go to
  • Epidemiology Go to
  • Epitiaxial graphene based RF transistors Go to
  • Equation of state at supranuclear densities and high temperatures Go to
  • Equations of motion of mechanical systems Go to
  • Equilibrium statistical mechanics (rigorous) Go to
  • EUV/X-ray spectroscopy Go to
  • Evidence based policy making Go to
  • Evolutionary game theory Go to
  • Evolution of galaxies Go to
  • Exact solutions of hydrodynamics Go to
  • Excitonic solar cells Go to
  • Excitons, polaritons and microcavities Go to
  • Exotic nuclear decays Go to
  • Exotic Nuclei Go to
  • Exotic nuclei Go to
  • Exotic nuclei - halo phenomena Go to
  • Experimental and computational biomechanics and mechanobiology Go to
  • Experimental and theoretical research in condensed matter physics (metals, magnetism, magnetic nanostructures, spin electronics) Go to
  • Experimental and theoretical studies of superfluidity, superconductivity, fluid dynamics, and the properties of two-dimensional systems Go to
  • Experimental condensed matter physics Go to
  • Experimental high energy physics Go to
  • Experimental mechanics Go to
  • Experimental methods Go to
  • Experimental methods Go to
  • Experimental nuclear physics and applied areas (heavy-ion driven material science, proton and hadron therapy, radio-isotopes) Go to
  • Experimental nuclear physics and nuclear astrophysics, with expertise in nuclear structure and nuclear reactions Go to
  • EXPERIMENTAL NUCLEAR PHYSICS Go to
  • Experimental nuclear physics Go to
  • Experimental nuclear physics Go to
  • Experimental particle physics Go to
  • Experimental photon statistics Go to
  • Experimental physics Go to
  • EXPERIMENTAL PHYSICS Go to
  • Experimental physics Go to
  • Experimental plasma physics Go to
  • Experimental quantum optics Go to
  • Experimental soft matter physics (surfactants, liquid cystals, polymers, nanoparticles) Go to
  • Experimental solid state physics Go to
  • Experiment design Go to
  • Exploration and exploitation of intense-laser-matter interactions Go to
  • Exploring the high energy frontier Go to
  • Explosive events in astrophysics (novae, X-ray / Gamma-ray bursts, type Ia / core collapse supernovae, neutron star mergers) Go to
  • Extended systems: solids, liquids, Applications (e. g. photovoltaics) Go to
  • Extensions of the Standard Model Go to
F
  • Fallback Disks: Go to
    • Evolution of young neutron stars
  • Fatigue, fracture and creep of engineering solids Go to
  • Fatigue Go to
  • Fatigue Go to
  • Femto- and atto-second technology Go to
  • Femtoscopy, particle correlations, Bose-Einstein correlations, Go to
  • Ferroelectrics Go to
  • Few-body physics Go to
  • Few-body physics Go to
  • Few-body theory Go to
  • Fiber composites, with applications to car crashworthiness, ships and aircraft Go to
  • Fiber lasers Go to
  • Fibres Go to
  • Field theory and neural networks Go to
  • Film flows, Wetting and Spreading Dynamics Go to
  • Finite element analysis Go to
  • Finite element method Go to
  • Finite wordlength effects in signal processing and control Go to
  • Fish swimming Go to
  • Flow and self-excited oscillations in collapsible tubes Go to
  • Fluctuation analysis in stock exchanges (econophysics) Go to
  • Fluid dynamics Go to
  • FLUID DYNAMICS Go to
  • Fluid dynamics in geophysics and astrophysics Go to
  • Fluid mechanics Go to
  • Fluid mechanics Go to
  • FLUID MECHANICS Go to
  • Fluid Mechanics Go to
  • Fluid mechanics Go to
  • Fluid mechanics of buildings Go to
  • Force control Go to
  • Formation and development of collective anisotropic flow in A+A collisions Go to
  • Formation of pollutants in combustion, NOx and particles Go to
  • Foundations of Many-Body Theory Go to
  • Foundations of quantum mechanics and quantum entanglement Go to
  • Foundations of quantum mechanics Go to
  • Foundations of quantum theory Go to
  • Foundations of time-dependent density functional theory Go to
  • Fractal growth Go to
  • Fractals in physics Go to
  • Fractal structures in nonlinear dynamics: fractal basins, Wada basins, basin entropy Go to
  • Fractal techniques in engineering Go to
  • Fractional calculus Go to
  • Fracture and damage mechanics, and fatigue analysis of engineering materials, components and structures Go to
  • Fracture and material failure of biological tissues Go to
  • Fracture Go to
  • Fracture Go to
  • Fracture mechanics Go to
  • Fracture mechanics Go to
  • Fracture mechanics Go to
  • Fracture mechanics Go to
  • Fracture mechanics Go to
  • Fracture mechanics Go to
  • Fracture mechanics Go to
  • Fracture of brittle and ductile materials, the glass transition Go to
  • Fragmentation, comminution, drilling, and wear Go to
  • Freeze-out of hadrons in heavy ion collisions Go to
  • Frequency synthesis Go to
  • Front-end micro-electronics and data acquisition and storage Go to
  • Front propagation into unstable states Go to
  • Fuel cell technology Go to
  • Fullerenes Go to
  • Functional analysis Go to
  • Functional analysis, spectral theory Go to
  • Functional-integral methods Go to
  • Functional nanomaterials and devices Go to
  • Fundamental interactions in nuclear transitions Go to
  • Fundamental quantum properties Go to
  • Fundamental studies of phase transitions, relaxation dynamics of magnetic excitations on macroscopic, mesoscopic and nanoscopic scales Go to
  • Fundamental symmetries and constants Go to
  • FUSION ENERGY Go to
  • Fusion energy Go to
  • Fusion plasma diagnostics Go to
  • Fusion plasma physics Go to
  • Fusion power plants Go to
  • Fusion research Go to
  • Future integrated circuits and systems Go to
G
  • Gallium nitride Go to
  • Game theory Go to
  • Gamma-ray spectroscopy Go to
  • Gamma spectroscopy Go to
  • Gamma spectroscopy Go to
  • Gas flow and mixing in pulmonary airways Go to
  • Gas-phase molecular physics Go to
  • General energy issues Go to
  • General relativity and field theory Go to
  • General relativity Go to
  • Generation if high phase space density ion beams Go to
  • Generation of elements and isotopes in stable or explosive (nuclear) burning of matter, Go to
  • Generation of highly ionized ions in plasmas Go to
  • Geoenvironmental engineering Go to
  • Geographical information systems Go to
  • Geological disposal of high level nuclear waste Go to
  • Geomagnetism Go to
  • Geometric control theory Go to
  • Geophysics Go to
  • Geophysics Go to
  • g-factor measurements Go to
  • Giant resonances Go to
  • Giant resonances, neutron-skin thickness measurements Go to
  • Global transport processes Go to
  • Go to
  • Grand unification Go to
  • GRANULAR ELECTRONIC MATERIALS Go to
  • Granular media Go to
  • Graphene and other two-dimensional crystals Go to
  • Graphene Go to
  • Graphene Go to
  • Graphene Go to
  • Graphene Go to
  • Graphene Go to
  • Graphics recognition Go to
  • Gravitational physics Go to
  • Gravitational wave detectors Go to
  • Gravitation and cosmology Go to
  • Gravity waves Go to
  • Ground energy problems - ground source heat Go to
  • Group theory, band structure, phonon spectra, ionic cohesion Go to
  • Group theory Go to
  • Growth and preferential attachment Go to
  • Growth and remodeling of biosolids Go to
H
  • Hadrochemistry: strangeness, kinetic and transport models Go to
  • Hadronic physics 3-dimensional (3D) Tomography of the nucleus Go to
  • Hadronic physics problems studied with electrons, muons, pions and protons Go to
  • Hadronic reactions (nucleon-nucleon, hyperon-nucleon and meson-nucleon interactions) Go to
  • Hadronization and hadroproduction in high energy collisions Go to
  • Hadron Physics Go to
  • HADRON PHYSICS Go to
  • Hadron structure Go to
  • Halo nuclei and reaction mechanisms Go to
  • Hanbury Brown - Twiss effect in high energy physics, pion lasers Go to
  • Hard metals and stainless steels Go to
  • Heating of fusion plasma Go to
  • HEAT TRANSFER AND COMBUSTION Go to
  • Heavy flavor productions in high-energy nuclear collisions Go to
  • Heavy ion collisions and phenomenology Go to
  • Heavy ion collisions at ultra-relativistic energies Go to
  • Heavy Ion collisions Go to
  • Heavy ion elastic and inelastic scattering Go to
  • Heavy-ion Phenomenology Go to
  • Heavy-ion physics Go to
  • HEAVY ION PHYSICS Go to
  • Heavy-ion physics Go to
  • Heavy-Ion physics Go to
  • Heliosphere/Cosmic Rays Go to
  • High-energy heavy-ion collisions Go to
  • High energy heavy ion physics (both theory and experiment) Go to
  • High-energy heavy-ion physics Go to
  • High energy nuclear collision Go to
  • High-energy nuclear collisions and emergent properties of QCD Go to
  • HIGH ENERGY NUCLEAR PHYSICS Go to
  • High energy nuclear physics Go to
  • HIGH ENERGY PARTICLE AND HEAVY ION COLLISIONS Go to
  • High energy particle physics (both theory and experiment) Go to
  • High energy physics Go to
  • High-energy physics Go to
  • HIGH ENERGY THEORY Go to
  • High-intensity lasers Go to
  • Highly conducting organic polymers Go to
  • High order anisotropic flow coefficients and ridge Go to
  • High performance computing Go to
  • High performance computing Go to
  • High power devices Go to
  • High power high speed GaN/AlGaN nnotransistors Go to
  • High power Laser (>1PW), Laser Driven QED and Subatomic physics (Extreme Ligth Infrastructure) Go to
  • High power lasers Go to
  • High-precision spectroscopy of atoms and molecules Go to
  • High response speed servo drives Go to
  • High speed computer networks Go to
  • High speed optoelectronic devices Go to
  • High-temperature aerospace materials Go to
  • High temperature alloys Go to
  • High temperature creep Go to
  • High-temperature superconductors Go to
  • HISTORY OF PHYSICS Go to
  • History of physics Go to
  • History of science Go to
  • History of science in general and history of modern physics in particular Go to
  • Holographic superconductivity Go to
  • Human balancing Go to
  • Hybrid structures Go to
  • Hydraulic fracturing of rock Go to
  • Hydrodynamic and jet quenching hybrid model Go to
  • Hydrodynamic and thermal statistical models for relativistic A+A collisions Go to
  • Hydrodynamic instabilities and flows, turbulence Go to
  • Hydrodynamics Go to
  • Hydrodynamics Go to
  • Hygrothermal effects, with applications to concrete Go to
  • Hysteresis Go to
I
  • Identification for robust control Go to
  • Image analysis Go to
  • IMAGE PROCESSING Go to
  • Image processing Go to
  • Impact mechanics Go to
  • Implementation of new trenchless technologies Go to
  • Indirect techniques for nuclear astrophysics Go to
  • Industrial organization Go to
  • Inequalities in analysis Go to
  • Inertial confinement fusion Go to
  • Information security Go to
  • Information techniques Go to
  • Information theory and statistical inference Go to
  • Information theory Go to
  • Infrared free electron lasers Go to
  • Infra-red imaging systems Go to
  • Infrared, optical and Raman spectra of carbon nanotubes Go to
  • Infrared spectra of self-assembled supramolecular structures and surfaces Go to
  • Innovations and technology transfer to industry Go to
  • Insect aerodynamics Go to
  • in-situ (transmission and scanning) electron microscopy Go to
  • Instabilities Go to
  • Instabilities Go to
  • Instrumentation, in particular for synchrotron radiation Go to
  • Instruments for experimental physics - separator-spectrometer, pure Ge array and LaBr3 gamma detectors Go to
  • Integrated electronic/electromechanical design Go to
  • Intelligent control Go to
  • Intense fields and particles Go to
  • Interacting Boson model Go to
  • Interaction of intense laser fields with matter Go to
  • Interactions of photons, slow electrons, and ions with atoms and molecules in the various states of matter and states of excitation Go to
  • Interdisciplinary applications of physics Go to
  • Interfaces and wetting Go to
  • Interface superconductivity, interface physics, heterostructures, superlattices Go to
  • Interfacial dynamics Go to
  • Intermediate vector bosons (the W and Z bosons) Go to
  • Interventional magnetic resonance imaging Go to
  • Introduction of Beam Foil Auger Electron spectrometry Go to
  • Inventor of Rubik's cube and other twisting puzzles Go to
  • Inverse problems Go to
  • Ion diagnostics and imaging Go to
  • Ion implantation Go to
  • Ion trapping and cooling Go to
  • Island of inversion around N=20 Go to
  • ISOL experimental techniques Go to
  • Isospin-dependent interactions Go to
  • Iso-spin in heavy ion reaction Go to
  • Issipative quantum systems Go to
J
  • Jets and photons physics Go to
K
  • Kinetic relativistic transport theory Go to
  • Kinetic theory Go to
  • Knowledge-based systems Go to
L
  • Laboratory experiments in fluids Go to
  • Large deviations growth Go to
  • Large scale computing Go to
  • Large scale nuclear structure calculations with conventional shell model and Monte Carlo Shell Model Go to
  • Laser cooling and trapping Go to
  • Laser cooling of atoms (1985-1992) Go to
  • Laser/LED Colorimetry Go to
  • Laser-matter interaction Go to
  • Laser peening and other life extending surface treatment technologies Go to
  • LASER PHYSICS & ENGINEERING Go to
  • Laser physics Go to
  • Laser physics Go to
  • Laser physics Go to
  • Laser physics Go to
  • Laser physics Go to
  • Laser produced plasmas Go to
  • Lasers and quantum electronics Go to
  • Laser spectroscopy Go to
  • Laser spectroscopy Go to
  • Laser spectroscopy Go to
  • Laser surface modifications Go to
  • Laser velocimetry and turbulence measurement Go to
  • Lattice: chaos, monopoles, non-extensive Monte Carlo Go to
  • Lattice gauge theory Go to
  • Lattice properties of metals and alloys Go to
  • Left-Handed Materials
  • Life-cycle cost analysis and design of infrastructure systems Go to
  • Life cycle management Go to
  • Life-cycle performance of structures and infrastructure systems under uncertainty Go to
  • Life extension and revalidation Go to
  • Light-matter interactions Go to
  • LIGHTWEIGHT STRUCTURES Go to
  • Limits of Quantum Physics Go to
  • Linear algebra Go to
  • Linear and nonlinear analysis of structures (beams, plates, shells, membranes, cables) under static and dynamic loads Go to
  • Linear and nonlinear analysis of viscoelastic plates and membranes modeled with multi-term fractional derivative models Go to
  • Linear and nonlinear flutter instability Go to
  • Linear and nonlinear modeling Go to
  • Linear and nonlinear system and circuit theory Go to
  • Linear, rotational and stir friction welding of Al, Ni and Ti materials and components Go to
  • Lipid membranes: phase transitions Go to
  • Liquid crystal-polymer interfaces Go to
  • Liquid crystals Go to
  • Localization of Electrons Go to
  • Logic design and representations of discrete functions Go to
  • Loop quantum gravity Go to
  • Low background experiments Go to
  • Low Dimensional Physics Go to
  • Low dimensional structures Go to
  • Low dimensional structures Go to
  • Low dimensional systems Go to
  • Low-dimensional systems Go to
  • Low-emission combustion Go to
  • Low-energy experimental physics Go to
  • Low-energy nuclear effective field theory Go to
  • Low energy nuclear physics Go to
  • Low-energy studies of fundamental symmetries Go to
  • Low-noise aircraft Go to
  • Low-power analog IC design Go to
  • Low temperature physics Go to
  • Low-temperature plasma applications Go to
  • Low temperature plasma physics Go to
  • Luminescence and solid-state detectors Go to
M
  • Machine tool vibrations Go to
  • Magnetic confinement fusion Go to
  • Magnetic materials Go to
  • MAGNETIC RESONANCE IMAGING Go to
  • Magnetic resonance imaging Go to
  • Magnetism Go to
  • MAGNETISM, NANOMAGNETISM Go to
  • Magnetohydrodynamics Go to
  • Magnetooptics Go to
  • Magnetospheric physics Go to
  • Management and economy Go to
  • Management of large institutes and collaborations Go to
  • Manipulating molecules with electro-magnetic fields Go to
  • Manufacture of materials Go to
  • Many body theory Go to
  • Map-based neuron models Go to
  • Mass spectrometry Go to
  • Material fatigue Go to
  • MATERIAL SCIENCE Go to
  • Material science Go to
  • Material science Go to
  • Material science Go to
  • MATERIAL SCIENCES Go to
  • MATERIALS ENGINEERING Go to
  • MATERIALS Go to
  • MATERIALS PHYSICS Go to
  • MATERIALS SCIENCE, APPLIED PHYSICS Go to
  • MATERIALS SCIENCE Go to
  • Materials science Go to
  • Materials science Go to
  • Materials science Go to
  • Materials science Go to
  • Materials science Go to
  • Materials science Go to
  • Materials structure Go to
  • Materials technology Go to
  • Materials with extreme and rare properties Go to
  • Materials with strong electronic correlations Go to
  • MATHEMATICAL ENGINEERING Go to
  • Mathematical engineering Go to
  • Mathematical methods of quantum theory Go to
  • Mathematical modeling Go to
  • MATHEMATICAL PHSYICS Go to
  • Mathematical physics, analysis, probability Go to
  • MATHEMATICAL PHYSICS Go to
  • Mathematical physics Go to
  • Mathematical physics Go to
  • Mathematical physics Go to
  • Mathematical physics Go to
  • Mathematical physics, in particular quantum theory and statistical physics Go to
  • MATHEMATICAL PHYSICS, MATHEMATICAL ANALYSIS Go to
  • Mathematical system theory and its applications Go to
  • MATHEMATICS & ENGINEERING SCIENCES Go to
  • MATHEMATICS & PHYSICS Go to
  • Matrix effects in PIXE studies Go to
  • Matter-antimatter asymmetry Go to
  • Matter wave optics Go to
  • Measurement of transport and magnetic properties Go to
  • Measurements of physical properties (equation of state, conductivity, opacity, stopping power, light reflectivity, plasma composition, et-cetera) of strongly coupled plasmas with strong interparticle interactions Go to
  • Mechanical and structural properties of surfaces Go to
  • Mechanical behaviour of materials Go to
  • MECHANICAL ENGINEERING Go to
  • Mechanical properties Go to
  • Mechanical properties of amorphous materials Go to
  • Mechanical properties of materials Go to
  • Mechanical property analysis of non-oxide based ceramics Go to
  • MECHANICS, COMPOSITE MATERIALS, SMART MATERIALS AND STRUCTURES Go to
  • MECHANICS Go to
  • Mechanics Go to
  • Mechanics of advanced structural materials Go to
  • Mechanics of composite materials Go to
  • Mechanics of composites materials Go to
  • Mechanics of deformable solids and related problems of continuum mechanics Go to
  • Mechanics of deformable solids (concrete,rock,soil) Go to
  • Mechanics of materials and structures and structural safety Go to
  • MECHANICS OF MATERIALS AND STRUCTURES Go to
  • MECHANICS OF MATERIALS AND STRUCTURES Go to
  • MECHANICS OF MATERIALS Go to
  • Mechanics of materials Go to
  • Mechanics of materials: micro-scale plasticity theory based on dislocation models Go to
  • Mechanics of multifunctional (noise-absorbing, vibration-damping, heat-isolating and energy-saving) materials and structures Go to
  • Mechanics of nanocomposites Go to
  • Mechanics of non-classical deformable solids Go to
  • Mechanics of smart (piezoelectzric, magnetoelectroelastic, shape-memory) materials and structures Go to
  • Mechanics of solids Go to
  • MECHATRONICS Go to
  • Mechatronics Go to
  • Medical image processing Go to
  • Medical imaging Go to
  • MEDICAL PHYSICS Go to
  • Medical physics Go to
  • Medical physics Go to
  • Medium modifications of hadrons Go to
  • MEMBRANE BIOPHYSICS Go to
  • Membrane biophysics Go to
  • Meshless methods Go to
  • Mesopotamian bronze alloy Go to
  • Mesoscopic (nano-scale) phenomena Go to
  • Mesoscopic physics Go to
  • MESOSCOPIC & QUANTUM PHYSICS Go to
  • Metal composites Go to
  • Metallic foams Go to
  • Metallic muscles Go to
  • METALLURGY Go to
  • METALLURGY, MATERIAL SCIENCES Go to
  • Metallurgy (process and product) Go to
  • Metal matrix composites (Ti-SiC fibre and Al particulate) Go to
  • Meteorology and physical oceanography Go to
  • Methods from general relativity Go to
  • Micro- and nanofluidics Go to
  • Microdosimetry and nanodosimetry Go to
  • Microelectronics and nanoelectronics Go to
  • MICROFLUIDICS Go to
  • Micromechanics of concrete materials and structures (effective properties, homogenization, interface defects, etc.) Go to
  • Micromechanics of deformation and fracture Go to
  • MICRO/NANOELECTRONICS; ANALOG & MIXED-SIGNAL INTEGRATED CIRCUITS AND CAD Go to
  • Micro/nano mechanics Go to
  • Microstructure analysis of non-oxide based ceramics Go to
  • Microwaves Go to
  • Millimetre waves Go to
  • Minimization of fuel consumption and pollutant emission of land vehicle propulsion systems Go to
  • Mitigation, Kyoto mechanisms, capacity building and technology transfer in the context of climate change Go to
  • Mixed-signal testing Go to
  • MOCVD growth of GaN and related materials Go to
  • Modeling of therapeutic interventions such as balloon angioplasty and stent implantation Go to
  • Modelling and physics of cancer Go to
  • Modelling of smart materials and functionally graded materials Go to
  • Modelling salt and water transport across cell membranes and pumping epithelia Go to
  • Model reduction Go to
  • Models of quantum spacetime Go to
  • Modern technologies Go to
  • Molecular electronics Go to
  • Molecular ion beam studies (Coulomb Explosion) Go to
  • Molecules and clusters Go to
  • Monte Carlo simulation of cluster models Go to
  • Monte-Carlo simulations for large detection systems Go to
  • Monte Carlo simulations Go to
  • Monte Carlo string models for the description of hadron-hadron and A+A collisions Go to
  • Multiferroic materials Go to
  • Multi-Field analysis Go to
  • Multifragmentation: percolation models, scaling Go to
  • Multifunctional materials Go to
  • Multifunctional Nanocomposites Go to
  • Multi-hazard risk mitigation and health monitoring of bridges and naval ships Go to
  • Multi-layered and functionally graded materials Go to
  • Multimedia communications Go to
  • Multimedia signal processing Go to
  • Multi-particle detection within a large solid angle Go to
  • Multiphase systems Go to
  • Multi-photon microscopy (SHG) Go to
  • Multi-Scale analysis of materials and structures Go to
  • Multiscale Modeling of Materials, linking microscopic and macroscopic properties Go to
  • Multiscale models for porous materials and fiber reinforced composites Go to
N
  • Nano- and micro-mechanics of multi-phase materials Go to
  • Nanocapilarity Go to
  • Nano-clusters Go to
  • Nano-crystalline materials Go to
  • Nanoelectronics Go to
  • Nanoelectronics Go to
  • Nanofabrication and nanopatterning Go to
  • Nano-foams Go to
  • Nanomaterials characterization and design Go to
  • Nanomaterials Go to
  • NANOMATERIALS Go to
  • Nanomaterials Go to
  • Nanomaterials processing Go to
  • Nanomechanics: continuum mechanics theory for nanostructures based on interatomic potentials Go to
  • Nano-mechanics Go to
  • Nanomechanics Go to
  • Nanomechanics Go to
  • NANOPHOTONICS Go to
  • Nanophotonics Go to
  • Nanophysics and soft matter Go to
  • Nanophysics Go to
  • Nano-plasmas and plasmonics Go to
  • Nanoplasmonics Go to
  • Nanoplasmonics Go to
  • Nanoscale synthesis and processing Go to
  • Nanoscience: carbon nanotubes, graphene and graphene derivatives Go to
  • Nano-structured and hierarchical materials Go to
  • Nanostructured coatings Go to
  • Nanostructured materials Go to
  • Nanostructures and nanotubes Go to
  • Nanostructures by controlled selforganization Go to
  • Nanostructures Go to
  • Nanostructures Go to
  • Nanotechnology Go to
  • Nanotechnology Go to
  • Nanotechnology Go to
  • Nanotechnology, nanofabrication Go to
  • Nanotechnology: opto-electronics Go to
  • Nanotechnology, solar blind nitride based UV detectors Go to
  • Nanotomography Go to
  • Nanotribology-superlow friction Go to
  • Nanotubes Go to
  • NANPHYSICS Go to
  • Nature of Time and Space - Wormholes, Quantum Foam and All That Go to
  • Negative hydrogen ion sources Go to
  • Network science Go to
  • NEUCLEAR PHYSICS Go to
  • Neural networks Go to
  • Neural networks Go to
  • Neural networks Go to
  • Neural networks: spontaneous pattern formation Go to
  • Neuro-dynamics modeling for robots Go to
  • Neutral beam injection Go to
  • Neutrinoless Double-Beta Decay Go to
  • Neutrino physics and neutrino astrophysics Go to
  • Neutrino physics Go to
  • Neutrino physics Go to
  • Neutron interferometry Go to
  • Neutron optics Go to
  • Neutron physics Go to
  • Neutron physics Go to
  • Neutron Stars: Go to
    • Structure and dynamics
    • Evolution
    • Superfluidity and superconductivity
    • Accretion and accretion disks
  • New developments within many-body theory and TDDFT, including ab-initio description of electron excitations, optical spectroscopy, time-resolved spectroscopies, STM/STS, XAFS and lifetimes, novel techniques to calculate total energies and assessment and development of exchange-correlation functionals for TDDFT calculations; improvements on transport theory within the real-time TDDFT formalism; characterization of the electronic and optical properties of solids, nanostructures (in particular nanotubes, nanowires and semiconducting clusters) and biomolecules Go to
  • New electrical machines structures Go to
  • New kinds of non-crystalline solids: Nano-glasses Go to
  • New materials with honeycomb structures: Silicene, Germanene and MX2 Go to
  • New physics beyond the Standard Model (SM) Go to
  • New residual stress measurement technologies Go to
  • Non-adaptive complexity in biological systems Go to
  • Non-classical problems of fracture mechanics Go to
  • Non classical properties of light as tests of the foundations of quantum mechanics (1974-1985) Go to
  • Non-destructive methods of stress determination Go to
  • Non-Equilibrium aspects of materials development Go to
  • Non-equilibrium dynamics Go to
  • Nonequilibrium Go to
  • Non-Equilibrium Pattern Formation Go to
  • Non-equilibrium phenomena Go to
  • Non-equilibrium quantum field theory Go to
  • Non-equilibrium statistical mechanics Go to
  • NON EQUILIBRIUM STATISTICAL MECHANICS Go to
  • Non-equilibrium statistical mechanics Go to
  • NONEQUILIBRIUM STATISTICAL PHYSICS Go to
  • Non equilibrium systems Go to
  • Nonequilibrium thermodynamics and statistical mechanics Go to
  • Non-extensive thermodynamics: additivity restoring condition for entropy formulas Go to
  • Nonlinear circuits and systems Go to
  • NONLINEAR CIRCUITS AND SYSTEMS Go to
  • Nonlinear circuits and systems Go to
  • Nonlinear continuum mechanics Go to
  • Nonlinear control systems Go to
  • Nonlinear control theory Go to
  • Nonlinear dynamical systems Go to
  • Nonlinear dynamics and chaos Go to
  • Nonlinear dynamics and chaos in dynamical systems Go to
  • Nonlinear dynamics and classical chaos Go to
  • Nonlinear dynamics, bifurcation and chaos Go to
  • NONLINEAR DYNAMICS, CHAOS AND COMPLEX SYSTEMS Go to
  • Nonlinear dynamics, control of quantum transport Go to
  • Nonlinear dynamics Go to
  • Nonlinear dynamics Go to
  • Nonlinear dynamics Go to
  • Nonlinear dynamics Go to
  • Nonlinear dynamics Go to
  • Nonlinear dynamics of wheels Go to
  • Nonlinear dynamics, quantum- and wave dynamical chaos Go to
  • Nonlinear finite element methods Go to
  • Nonlinear lattice dynamics, Soliton-assisted electron transport (Solectron transport) Go to
  • Nonlinear-magneto Optics Go to
  • Nonlinear methods (support vector machines, multilinear algebra) for data processing and optimization techniques Go to
  • Nonlinear optics Go to
  • Nonlinear optics Go to
  • Non-linear optics Go to
  • Nonlinear optics Go to
  • Nonlinear optics Go to
  • Nonlinear optics Go to
  • Nonlinear Patterns and defects Go to
  • Nonlinear phononics Go to
  • Nonlinear resonances: vibrational resonance and stochastic resonance Go to
  • Nonlinear signal processing Go to
  • Nonlinear systems and chaotic motions Go to
  • Nonlinear systems Go to
  • Nonlinear vibrations Go to
  • Nonlinear viscoelasticity and viscoplasticity Go to
  • Nonlinear waves and intermediate asymptotics Go to
  • Nonperturbative methods in quantum field theory Go to
  • Novel approaches in system dynamics Go to
  • Novel detection methods (particle detectors, radio detection, microwave detection) Go to
  • Novel germanium detectors Go to
  • Novel nuclear rotation - nuclear chirality Go to
  • Novel scintillator detectors Go to
  • NUCLEAR AND HADRON PHYSICS Go to
  • Nuclear and particle physics Go to
  • Nuclear astrophysical applications - r-process nucleo-cosmochronology Go to
  • Nuclear astrophysics Go to
  • Nuclear Astrophysics Go to
  • NUCLEAR ASTROPHYSICS Go to
  • Nuclear astrophysics Go to
  • Nuclear astrophysics Go to
  • Nuclear astrophysics Go to
  • Nuclear astrophysics Go to
  • Nuclear astrophysics Go to
  • Nuclear astrophysics (light elements in the Universe, CNO cycle) Go to
  • Nuclear astrophysics using radioactive-ion beams Go to
  • Nuclear collective states Go to
  • Nuclear detection techniques Go to
  • Nuclear instrumentation Go to
  • Nuclear instrumentation (magnetic devices; detectors; diagnostics) Go to
  • Nuclear Magnetic Resonance Go to
  • Nuclear matter equation of State Go to
  • Nuclear methods and techniques Go to
  • Nuclear neutrino-less double-beta decay Go to
  • NUCLEAR & PARTICLE PHYSICS Go to
  • NUCLEAR PHYSIC Go to
  • Nuclear physics and applications Go to
  • NUCLEAR PHYSICS, COMPUTATIONAL PHYSICS Go to
  • NUCLEAR PHYSICS Go to
  • Nuclear physics Go to
  • Nuclear physics Go to
  • Nuclear physics Go to
  • Nuclear Physics Go to
  • Nuclear physics Go to
  • Nuclear physics Go to
  • Nuclear physics Go to
  • NUCLEAR PHYSICS, NUCLEAR ASTROPHYSICS, CULTURAL HERITAGE Go to
  • Nuclear physics (parity violation, proton polarized beams) Go to
  • Nuclear reactions and accelerator technology Go to
  • Nuclear reactions at low-momentum transfers Go to
  • Nuclear reactions: direct transfer reactions; elastic and inelastic scattering; charge-exchange reactions Go to
  • Nuclear reactions Go to
  • Nuclear reactions; knock-out reactions; Coulomb excitation Go to
  • Nuclear reactions with heavy ions Go to
  • Nuclear reactions with light and heavy ions Go to
  • Nuclear shell model Go to
  • Nuclear structure and electromagnetic interactions Go to
  • Nuclear structure and reactions Go to
  • Nuclear structure and reactions using electron scattering Go to
  • Nuclear structure Go to
  • Nuclear structure Go to
  • Nuclear structure Go to
  • Nuclear structure Go to
  • Nuclear structure Go to
  • Nuclear structure Go to
  • Nuclear structure Go to
  • Nuclear structure physics Go to
  • Nuclear structure: single-particle and collective modes of excitation; isobaric analog states; exotic nuclei Go to
  • NUCLEAR STRUCTURE THEORY Go to
  • Nuclear structure using radioactive-ion beams Go to
  • Nuclear weak interactions and astrophysical applications Go to
  • Nucleation theory (phase-field, Cahn-Hilliard, phenomenological) Go to
  • Nucleon structure Go to
  • Nucleosynthesis in stellar and explosive burning Go to
  • NUCLEUS RESEARCH Go to
  • Numerical methods Go to
  • Numerical methods in fracture mechanics Go to
  • Numerical modelling and simulation of THMC behaviour of soils and rocks Go to
  • Numerical range and operator theory Go to
  • Numerical solution of ordinary and partial fractional differential equations Go to
O
  • Oil and gas processing Go to
  • On-line diagnostical methods Go to
  • Open system dynamics Go to
  • Optical communications Go to
  • Optical investigation of non-equilibrium many-body phenomena Go to
  • Optical lattices Go to
  • Optical methods Go to
  • Optical properties of high temperature superconductors Go to
  • Optical properties of quantum nanostructures Go to
  • optical pumping Go to
  • OPTICAL SPECTROSCOPY Go to
  • Optical spectroscopy Go to
  • Optics (thin metal layers) Go to
  • OPTIC/ULTRASHORT PHENOMENA Go to
  • Optimization algorithms Go to
  • Optimum inspection, maintenance, and management of deteriorating infrastructures Go to
  • Optimum weight constructions Go to
  • Optoelectronic and photonic devices Go to
  • Optoelectronics Go to
  • Optoelectronics Go to
  • Opto-magnetism Go to
  • Organic/polymeric ultra-thin films/ monolayers Go to
  • Origin of the masses of particles Go to
  • Oscillators Go to
P
  • Pair production in strong fields, applications to high-intensity lasers Go to
  • Parametric excitation of delayed mechanical systems Go to
  • Particle accelerators Go to
  • PARTICLE ASTROPHYSICS Go to
  • Particle astrophysics Go to
  • Particle cosmology Go to
  • Particle physics at the 440 Mev synchrocyclotron Go to
  • Particle physics Go to
  • PARTICLE PHYSICS Go to
  • Particle physics Go to
  • Particle physics theory and phenomenology Go to
  • Particle production in intense fields Go to
  • Particle track production mechanisms Go to
  • Pattern formation and competition in nonlinear active and passive optics and in excitable media Go to
  • Pattern formation (computer and laboratory experiments) Go to
  • Pattern formation Go to
  • Pattern recognition Go to
  • Percolation theory Go to
  • Peristaltic pumping in the ureter Go to
  • Perturbative QCD Go to
  • Phase diagram of nuclear matter Go to
  • Phase-field modeling of complex solidification patterns ('dizzy' dendrites, spherulites, with foreign particles, in confined space) Go to
  • Phase-locked loops Go to
  • Phase relationships of non-oxide based ceramics Go to
  • Phase transformations in steels Go to
  • Phase transition of nuclear matter Go to
  • Phase transitions and critical phenomena Go to
  • Phase transitions Go to
  • Phenomenology of high energy nuclear collisions Go to
  • Phononics, control and manipulate heat due to phonons Go to
  • Photoionisation of atoms Go to
  • Photon correlation spectroscopy Go to
  • Photon counting avalanche photo-diodes Go to
  • Photonic Crystals Go to
  • Photonic Metamaterials Go to
  • Photonuclear reactions (meson photoproduction) Go to
  • Physical biology Go to
  • Physical chemistry Go to
  • PHYSICAL METALLURGY Go to
  • Physical properties of hot dense matter at megabar pressure range Go to
  • Physics and engineering section Go to
  • Physics and society Go to
  • Physics beyond the Standard Model Go to
  • Physics beyond the Standard Model Go to
  • Physics/Condensed matter physics Go to
  • Physics education Go to
  • Physics education Go to
  • PHYSICS & ELECTRICAL ENGINEERING Go to
  • PHYSICS, ENERGY Go to
  • PHYSICS & ENGINEERING Go to
  • PHYSICS & ENGINEERING SCIENCES Go to
  • PHYSICS ENGINEERING SCIENCES Go to
  • PHYSICS Go to
  • Physics Go to
  • Physics Go to
  • Physics Go to
  • Physics Go to
  • Physics Go to
  • Physics Go to
  • Physics in magnetic fields Go to
  • Physics, materials, and technology of semiconductor devices Go to
  • Physics of beam-plasma interaction Go to
  • PHYSICS OF BLACK HOLES Go to
  • Physics of cold gases Go to
  • Physics of disorder with ultracold atoms Go to
  • Physics of extensive air-showers Go to
  • PHYSICS OF SEMICONDUCTORS Go to
  • Physics of semiconductors Go to
  • Physics of social systems Go to
  • PHYSICS OF STRONG INTERACTION Go to
  • Physics of the aurora Go to
  • PHYSICS-OPTICS Go to
  • Physics outreach Go to
  • Piezonuclear reactions Go to
  • Planetary magnetospheres Go to
  • Planetology Go to
  • Plasma catalysis Go to
  • Plasma chemistry Go to
  • Plasma control Go to
  • Plasma diagnostics Go to
  • Plasma health care and medicine Go to
  • Plasma magnetohydrodynamic stability Go to
  • Plasma modelling Go to
  • PLASMA NANOSCIENCE Go to
  • Plasma nanoscience Go to
  • PLASMA PHYSICS Go to
  • Plasma spectroscopy Go to
  • Plasma technology Go to
  • Plasticity Go to
  • Plasticity theory and finite elements Go to
  • Plates with variable thickness, plates on elastic foundation, plates reinforced with beams Go to
  • Politics Go to
  • Polymerisation Go to
  • Polymer materials and systems Go to
  • POLYMER PHYSICAL CHEMISTRY Go to
  • Polymer physics Go to
  • Polymers Go to
  • Position astronomy and new time standards based on atomic clocks Go to
  • Powder compaction Go to
  • Powder metallurgy Go to
  • Powder processing Go to
  • Powder technology Go to
  • Power conditioning systems for fuel cells applications Go to
  • Power electronics conversion Go to
  • Power plant materials Go to
  • Precision femtosecond spectroscopy Go to
  • Principles of phase diagrams Go to
  • Probabilistic approach of the yield design theory Go to
  • Probabilistic mechanics Go to
  • Processes and nonlinear equations Go to
  • PROCESS SAFETY TECHNOLOGY Go to
  • Process technology Go to
  • Production engineering Go to
  • Production of heavy quarkonia and cold nuclear matter effects Go to
  • Project management Go to
  • Propagation Go to
  • Properties of elementary particles Go to
  • Properties of extremely unstable nuclei ("nucleon halos") Go to
  • Properties of hadrons in nuclear matter under extreme conditions of energy density and temperature Go to
  • Properties of nuclei far from stability Go to
  • Properties of strongly interacting matter Go to
  • Proton therapy Go to
  • Pulsars: Go to
    • Timing and glitches
    • Evolution of millisecond pulsars
  • Puzzle designer Go to
Q
  • QCD phase diagram Go to
  • Quality of service for IP-based networks; flow-aware networking Go to
  • Quantitative non-destructive evaluation Go to
  • Quantization of constrained systems Go to
  • Quantized electric and heat conductance Go to
  • Quantum beat studies Go to
  • Quantum chaos Go to
  • Quantum chaos Go to
  • Quantum chaos Go to
  • Quantum ChromoDynamics Go to
  • Quantum chromodynamics Go to
  • Quantum classical correspondence for classically chaotic systems Go to
  • QUANTUM COLLISION THEORY Go to
  • Quantum collision theory Go to
  • Quantum communications Go to
  • Quantum computing Go to
  • Quantum cryptography Go to
  • Quantum Dots Go to
  • Quantum dots Go to
  • QUANTUM ELECTRONICS Go to
  • Quantum electronics Go to
  • Quantum electronic transport Go to
  • Quantum field theory at finite temperature, Go to
  • Quantum fluids and solids Go to
  • QUANTUM GRAVITY Go to
  • Quantum gravity Go to
  • Quantum Hall effect Go to
  • Quantum Hall effect Go to
  • Quantum information Go to
  • Quantum information Go to
  • Quantum information processing Go to
  • Quantum information processing Go to
  • Quantum information processing Go to
  • Quantum information science Go to
  • Quantum information theory and computer science Go to
  • Quantum information theory Go to
  • Quantum many-body theory Go to
  • Quantum mechanics and quantum entanglement Go to
  • Quantum mechanics Go to
  • Quantum mechanics on graphs and surfaces Go to
  • Quantum Monte Carlo simulations of many-body systems, in particular electron gas Go to
  • QUANTUM OPTICS & ATOMIC PHYSICS Go to
  • Quantum optics Go to
  • quantum optics Go to
  • Quantum optics Go to
  • Quantum optics Go to
  • Quantum optics Go to
  • QUANTUM OPTICS Go to
  • Quantum optics Go to
  • Quantum optics Go to
  • Quantum optics in nanoscale semiconductors Go to
  • Quantum origin of the universe Go to
  • Quantum physics Go to
  • Quantum physics of ultracold atoms Go to
  • Quantum simulation Go to
  • Quantum simulations Go to
  • Quantum simulation with ultracold atoms in optical lattices Go to
  • Quantum technologies: 3He-4He Dilution refrigerators, dc Squid electronics Go to
  • Quantum Technologies Go to
  • Quantum thermodynamics Go to
  • Quantum thermodynamics Go to
  • Quantum Transport of Electrons Go to
  • Quark-Gluon Plasma as a Perfect Fluid Go to
  • Quark-gluon plasma Go to
  • Quark-gluon plasma Go to
  • Quark Gluon Plasma Go to
  • Quark-Gluon Plasma Go to
  • Quark-gluon-plasma Go to
  • Quark gluon plasma research in high energy nucleus-nucleus collisions Go to
  • Quark - gluon plasma: strangeness, magnetic mass Go to
  • Quark matter in heavy-ion collisions and in compact stars, Go to
R
  • Radiation protection Go to
  • Radiation therapy Go to
  • radiative forces – laser cooling and trapping Go to
  • Radioactive beams Go to
  • Radioactive ion beams: production (electro-fission; photo-fission; neutron-induced fission; fusion reactions) and acceleration Go to
  • Radioactive nuclear beam theory Go to
  • Radioactivity mapping (Fukushima) Go to
  • Radiobiological modelling Go to
  • Radio-biology Go to
  • Radiocommunications Go to
  • RADIO FREQUENCY ELECTRONICS Go to
  • Raman spectroscopy Go to
  • Random matrices and quantum chaos Go to
  • Random matrices Go to
  • Random networks Go to
  • Reaction physics with stable and radioactive beams Go to
  • Reactor physics Go to
  • Real-world network theory Go to
  • Recursive algorithms Go to
  • Rehabilitation robotics Go to
  • Reinforced concrete Go to
  • Relativistic fluid dynamics Go to
  • Relativistic fluid dynamics Go to
  • Relativistic heavy ion collisions and Quark Gluon Plasma Go to
  • Relativistic heavy ion collisions and the nuclear equation of state Go to
  • Relativistic heavy ion collisions Go to
  • Relativistic heavy ion collisions Go to
  • Relativistic heavy-ion physics Go to
  • Relativistic heavy ions and proton spin Go to
  • Relativistic heavy ions Go to
  • Relativistic hidrodynamics Go to
  • Relativistic hydrodynamics Go to
  • Relativistic hydrodynamics Go to
  • Relativistic quantum mechanics; Dirac Hamiltonians Go to
  • Relativistic statistical mechanics and thermodynamics Go to
  • Relativistic statistical physics Go to
  • Relativistic thermodynamics Go to
  • Relaxation of hot and dense partonic matter to local equilibrium Go to
  • Reliability and survivability assurance in telecommunication networks Go to
  • Research on radioactivity, beta decay, exotic nuclear decay modes Go to
  • Resilience and sustainability of structures and distributed infrastructure Go to
  • resonance fluorescence in intense resonant laser beams Go to
  • Response of structures under nonconservative loads Go to
  • Rheological models Go to
  • Rheology Go to
  • Riccati equations Go to
  • Rigorous results in statistical mechanics and solid state theory Go to
  • Risk-based assessment and risk-informed decision making in civil and marine engineering Go to
  • Robust control Go to
  • Rocking and hysteretic systems Go to
  • Rock mechanics Go to
S
  • Safety management related to nuclear installations Go to
  • Safety of magnetic resonance imaging Go to
  • Safety of tunnels in case of fire Go to
  • Safety, reliability, risk and multi-criteria optimization of structural systems Go to
  • Safety technology Go to
  • Scanned probe microscopy techniques Go to
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  • Sediments in Roman aqueducts Go to
  • Seismic engineering and structural dynamics problems Go to
  • Seismic isolation Go to
  • Seismic structural analysis and design Go to
  • Self-organization and collective behavior Go to
  • Self-similarities Go to
  • Semiconductor epitaxy Go to
  • Semiconductor heterostructures Go to
  • Semiconductor Nanoelectronics Go to
  • SEMICONDUCTOR PHYSICS Go to
  • Semiconductors and semiconductor nanostructures Go to
  • SEMICONDUCTORS, EPITAXY Go to
  • Semiconductors Go to
  • Semiconductors Go to
  • Semiconductors Go to
  • SEMICONDUCTORS, MICRO AND NANOTECHNOLOGY Go to
  • Sensors and Actuators Go to
  • Shallow foundations under inclined and eccentric or seismic loads Go to
  • Shock phenomena Go to
  • Shocks, detonations, deflagrations Go to
  • Short-range, long-range, and femtoscopic correlations Go to
  • Short wavelength laser diodes and light emitters Go to
  • Signal detection & estimation Go to
  • Signal processing and neural networks Go to
  • Signal processing Go to
  • Signal processing Go to
  • Silicon detectors Go to
  • Silicon strip detectors Go to
  • Silks Go to
  • Single-mode optical-fiber sensors Go to
  • Single photon sources Go to
  • Size effects and scaling Go to
  • Size effects in structural materials Go to
  • Smart grid Go to
  • Smart Materials and Structures Go to
  • SOFT CONDENSED MATTER Go to
  • Soft condensed matter Go to
  • (Soft) condensed-matter physics Go to
  • Soft matter and granular media Go to
  • Soft matter Go to
  • SOFT MATTER PHYSICS AND MECHANICS Go to
  • Soft Robotics Go to
  • SOIL MECHANICS Go to
  • Soil mechanics Go to
  • Soil-structure-interaction Go to
  • Solar and interplanetary physics Go to
  • Solar physics Go to
  • Solidification of alloys Go to
  • Solid mechanics Go to
  • SOLID MECHANICS Go to
  • Solid mechanics Go to
  • Solid Mechanics Go to
  • Solid mechanics Go to
  • Solid-state diffusion and kinetics, based on experimental, theoretical, and computer-simulation activities Go to
  • Solid state lasers Go to
  • Solid state physics Go to
  • Solid state physics Go to
  • Solid state physics Go to
  • SOLID STATE PHYSICS Go to
  • Solid-state polymerization Go to
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  • SPACE SCIENCE/MAGNETOSPHERES/HELIOSPHERE Go to
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  • Spectroscopic instrumentation Go to
  • Spectroscopic studies on clusters and biomolecules Go to
  • Spectroscopy in Condensed Matter Physics Go to
  • Spectroscopy of s- and d-shell Go to
  • Spectroscopy: optical, Raman, ion scattering Go to
  • Spin as a tool (e.g., production of polarized antiprotons, search for time reversal invariance violation (TRV), and electric dipole moments (EDM)) Go to
  • Spin-dependent phenomena Go to
  • Spin glasses Go to
  • Spin structure of the nucleons Go to
  • Spintronics Go to
  • SPINTRONICS Go to
  • Spintronics Go to
  • Sputtering Go to
  • Stability analysis of earthworks Go to
  • Stability of structures (beams, plates and shells) Go to
  • Stability of structures Go to
  • Stability theory Go to
  • Stabilization of unstable equilibria and unstable motions Go to
  • Star experiment at RHIC Go to
  • Static and dynamic analysis of continuously nonhomogeneous functionally graded materials (FGMs) and structures Go to
  • STATISTICAL AND NONLINEAR PHYSICS Go to
  • STATISTICAL MECHANICS Go to
  • Statistical mechanics Go to
  • Statistical mechanics Go to
  • Statistical mechanics Go to
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  • STATISTICAL PHYSICS Go to
  • Statistical physics Go to
  • Statistical physics Go to
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  • Stat physics Go to
  • Steel structures Go to
  • Stellar evolution Go to
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  • Stimulus Responsive Polymers (Shape Memory Polymers and Electro-Active Polymers) Go to
  • Stochastic analysis Go to
  • STOCHASTIC MECHANICS Go to
  • Stochastic modeling and queueing theory Go to
  • Stochastic modelling Go to
  • Stochastic phenomena Go to
  • Stochastic phenomena in physics and in engineering sciences Go to
  • Stochastic processes Go to
  • Stochastic theory Go to
  • Strangeness physics Go to
  • Stress concentration around holes in shells Go to
  • Stress related transformations including ferro electric and shape memory transitions Go to
  • Stretchable/flexible electronics: using mechanics principles to design/fabricate silicon-based stretchable electronics Go to
  • String theory Go to
  • String theory Go to
  • Strong-field physics Go to
  • Strong-interaction physics Go to
  • Strong Interactions at high density and temperature Go to
  • Strong interactions Go to
  • Strongly correlated quantum systems Go to
  • Strongly correlated systems Go to
  • Strongly interacting photons Go to
  • Structural analysis and applied mechanics Go to
  • Structural control and health monitoring Go to
  • STRUCTURAL DYNAMICS Go to
  • Structural engineering and applied mechanics-dynamics Go to
  • Structural engineering Go to
  • STRUCTURAL ENGINEERING Go to
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  • Structural health monitoring Go to
  • Structural integrity of aerospace and nuclear plant Go to
  • Structural mechanics Go to
  • STRUCTURAL MECHANICS Go to
  • Structural mechanics Go to
  • Structural mechanics Go to
  • Structural mechanics (reinforced concrete and steel structures, geotechnical structures, stability of structures) Go to
  • STRUCTURAL RELIABILITY AND RISK Go to
  • Structure analysis Go to
  • Structure and dynamic properties of monolayers, micelles, thin liquid films, foams, emulsions and microemulsions Go to
  • Structure and dynamics of complex networks Go to
  • Structure and dynamics of thin molecular films Go to
  • Structure and reactions of exotic nuclei Go to
  • Structure Health Monitoring Go to
  • Structure of hadronic matter Go to
  • Structure Process Property Relations of materials, i.e. the relevance of sample history on morphology and function Go to
  • Studies in metallurgy of electrical welding Go to
  • Study of exotic nuclei far from stability Go to
  • Study of shell closure around magic numbers 20, 28, 50 Go to
  • Super- and hyperdeformed states in the actinide region Go to
  • Supercomputers Go to
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  • Superconductivity Go to
  • Superconductivity Go to
  • Superdense stars and supernova Go to
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  • Superheavy element research Go to
  • Superheavy nuclei Go to
  • Superplasticity Go to
  • Superstring compactifications and their effective supergravity theories Go to
  • Supersymmetry and Supergravity Go to
  • Supersymmetry Go to
  • Supramolecular chemistry at interfaces Go to
  • Surface and bulk light scattering, excited surface waves techniques, ellipsometry, fluorescence recovery, brewster angle microscopy, videomicroscopy Go to
  • Surface and interface effects in nao-materials and nano-structures (nano-ribbons, nano-tubes, nano-plates, nano-shells, etc. Go to
  • Surface and interface magnetism Go to
  • Surface engineering and coating technology Go to
  • Surface-interface physics Go to
  • Surface optical techniques/ Integrated optics/ nonlinear optics Go to
  • Surface physics Go to
  • Surface physics Go to
  • Surfaces and interfaces Go to
  • Surface tension-driven phenomena Go to
  • Sustainability assessment, energy planning, new and renewable energy technologies Go to
  • Sustainability Go to
  • Symmetries and invariance principles in nuclei Go to
  • Symmetries and representational theory Go to
  • Symmetries and symmetry breaking in hadronic reactions (e.g., chiral, isospin) Go to
  • Symmetries Go to
  • Symmetries in nuclei Go to
  • Symmetry groups Go to
  • Synchronization in chaotic and spatially extended systems Go to
  • Synthesis of distributed circuits Go to
  • Synthesis of intense Go to
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  • System identification Go to
  • System identification Go to
  • System identification Go to
  • Systems and control Go to
  • SYSTEMS AND CONTROL Go to
  • Systems biology and bioinformatics Go to
T
  • Technical detector developments Go to
  • Technological innovations derived from basic research, principally in radiation detection, plasma processing, environment, and energy Go to
  • Technology (electron cyclotron heating, material science, superconductivity) for fusion reactors (ITER, DEMO) Go to
  • Technology of semiconductors Go to
  • Technology transfer and outreach Go to
  • TELECOMMUNICATIONS Go to
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  • Terahertz Radiation Go to
  • Testing of analog and mixed-signal integrated circuits Go to
  • Texture representation in Rodriguez space Go to
  • The Constructal Law of evolution in nature Go to
  • The development of a sustainable geoenvironment - groundwater contamination, land regeneration, landfills, pollutants Go to
  • The Higgs boson Go to
  • The mechanics of fracture, materials damage and creep Go to
  • Theoretical and applied mechanics Go to
  • Theoretical and computational astrophysics Go to
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  • THEORETICAL AND SUBNUCLEAR PHYSICS. Go to
  • THEORETICAL & APPLIED MECHANICS Go to
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  • Theoretical condensed matter physics Go to
  • Theoretical condensed matter physics Go to
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  • Theoretical high energy nuclear physics Go to
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  • Theoretical nuclear physics - nuclear structure Go to
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  • THEORETICAL PARTICLE PHYSICS Go to
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  • THEORETICAL PHYSICS Go to
  • Theoretical physics Go to
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  • Theoretical physics, in particular statistical mechanics Go to
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  • Theoretical physics – statistical physics Go to
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  • Theoretical quantum optics and atomic physics Go to
  • Theoretical Soft Matter Physics with focus on macromolecular materials Go to
  • Theoretical spectroscopy: photoemission, time-resolved optical and magnetic spectroscopies Go to
  • Theory and experiment Go to
  • Theory and modelling of electronic and structural properties in condensed matter Go to
  • Theory and phenomenology of the fundamental interactions Go to
  • Theory and practice of telecommunications switching, including photonic switching Go to
  • Theory of complex systems Go to
  • Theory of fluid and gas flows in porous media Go to
  • Theory of gravity Go to
  • Theory of high frequency transistor amplifiers and oscillators Go to
  • Theory of magnetism Go to
  • Theory of Open quantum systems. Strong light-matter interactions and Optimal control theory Go to
  • Theory of propagation and diffraction of elastic waves in multi-connected bodies and bodies with initial stresses Go to
  • Theory of scanning tunneling and atomic force microscopy Go to
  • Theory of tunnel diode amplifiers Go to
  • Thermal field theory Go to
  • Thermal field theory Go to
  • Thermal metamaterials: thermal cloak, thermal camouflage, thermal concentrator Go to
  • Thermal property analysis of non-oxide based ceramics Go to
  • Thermal rectification and thermal transistor Go to
  • Thermal stability of crystals Go to
  • Thermal stresses Go to
  • Thermodynamic modelling of phases Go to
  • Thermodynamic properties of alloys Go to
  • Thermodynamics Go to
  • Thermodynamics Go to
  • Thermoelasticity Go to
  • Thermoelectricity Go to
  • Thermo/hydraulic/mechanical/chemical (THMC) analysis of the engineering behaviour of unsaturated soils Go to
  • The science and technology of electrochemical devices, from sensors and fuel cells to batteries, supercapacitors, and actuators Go to
  • The science and technology of nanomaterials Go to
  • The self-assembly, properties, and applications of photonic crystals Go to
  • Thickness optimization of beams and plates under conservative and nonconservative loads Go to
  • Thin films Go to
  • Thin film synthesis and characterization Go to
  • Three-dimensional theory of stability of deformable bodies Go to
  • Threshold phenomena for Schrödinger type operators Go to
  • Time and frequency metrology Go to
  • Time-frequency analysis Go to
  • Time-periodic delayed systems Go to
  • Time-resolved observation and control of atomic-scale electron motion on the attosecond-femtosecond time scale Go to
  • Time-resolved spectroscopy Go to
  • Tokamak operations Go to
  • Topological effects in condensed matter Go to
  • Topological phononics Go to
  • Tough ceramics, rocks, soils, bone, snow and sea ice Go to
  • Transition-metal oxides Go to
  • Transmit array technology for magnetic resonance imaging Go to
  • Transport in strongly magnetized plasmas Go to
  • Transport of charge carriers in semiconductors Go to
  • Transport of Phonons/Heat in low dimensional nano structures Go to
  • Transport properties of unsaturated soils Go to
  • Travelling waves Go to
  • Tree ring elemental analysis Go to
  • Troposphere Go to
  • Turbulence and turbulent transport processes Go to
  • Turbulence Go to
  • Turbulence Go to
  • Twentieth Century History of Optics and Opto-electronics Go to
  • Two-dimensional systems of electrons and ions Go to
  • Two nucleon transfer reactions Go to
  • Two-phase flow Go to
U
  • Ultimate limit state design Go to
  • Ultracold atomic Fermi gases Go to
  • Ultra-cold atomic gases Go to
  • Ultrafast and ultra-intense lasers and applications Go to
    • Optics
    • Physics
    • Inertial fusion for energy
    • Astronomy
    • Chemistry
    • Biology
  • Ultrafast science Go to
  • Ultrafast (spin- and magnetization) dynamics Go to
  • Ultrafine-grained materials Go to
  • Ultra-high resolution laser spectroscopy Go to
  • Ultra-low temperature techniques and their applications for cosmology Go to
  • Ultraprecise laser spectroscopy Go to
  • Ultra short pulses Go to
  • Ultrasonics Go to
  • Unconventional superconductivity Go to
  • Underground nuclear physics Go to
  • Understanding atomic nuclei Go to
  • Unstable systems, decay and resonance phenomena Go to
  • Urban underground infrastructure Go to
  • Using storage rings for nuclear structure studies Go to
  • Utilising radioactive ions for nuclear structure studies Go to
V
  • Very high energy subnuclear physics Go to
  • Vibration and stability issues of robots Go to
  • Vibration Go to
  • Vibrations, dynamical systems, control Go to
  • Vibron model Go to
  • Viscoelasticity Go to
  • Visible laser diodes Go to
  • Voting power and voting systems Go to
W
  • Wavelets Go to
  • Wave propagation Go to
  • Waves in solids Go to
  • Waves, Solitons Go to
  • Weak interactions and Higgs boson physics Go to
  • Weak interactions in nuclei Go to
  • Weak processes in the nucleus Go to
  • Weld residual stresses, their modelling and mitigation Go to
  • Wireless communications Go to
  • Wireless communications Go to
  • Wireless communications Go to
  • Wireless networking Go to
  • Wireless technologies Go to
X
  • X-Ray and Auger-Electron spectrometry Go to
  • X-ray astronomy Go to
  • X-ray physics Go to
  • x-rays and neutrino masses. Go to
  • X-ray science Go to
Y
  • Yield design methods in the case of anisotropic soils Go to
  • Yield design methods in the case of anisotropic soils Go to
  • Yield design theory Go to
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