Skip to main navigation
Skip to search
Skip to main content
VTT's Research Information Portal Home
Home
Profiles
Research output
Projects
Datasets
Research units
Research Infrastructures
Activities
Prizes
Press/Media
Impacts
Search by expertise, name or affiliation
Toroidal and poloidal momentum transport studies in JET
Tuomas Tala
, Y. Andrew
, K. Crombé
, P.C. de Vries
, X. Garbet
, N. Hawkes
, H. Nordman
, Karin Rantamäki
, et al
Culham Science Centre
Ghent University
Commissariat a l'Energie Atomique et aux Energies Alternatives (CEA)
Chalmers University of Technology
Eindhoven University of Technology (TU/e)
Institute of Plasma Physics “Pietro Caldirola” (CNR-IFP)
Risø DTU National Laboratory for Sustainable Energy
Research output
:
Contribution to journal
›
Article
›
Scientific
›
peer-review
41
Citations (Scopus)
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'Toroidal and poloidal momentum transport studies in JET'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
B-flow
12%
Collisionality
12%
Confinement Time
12%
Crash
12%
Curvature Effect
12%
Damping Mechanism
12%
Edge Pedestal
12%
Effective Momentum
12%
Energy Confinement Time
12%
Flow Shear
12%
Geodesic Acoustic Mode
25%
Geodesic Curvature
12%
Global Energy
12%
Heat Diffusivity
12%
Heat Transport
12%
Ion Temperature
37%
Local Transport
12%
Low Density
12%
Momentum Diffusivity
12%
Momentum Transport
100%
Onset Location
12%
Order of Magnitude
12%
Poloidal Velocity
100%
Profile Stiffness
12%
Radial Electric Field
12%
Reynolds Stress
25%
Self-consistent Modeling
12%
Stiffness
12%
Temperature Profile
25%
Time-dependent Transport
12%
Transport Analysis
12%
Transport Simulation
37%
Transport Studies
100%
Turbulence
25%
Velocity Profile
37%
INIS
accuracy
9%
acoustics
18%
carbon
9%
confinement
18%
confinement time
18%
damping
9%
density
9%
dynamics
9%
edge localized modes
9%
electric fields
9%
energy
9%
equilibrium
9%
geodesics
27%
heat
18%
heat transfer
9%
ion temperature
27%
ions
27%
iter tokamak
9%
jets
100%
modeling
9%
neoclassical transport theory
27%
peaks
9%
prediction
9%
reynolds number
18%
shear
9%
simulation
27%
stiffness
18%
time dependence
9%
transport
100%
turbulence
18%
values
9%
velocity
100%
Engineering
Acoustic Mode
66%
Diffusivity
66%
Driven Flow
33%
Electric Field
33%
Experimental Measurement
33%
Global Energy
33%
Heat Transport
33%
Momentum Transport
100%
Reynolds Stress
66%
Shear Flow
33%
Temperature Profile
66%
Velocity Profile
100%
Earth and Planetary Sciences
Diffusivity
66%
Electric Field
33%
Ion Temperature
100%
Shear Flow
33%
Temperature Profile
66%
Velocity Distribution
100%