INIS
monte carlo method
95%
fuels
84%
simulation
67%
coupling
56%
physics
52%
reactors
51%
modeling
46%
burnup
44%
solutions
38%
applications
38%
benchmarks
36%
levels
34%
comparative evaluations
33%
thermal hydraulics
31%
performance
28%
ants
28%
power
27%
transients
26%
pwr type reactors
26%
wwer type reactors
25%
data
22%
interfaces
22%
tools
22%
implementation
21%
steady-state conditions
21%
validation
20%
experimental data
20%
reactor physics
19%
fuel assemblies
19%
energy
19%
feedback
18%
neutron transport
18%
control rods
16%
transport
16%
finland
15%
design
15%
power distribution
14%
time dependence
14%
district heating
13%
small modular reactors
13%
water
12%
accuracy
12%
reactor cores
12%
group constants
11%
nuclear reactors
10%
geometry
10%
distribution
10%
nuclear fuels
10%
boron
10%
Keyphrases
Serpent
95%
Serpent 2
87%
Multiphysics
54%
Fuel Behavior
50%
Neutronics
50%
Monte Carlo Code
46%
SUBCHANFLOW
43%
Pin-by-pin
35%
FINIX
33%
Burnup Calculation
28%
Kraken
24%
Full Core
24%
Reactor Physics
22%
VVER-1000
21%
Fuel Temperature
20%
Thermal-hydraulics
20%
Reactor
18%
Finland
17%
Multiphysics Simulation
16%
Monte Carlo
16%
Burnup
15%
Fuel Assembly
15%
Small Modular Reactor
14%
Monte Carlo Neutron Transport
13%
Reactor Core
13%
District Heating Reactor
13%
Steady State
13%
Technical Research
13%
TRANSURANUS
12%
VVER-1000 Reactor
12%
Group Constants
11%
Control Rod
11%
Computational Framework
11%
Coolant
11%
Temperature Distribution
10%
Coupled Calculation
10%
Monte Carlo Transport Code
10%
Continuous Energy
10%
Engineering
Neutronics
100%
Transients
74%
Burnup
41%
Thermal Hydraulics
39%
Control Rod
28%
Energy Engineering
27%
Fuel Assembly
24%
Subchannel
21%
Reactor Dynamics
20%
Power Distribution
20%
Internals
17%
Good Agreement
17%
Technical Research Centre
16%
District Heating
16%
Reactor Core
15%
Neutron Transport
15%
Small Modular Reactor
14%
Code Performance
13%
Fuel Rod
11%
Rod
11%
Light Water Reactors
10%
Nuclear Reactor
10%