Vladimír Wagner
Nuclear physics institute of CAS, 250 68 Řež, Czech Republic, E_mail: [email protected]
for collaboration “Energy plus transmutation RAW”
(Russia, Belarus, Germany, Greece, Poland, Ukraine, Czech Republic …)
1. Introduction
2. Big uranium target KVINTA 2.1 Description 2.2 First set of experiments 2.3 Beam monitoring
3. ERINDA project 3.1 Project of 7 FP 3.2 Cross-section measurements
4. Conclusions and outlooks
Mart 26-27, 2011 Liblice, Czech Republic
First experiments with big uranium set-up KVINTA irradiated by deuterons
1) To have „simple set-up for benchmark studies of neutron production and transport simulation codes (for example MCNPX code).
2) Systematic of deuteron beams with energies higher then 1 GeV.
3) Measurement of neutrons and delayed neutrons during low intensive beam
4) Activation and track detectors
5) To obtain strong source of neutrons for transmutation tests
Main objectives:
Set-up: Natural uranium target: rods with Al cladding total weight 315 kg (500 kg) Sometimes lead box is used: bricks 1780 kg
KVINTA Setup"Центр Физико-Технических Проектов“
"АТОМЭНЕРГОМАШ"
QUINTA-M setup layout at the irradiation position
Target «Quinta-М»
Plate (700х400х16)
Platform
p, d
- SSNTD and AD positions at the QUINTA-M target surface
Rails
Beam window
Pad with a Pb foil monitor and SSNTD
Detector plates
Cadmium containerswith
activation detectors
Detectors plate
Track detectors
R=40
R=120
Installation of KVINTA set-up and placement of detectors
d d
mPb= 1780 кg mΣ = 2125 кg
Holes for installation and withdrawingof activation samples
Top part of lead shielding
Window of beam entry
15×15см
Lead shielding
Detector plates
Natural uranium target
Аctivation and track detectors
Part of lead Shielding
Is not shown
600
650
600
Lead shielding is possible to use for some experiments
QUINTA-M setup and equipment layout during an experiment at F-3 focus
3320
Beam extraction
Ionization chamber
Activation foil
Profilometer
QUINTA-М
Polyethylene shielding
Sc telescope
Stilbene, NE213detectors
ISOMER
30°
90°150°
Platform(turned by 3° relatively to the beam axis)
detector Не3NE213
Stilbene, NE213detectors Stilbene, NE213
detectors
1) Activation detectors2) Track detectors3) NE213, Stilben neutron detectors4) He-3 detectors
Radioactive samplesfor transmutationstudies
First irradiation - 2009
First experiment with very low intensity of beam – delayed neutrons measurement, no activation detectors
First full irradiation – March 2011
Three different energies: 2 GeV, 4 GeV and 6 GeV – low and high intensity run irradiation time – around 20 hours
0.000.01 0.12
0.05
0.000.04
0.99
0.33
0.000.02
0.56
0.20
0.000.00
0.030.02
Beam profile in front of the target - big monitors
left
rightcentre
centre
top
down0.09
0.31
0.14
0.01
0.17
0.99
0.23
0.01
Beam profile from small monitors
foil 11 foil 12
11-1 11-2 12-1 12-2
11-3 11-4 12-3 12-4
3 4
7 8
13 14 15 16
1 2
5 6
9 10
Aluminum and copper beam monitor foils
Deuteron beam 2 GeV, 4 GeV and 6 GeV
Integral number of deuterons – aluminum foil few meters from the set-up
Common measurement using ionization chamber
Common measurement of copper foil cross-section determination
Cut copper foil – beam profile determination
8 cm
The ERINDA Project
Start date: 1/1/2011Duration : 4 yearsBeam time: 2600 hoursTypical experiments: 26Support: 80 manweeks
The ERINDA Consortium13 partners- 13 facilities hours for external users
Web-site: www.erinda.orgProject Coordinator: A. Junghans
The ERINDA project is an Integrated Infrastructure Initiative (I3) funded under the 7th framework programme (FP7) of the European Commission.
ERINDATransnational Access Activities
→ measurement capabilities : quasi-monochromatic neutron beams
high-resolution neutron time-of-flight facilities thermal neutron beams charged particle beams indirect measurements (surrogate reactions) isotopic yield distributions (Penning trap)
→ neutron energy range: sub-thermal energies – several hundred MeV
high-quality nuclear data for waste transmutation or Generation IV systems
Main ERINDA tasks
February 21, 2011
AIFIRA 3.5 MV Van de Graaff accelerator 100 keV – 6 MeV CENBG Bordeaux (France)
BRR 10 MW research reactor cold and thermal IKI Budapest (Hungary)
Lolita 3.7 MV Van de Graaff accelerator 10 keV – 1.5 MeV FZ Karlsruhe (Germany)
nELBE 40 MeV superconducting electron linac 20 keV – 8 MeV, 14 MeV FZ Dresden (Germany)
PIAF CV28 cyclotron and 3.7 MV Van de Graaff accelerator 24 keV – 19 MeV PTB Braunschweig (Germany)
TSL 180 MeV cyclotron 20 MeV – 175 MeV UU-TSL Uppsala (Sweden)
CEA 4 MV Van de Graaff accelerator, 7 MV tandem accelerator, 19 MeV electron linac 30 keV – 20 MeV CEA Bruyéres-le-Chatel (France)
n_TOF 20 GeV proton beam of the PS + spallation neutron source 1 eV – 250 MeV CERN Geneva (Switzerland/France)
Tandem-ALTO 15 MV tandem + photo-fission source up to 20 MeV, IPN Orsay (France) (ALTO) up to 50 MeV
Participated neutron sources
Accelerator – Cyclotron U-120M
Beam: protons with energy from 10 up to 24 MeV (3μA)
deuterons with energy from 10 up to 20 MeV (3μA) 3He with energy from 17 up to 57 MeV (2μA) alpha with energy from 20 up to 40 MeV (2μA)
High intensive 1011 cm-2s-1 negative ion beam:
protons with energy from 10 up to 37 MeV (20μA) deuterons with energy from 10 up to 20 MeV (10μA)
Different tasks:
1) Radiopharmaceutical research and production
2) Astrophysical reaction research (mainly with 3He beam)
3) Neutron research using two different neutron generators
Fast neutron generators
NG 2 – white source on H- beam (heavy water target) with very high neutron flux 1011 cm-2s-1
spectrum range from 2 up to 34 MeV neutron irradiation of small samples, integral bechmark tests of fusion (IFMIF) relevant neutron activation cross sections
NG 2 - quasi monoenergetic p – 7Li source with neutron flux 109 cm-2s-1, energy 18 – 35 MeV
Negative ions high intensity for activation and irradiation experiments
NG - 2
Lower intensive beam for spectroscopic measurement
NG - 1
NG 1 – white neutron source based on heavy watter, berylium and lithium targets (
Conclusions and outlooks
• Different targets and set-ups use Nuclotron accelerator
• New set-up – big uranium target Kvinta
• Main tasks: 1) Measurement of neutron distribution 2) Benchmark of simulation codes 3) Intensive source of neutrons for transmutation studies
• First set of experiments – deuterons with energy 2 GeV, 4 GeV and 6 GeV (March 2011)
• Low intensive beam – electronic neutron detectors, delayed neutron measurement
• High intensive beam – activation and track detectors, transmutation studies
• Test of beam monitors (determination of new important cross-sections of deuteron reactions on copper
• Start o systematic studies using high energy deuteron beam
• New FP-7 project ERNIDA – possibility of studies using different european neutron sources