270:
136:
370:
setup, based on the VANDLE (Versatile Array of
Neutron Detectors at Low Energy) detector, is dedicated to detection of neutron time-of-flight. The setup consists of three scintillating detector modules of different sizes, with the scintiliating plastic bars coupled to PMTs.
398:
In 2023, a multiple-particle emission experiment was successful performed at the IDS for the first time. The aim of the analysis for this experiment is to study a specific decay channel that leads to gamma ray de-excitations from excited states of Si.
695:"First Accurate Normalization of the $ \ensuremath{\beta}$ -delayed $ \ensuremath{\alpha}$ Decay of $ ^{16}\mathrm{N}$ and Implications for the $ ^{12}\mathrm{C}(\ensuremath{\alpha},\ensuremath{\gamma})^{16}\mathrm{O}$ Astrophysical Reaction Rate"
237:
can be used to measure the time if takes for a neutron to travel from a sample to the detector, and calculate the neutron's energy. Alternatively, scintillation detectors are also used to determine the neutron's energy, by converting the energy to
692:
Kirsebom, O. S.; Tengblad, O.; Lica, R.; Munch, M.; Riisager, K.; Fynbo, H. O. U.; Borge, M. J. G.; Madurga, M.; Marroquin, I.; Andreyev, A. N.; Berry, T. A.; Christensen, E. R.; Fernández, P. Díaz; Doherty, D. T.; Van Duppen, P. (2018-10-03).
320:
The standard high beta-gamma efficiency configuration of the IDS consists of five HPGe clover detectors, one placed in very close proximity (60 mm) to the implantation point, and the rest slightly further away (75 mm). Signals are induced in a
823:
1181:
IDS Collaboration; Stryjczyk, M.; Andel, B.; Andreyev, A. N.; Cubiss, J.; Pakarinen, J.; Rezynkina, K.; Van Duppen, P.; Antalic, S.; Berry, T.; Borge, M. J. G.; Clisu, C.; Cox, D. M.; De Witte, H.; Fraile, L. M. (2020-08-18).
990:
Xu, Z. Y.; Madurga, M.; Grzywacz, R.; King, T. T.; Algora, A.; Andreyev, A. N.; Benito, J.; Berry, T.; Borge, M. J. G.; Costache, C.; De Witte, H.; Fijalkowska, A.; Fraile, L. M.; Fynbo, H. O. U.; Gottardo, A. (2023-07-14).
379:
The results from the IDS permanent experimental setup are useful for multiple areas of physics, in particularly for astrophysics. The experimental data taken by the IDS when measuring the probability of a particular delayed
1231:
IDS Collaboration; Lică, R.; Benzoni, G.; Rodríguez, T. R.; Borge, M. J. G.; Fraile, L. M.; Mach, H.; Morales, A. I.; Madurga, M.; Sotty, C. O.; Vedia, V.; De Witte, H.; Benito, J.; Bernard, R. N.; Berry, T. (2018-02-05).
771:
Marroquin, I.; Borge, M.J.G.; Ciemny, A.A.; de Witte, H.; Fraile, L.M.; Fynbo, H.O.U.; Garzón-Camacho, A.; Howard, A.; Johansson, H.; Jonson, B.; Kirsebom, O.S.; Koldste, G.T.; Lica, R.; Lund, M.V.; Madurga, M. (2016).
484:
IDS Collaboration; Lică, R.; Mach, H.; Fraile, L. M.; Gargano, A.; Borge, M. J. G.; Mărginean, N.; Sotty, C. O.; Vedia, V.; Andreyev, A. N.; Benzoni, G.; Bomans, P.; Borcea, R.; Coraggio, L.; Costache, C. (2016-04-04).
847:
Lică, R.; Rotaru, F.; Borge, M. J. G.; Grévy, S.; Negoiţă, F.; Poves, A.; Sorlin, O.; Andreyev, A. N.; Borcea, R.; Costache, C.; De Witte, H.; Fraile, L. M.; Greenlees, P. T.; Huyse, M.; Ionescu, A. (2019-09-11).
357:
detector array surrounding the tape onto which the beam is implanted. Around this array, the four HPGe clover detectors are placed, which allows high-efficiency detection of both charged particles and gamma rays.
206:
by measuring time differences and delays. The detectors used in this technique must be able to accurately measure the time a particle is detected, leading to a fast response time.
202:
with fast-timing electronics are needed to overcome the short nuclear lifetimes of radioisotopes. This method is known as the fast-timing technique, and is used for sequential
1125:
345:
detectors, and four HPGe clover detectors. This method has high precision measurements for low-intensity beams and can achieve good efficiency and time resolution.
304:
The specific configurations of the IDS setup correspond to different experimental purposes. These configurations include: high efficiency beta-gamma, fast-timing,
122:
254:
in the ISOLDE facility, which can use the beam from either
General Purpose Separator (GPS) or High Resolution Separator (HRS), is connected to the IDS. The
297:. In April 2023, a new support structure was installed at IDS, which allowed up to 15 extra detectors to be mounted at various angles and distances. The
51:
1040:
IDS Collaboration; Lund, M. V.; Andreyev, A.; Borge, M. J. G.; Cederkäll, J.; De Witte, H.; Fraile, L. M.; Fynbo, H. O. U.; Greenlees, P. T.;
395:
Results from experiments performed using IDS, have also been used to study isotope properties as well as confirm theoretical models.
115:
487:"Fast-timing study of the $ l$ -forbidden $ 1/{2}^{+}\ensuremath{\rightarrow}3/{2}^{+} M1$ transition in $ ^{129}\mathrm{Sn}$ "
262:, is implanted on tape, which is moved either manually or automatically depending on the specified implantation time. A movable
1050:
955:
Nuclear
Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
532:
Nuclear
Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
182:
Experiment systems can be coupled to the station for different decay measurements, using techniques such as fast timing, and
152:
1126:"The ISOLDE Decay Station (IDS) gives improved results on delayed alpha decay for 16N. New paper in Physical Review Letters"
464:"Development of the ISOLDE Decay Station and γ spectroscopic studies of exotic nuclei near the N=20 "Island of Inversion""
661:
108:
221:
spectroscopy, detectors are used to determine the position and energy of charged particle, as they create measurable
337:
The standard fast-timing spectroscopy set-up consists of a thin plastic scintillator to measure beta particles, two
1302:
282:
773:
587:
Deloncle, I; Roussière, B; Cardona, M A; Hojman, D; Kiener, J; Petkov, P; Tonev, D; Venkova, Ts (2010-01-01).
234:
1041:
528:"A digital data acquisition framework for the Versatile Array of Neutron Detectors at Low Energy (VANDLE)"
278:
949:
Lynch, K. M.; Cocolios, T. E.; Althubiti, N.; Farooq-Smith, G. J.; Gins, W.; Smith, A. J. (2017-02-01).
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Paulauskas, S. V.; Madurga, M.; Grzywacz, R.; Miller, D.; Padgett, S.; Tan, H. (2014-02-11).
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850:"Normal and intruder configurations in Si 34 populated in the β − decay of Mg 34 and Al 34"
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301:(DAQ) used to read data from the experiment, consists of a dedicated Xia Pixie-16 DAQ
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1152:"$ \ensuremath{\beta}$ -delayed $ \ensuremath{\alpha}$ decay of $ ^{16}\mathrm{N}$ "
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891:
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1044:; Howard, A. M.; Huyse, M.; Jonson, B.; Judson, D. S.; Kirsebom, O. S. (Oct 2016).
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1105:"On the simulation of limit thresholds for ISOLDE decay station neutron detector"
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384:, improved upon its previous result. This nuclear reaction is one that occurs in
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detector array with good efficiency and energy resolution. Each detector has a
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Isotope Mass
Separator On-Line Facility (ISOLDE) and Universidad de Costa Rica
993:"$ \ensuremath{\beta}$ -delayed neutron spectroscopy of $ ^{133}\mathrm{In}$ "
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1234:"Evolution of deformation in neutron-rich Ba isotopes up to $ A=150$ "
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22:
17:
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353:
The standard IDS charged-particle spectroscopy setup consists of a
135:
338:
268:
134:
1184:"Decay studies of the long-lived states in $ ^{186}\mathrm{Tl}$ "
156:
589:"Fast timing: Lifetime measurements with LaBr 3 scintillators"
273:
A high-purity germanium (HPGe) detector for the IDS experiment
281:, which can be retracted and inserted manually and one HPGe
266:
is located at the entrance and exit of the vacuum chamber.
746:"Laser Spectroscopy Of Neutron-Deficient Bismuth Isotopes"
179:. The experimental setup has been operational since 2014.
567:"Test and calibration of the IDS fast-timing electronics"
774:"Multi-particle Emission from $ {^{31}}$ Ar at ISOLDE"
951:"A simple decay-spectroscopy station at CRIS-ISOLDE"
824:"Clover™ Detectors Four Coaxial Germanium Detectors"
229:
are not charged particles, to measure their motion,
171:
techniques for a variety of applications, including
1150:Buchmann, L.; Ruprecht, G.; Ruiz, C. (2009-10-21).
242:and measuring the intensity of the produced light.
214:(PMTs) are most often employed for this technique.
100:
90:
85:
29:
914:Journal of Physics G: Nuclear and Particle Physics
139:Recently upgraded IDS setup in the ISOLDE facility
159:. The purpose of the experiment is to measure
279:high-purity germanium (HPGe) clover detectors
116:
8:
293:cooling canister, and consists of four HPGe
16:
151:) is a permanent experiment located in the
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510:
1046:"Beta-delayed proton emission from 20Mg"
1103:José Rafael Arce, G. (26 August 2015).
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662:"Neutron detection with scintillators"
186:. The IDS is able to study a range of
96:Medical Isotopes Collected from ISOLDE
15:
903:
901:
766:
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593:Journal of Physics: Conference Series
436:"ISOLDE Decay Station (IDS) | ISOLDE"
7:
910:"Fast-timing spectroscopy at ISOLDE"
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685:
479:
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277:The base IDS setup consists of four
744:Jenkinson, Megan (September 2017).
349:Charged-particle spectroscopy setup
30:List of ISOLDE experimental setups
14:
414:IDS page within the CERN website
316:High-efficiency beta-gamma setup
18:Isotope Separator On Line Device
1051:The European Physical Journal A
574:Chiang Mai University, Thailand
104:Solid State Physics Laboratory
722:10.1103/PhysRevLett.121.142701
606:10.1088/1742-6596/205/1/012044
409:IDS page on the ISOLDE website
329:, which are read by two PMTs.
1:
233:processes must be observed.
1200:10.1103/PhysRevC.102.024322
1019:10.1103/PhysRevC.108.014314
866:10.1103/PhysRevC.100.034306
645:. Spectroscopy-12-01-2010.
462:Razvan, Lics (3 Oct 2017).
225:when they pass through. As
1319:
1250:10.1103/PhysRevC.97.024305
1168:10.1103/PhysRevC.80.045803
1074:10.1140/epja/i2016-16304-x
968:10.1016/j.nima.2016.11.024
908:Fraile, L M (2017-09-01).
544:10.1016/j.nima.2013.11.028
503:10.1103/PhysRevC.93.044303
362:Neutron spectroscopy setup
565:Phrompao, Jindaratsamee.
285:. These detectors form a
283:Miniball cluster detector
34:
927:10.1088/1361-6471/aa8217
791:10.5506/APhysPolB.47.747
258:is collimated and, in a
235:Time-of-flight detectors
1042:Harkness-Brennan, L. J.
778:Acta Physica Polonica B
699:Physical Review Letters
299:Data Acquisition System
208:Scintillation detectors
190:, from light to heavy.
660:Scionix (8 Oct 2013).
639:"Neutron Spectroscopy"
274:
140:
272:
212:photomultiplier tubes
138:
388:, and is related to
368:neutron spectroscopy
323:plastic scintillator
165:radioactive isotopes
145:ISOLDE Decay Station
223:electron-hole pairs
173:nuclear engineering
26:
753:University of York
308:spectroscopy, and
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231:neutron scattering
141:
1238:Physical Review C
1188:Physical Review C
1156:Physical Review C
997:Physical Review C
854:Physical Review C
649:(12). 2010-12-01.
491:Physical Review C
390:stellar evolution
333:Fast-timing setup
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1303:CERN experiments
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246:Experiment setup
219:charged-particle
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153:ISOLDE facility
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327:beta particles
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312:spectroscopy.
260:vacuum chamber
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163:properties of
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1281:. Retrieved
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1241:
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1209:10261/225991
1191:
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1134:. Retrieved
1132:. 2018-09-28
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801:10261/151807
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672:. Retrieved
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643:Spectroscopy
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616:11336/101874
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204:decay chains
197:
181:
177:astrophysics
169:spectroscopy
148:
144:
142:
47:
468:Cern-Isolde
440:isolde.cern
382:alpha decay
264:Faraday cup
1283:2023-07-25
1274:"Greybook"
1136:2023-07-25
1130:phys.au.dk
1065:1506.04515
1010:2303.12173
833:2023-07-21
784:(3): 747.
712:1804.02040
669:scionix.nl
599:: 012044.
445:2023-07-21
420:References
194:Background
1218:219260371
1090:254112622
1082:1434-6001
1027:259919994
977:0168-9002
961:: 14–18.
936:0954-3899
892:201698163
884:2469-9985
810:0587-4254
625:1742-6596
552:0168-9002
538:: 22–28.
200:detectors
1297:Category
731:30339438
366:The IDS
295:crystals
256:ion beam
252:beamline
250:The RC4
227:neutrons
64:Miniball
60:LUCRECIA
56:ISOLTRAP
674:25 July
375:Results
355:silicon
310:neutron
240:photons
92:MEDICIS
68:MIRACLS
36:COLLAPS
1216:
1088:
1080:
1058:(10).
1025:
975:
934:
890:
882:
828:Mirion
808:
729:
623:
550:
188:nuclei
167:using
80:WISArD
44:EC-SLI
23:ISOLDE
1214:S2CID
1108:(PDF)
1086:S2CID
1060:arXiv
1023:S2CID
1005:arXiv
888:S2CID
749:(PDF)
707:arXiv
665:(PDF)
570:(PDF)
287:gamma
198:Fast
161:decay
1078:ISSN
973:ISSN
932:ISSN
880:ISSN
806:ISSN
727:PMID
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