Optimizing the light output of a plastic scintillator and SiPM based detector through optical characterization and simulation: a case study for POLAR-2 Article Swipe

View

Nicolas De Angelis , F. Cadoux , Coralie Husi , Merlin Kole , S. Mianowski ·

YOU? · · 2025 · Open Access · · DOI: https://doi.org/10.1088/1748-0221/20/02/p02010

The combination of plastic scintillators with Silicon Photo-Multipliers (SiPMs) is widely used for detecting radiation in high-energy astrophysics, particle physics, neutrino physics, or medical physics. An example of application for this kind of detectors are Compton polarimeters such as POLAR-2 [1,2,3] or LEAP [4,5,6] for which a low-Z material is needed for the Compton effect to be dominant down to as low energy as possible. Such detectors aim to measure low energy Compton depositions in organic scintillators which produce small amounts of optical light because of the low energy deposited and the low scintillation efficiency, and for which optimizing the instrumental optical properties consequently imperative. The light collection efficiency of such a device was studied with a focus on the POLAR-2 Gamma-Ray Burst polarimeter. POLAR-2 consists of a segmented array of 6400 elongated plastic scintillators divided into 100 modules, all read out by SiPMs. The conversion of incoming γ -rays into readable signal goes through the production and collection of optical light, which has been optimized both through measurements and simulations. The optical elements of the POLAR-2 polarimeter prototype module were optically characterized and an optical simulation based on Geant4 was developed to fully model its optical performances. The results from simulations were used to optimize the design and finally to verify its performance. The study resulted in a detector capable of measuring energy depositions of several keV. In addition, an important finding of this work is the impact of the plastic scintillator surface roughness on the light collection. It was found that a plastic scintillator with a higher scintillation efficiency but made of a softer material, hence with a rougher surface, was not necessarily the best option to optimize the light collection. Furthermore, in order to optimize the optical crosstalk between different channels, a production technique for very thin (∼150 μm) and reusable silicone-based optical coupling pads was developed. This method can be adapted to produce either standalone pads or to directly mold a layer on any SiPM to be later coupled to the scintillators. After an introductory discussion describing the need of a large scale GRB polarimeter like POLAR-2, the optical design and characterization of the polarimeter modules that compose its sensitive part are described. The Geant4-based optical simulations of the POLAR-2 modules and the impact of the optical properties of its various elements on the light collection efficiency of the instrument are later presented. The work is finally summarized and an outlook is given on the potential applications of the POLAR-2 optical characterization and simulation work to other experiments employing similar elements.

Related Topics

Concepts

Silicon photomultiplier Scintillator Detector Characterization (materials science) Polar Optics Physics Optoelectronics Materials science Astronomy

Metadata

Type: article
Language: en
Landing Page: https://doi.org/10.1088/1748-0221/20/02/p02010
OA Status: hybrid
Cited By: 1
References: 28
Related Works: 10
OpenAlex ID: https://openalex.org/W4407407617

All OpenAlex metadata

Raw OpenAlex JSON

OpenAlex ID: https://openalex.org/W4407407617

Canonical identifier for this work in OpenAlex
DOI: https://doi.org/10.1088/1748-0221/20/02/p02010

Digital Object Identifier
Title: Optimizing the light output of a plastic scintillator and SiPM based detector through optical characterization and simulation: a case study for POLAR-2

Work title
Type: article

OpenAlex work type
Language: en

Primary language
Publication year: 2025

Year of publication
Publication date: 2025-02-01

Full publication date if available
Authors: Nicolas De Angelis, F. Cadoux, Coralie Husi, Merlin Kole, S. Mianowski

List of authors in order
Landing page: https://doi.org/10.1088/1748-0221/20/02/p02010

Publisher landing page
Open access: Yes

Whether a free full text is available
OA status: hybrid

Open access status per OpenAlex
OA URL: https://doi.org/10.1088/1748-0221/20/02/p02010

Direct OA link when available
Concepts: Silicon photomultiplier, Scintillator, Detector, Characterization (materials science), Polar, Optics, Physics, Optoelectronics, Materials science, Astronomy

Top concepts (fields/topics) attached by OpenAlex
Cited by: 1

Total citation count in OpenAlex
Citations by year (recent): 2025: 1

Per-year citation counts (last 5 years)
References (count): 28

Number of works referenced by this work
Related works (count): 10

Other works algorithmically related by OpenAlex

Full payload

id	https://openalex.org/W4407407617
doi	https://doi.org/10.1088/1748-0221/20/02/p02010
ids.doi	https://doi.org/10.1088/1748-0221/20/02/p02010
ids.openalex	https://openalex.org/W4407407617
fwci	6.11053543
type	article
title	Optimizing the light output of a plastic scintillator and SiPM based detector through optical characterization and simulation: a case study for POLAR-2
biblio.issue	02
biblio.volume	20
biblio.last_page	P02010
biblio.first_page	P02010
topics[0].id	https://openalex.org/T11216
topics[0].field.id	https://openalex.org/fields/31
topics[0].field.display_name	Physics and Astronomy
topics[0].score	1.0
topics[0].domain.id	https://openalex.org/domains/3
topics[0].domain.display_name	Physical Sciences
topics[0].subfield.id	https://openalex.org/subfields/3108
topics[0].subfield.display_name	Radiation
topics[0].display_name	Radiation Detection and Scintillator Technologies
topics[1].id	https://openalex.org/T11176
topics[1].field.id	https://openalex.org/fields/27
topics[1].field.display_name	Medicine
topics[1].score	0.9977999925613403
topics[1].domain.id	https://openalex.org/domains/4
topics[1].domain.display_name	Health Sciences
topics[1].subfield.id	https://openalex.org/subfields/2740
topics[1].subfield.display_name	Pulmonary and Respiratory Medicine
topics[1].display_name	Radiation Therapy and Dosimetry
topics[2].id	https://openalex.org/T10522
topics[2].field.id	https://openalex.org/fields/27
topics[2].field.display_name	Medicine
topics[2].score	0.9973999857902527
topics[2].domain.id	https://openalex.org/domains/4
topics[2].domain.display_name	Health Sciences
topics[2].subfield.id	https://openalex.org/subfields/2741
topics[2].subfield.display_name	Radiology, Nuclear Medicine and Imaging
topics[2].display_name	Medical Imaging Techniques and Applications
is_xpac	False
apc_list
apc_paid
concepts[0].id	https://openalex.org/C104335537
concepts[0].level	4
concepts[0].score	0.9578021764755249
concepts[0].wikidata	https://www.wikidata.org/wiki/Q1085747
concepts[0].display_name	Silicon photomultiplier
concepts[1].id	https://openalex.org/C161694136
concepts[1].level	3
concepts[1].score	0.939540445804596
concepts[1].wikidata	https://www.wikidata.org/wiki/Q910990
concepts[1].display_name	Scintillator
concepts[2].id	https://openalex.org/C94915269
concepts[2].level	2
concepts[2].score	0.6992479562759399
concepts[2].wikidata	https://www.wikidata.org/wiki/Q1834857
concepts[2].display_name	Detector
concepts[3].id	https://openalex.org/C2780841128
concepts[3].level	2
concepts[3].score	0.5941159725189209
concepts[3].wikidata	https://www.wikidata.org/wiki/Q5073781
concepts[3].display_name	Characterization (materials science)
concepts[4].id	https://openalex.org/C29705727
concepts[4].level	2
concepts[4].score	0.5223904252052307
concepts[4].wikidata	https://www.wikidata.org/wiki/Q294562
concepts[4].display_name	Polar
concepts[5].id	https://openalex.org/C120665830
concepts[5].level	1
concepts[5].score	0.5116317868232727
concepts[5].wikidata	https://www.wikidata.org/wiki/Q14620
concepts[5].display_name	Optics
concepts[6].id	https://openalex.org/C121332964
concepts[6].level	0
concepts[6].score	0.406727135181427
concepts[6].wikidata	https://www.wikidata.org/wiki/Q413
concepts[6].display_name	Physics
concepts[7].id	https://openalex.org/C49040817
concepts[7].level	1
concepts[7].score	0.4064701199531555
concepts[7].wikidata	https://www.wikidata.org/wiki/Q193091
concepts[7].display_name	Optoelectronics
concepts[8].id	https://openalex.org/C192562407
concepts[8].level	0
concepts[8].score	0.3957538604736328
concepts[8].wikidata	https://www.wikidata.org/wiki/Q228736
concepts[8].display_name	Materials science
concepts[9].id	https://openalex.org/C1276947
concepts[9].level	1
concepts[9].score	0.08202645182609558
concepts[9].wikidata	https://www.wikidata.org/wiki/Q333
concepts[9].display_name	Astronomy
keywords[0].id	https://openalex.org/keywords/silicon-photomultiplier
keywords[0].score	0.9578021764755249
keywords[0].display_name	Silicon photomultiplier
keywords[1].id	https://openalex.org/keywords/scintillator
keywords[1].score	0.939540445804596
keywords[1].display_name	Scintillator
keywords[2].id	https://openalex.org/keywords/detector
keywords[2].score	0.6992479562759399
keywords[2].display_name	Detector
keywords[3].id	https://openalex.org/keywords/characterization
keywords[3].score	0.5941159725189209
keywords[3].display_name	Characterization (materials science)
keywords[4].id	https://openalex.org/keywords/polar
keywords[4].score	0.5223904252052307
keywords[4].display_name	Polar
keywords[5].id	https://openalex.org/keywords/optics
keywords[5].score	0.5116317868232727
keywords[5].display_name	Optics
keywords[6].id	https://openalex.org/keywords/physics
keywords[6].score	0.406727135181427
keywords[6].display_name	Physics
keywords[7].id	https://openalex.org/keywords/optoelectronics
keywords[7].score	0.4064701199531555
keywords[7].display_name	Optoelectronics
keywords[8].id	https://openalex.org/keywords/materials-science
keywords[8].score	0.3957538604736328
keywords[8].display_name	Materials science
keywords[9].id	https://openalex.org/keywords/astronomy
keywords[9].score	0.08202645182609558
keywords[9].display_name	Astronomy
language	en
locations[0].id	doi:10.1088/1748-0221/20/02/p02010
locations[0].is_oa	True
locations[0].source.id	https://openalex.org/S116045149
locations[0].source.issn	1748-0221
locations[0].source.type	journal
locations[0].source.is_oa	False
locations[0].source.issn_l	1748-0221
locations[0].source.is_core	True
locations[0].source.is_in_doaj	False
locations[0].source.display_name	Journal of Instrumentation
locations[0].source.host_organization	https://openalex.org/P4310311669
locations[0].source.host_organization_name	Institute of Physics
locations[0].source.host_organization_lineage	https://openalex.org/P4310311669
locations[0].source.host_organization_lineage_names	Institute of Physics
locations[0].license	cc-by
locations[0].pdf_url
locations[0].version	publishedVersion
locations[0].raw_type	journal-article
locations[0].license_id	https://openalex.org/licenses/cc-by
locations[0].is_accepted	True
locations[0].is_published	True
locations[0].raw_source_name	Journal of Instrumentation
locations[0].landing_page_url	https://doi.org/10.1088/1748-0221/20/02/p02010
indexed_in	crossref
authorships[0].author.id	https://openalex.org/A5080651704
authorships[0].author.orcid	https://orcid.org/0000-0002-2498-0213
authorships[0].author.display_name	Nicolas De Angelis
authorships[0].author_position	first
authorships[0].raw_author_name	Nicolas De Angelis
authorships[0].is_corresponding	False
authorships[1].author.id	https://openalex.org/A5001813833
authorships[1].author.orcid
authorships[1].author.display_name	F. Cadoux
authorships[1].author_position	middle
authorships[1].raw_author_name	Franck Cadoux
authorships[1].is_corresponding	False
authorships[2].author.id	https://openalex.org/A5071579459
authorships[2].author.orcid
authorships[2].author.display_name	Coralie Husi
authorships[2].author_position	middle
authorships[2].raw_author_name	Coralie Husi
authorships[2].is_corresponding	False
authorships[3].author.id	https://openalex.org/A5009633218
authorships[3].author.orcid	https://orcid.org/0000-0003-0441-4959
authorships[3].author.display_name	Merlin Kole
authorships[3].author_position	middle
authorships[3].raw_author_name	Merlin Kole
authorships[3].is_corresponding	False
authorships[4].author.id	https://openalex.org/A5039134881
authorships[4].author.orcid	https://orcid.org/0000-0003-2514-6156
authorships[4].author.display_name	S. Mianowski
authorships[4].author_position	last
authorships[4].raw_author_name	Sławomir Mianowski
authorships[4].is_corresponding	False
has_content.pdf	False
has_content.grobid_xml	False
is_paratext	False
open_access.is_oa	True
open_access.oa_url	https://doi.org/10.1088/1748-0221/20/02/p02010
open_access.oa_status	hybrid
open_access.any_repository_has_fulltext	False
created_date	2025-10-10T00:00:00
display_name	Optimizing the light output of a plastic scintillator and SiPM based detector through optical characterization and simulation: a case study for POLAR-2
has_fulltext	False
is_retracted	False
updated_date	2025-11-06T03:46:38.306776
primary_topic.id	https://openalex.org/T11216
primary_topic.field.id	https://openalex.org/fields/31
primary_topic.field.display_name	Physics and Astronomy
primary_topic.score	1.0
primary_topic.domain.id	https://openalex.org/domains/3
primary_topic.domain.display_name	Physical Sciences
primary_topic.subfield.id	https://openalex.org/subfields/3108
primary_topic.subfield.display_name	Radiation
primary_topic.display_name	Radiation Detection and Scintillator Technologies
related_works	https://openalex.org/W2545281817, https://openalex.org/W1122808991, https://openalex.org/W2191527367, https://openalex.org/W2585204038, https://openalex.org/W3080146630, https://openalex.org/W2494309615, https://openalex.org/W4248482873, https://openalex.org/W2083171769, https://openalex.org/W4388936112, https://openalex.org/W3172327268
cited_by_count	1
counts_by_year[0].year	2025
counts_by_year[0].cited_by_count	1
locations_count	1
best_oa_location.id	doi:10.1088/1748-0221/20/02/p02010
best_oa_location.is_oa	True
best_oa_location.source.id	https://openalex.org/S116045149
best_oa_location.source.issn	1748-0221
best_oa_location.source.type	journal
best_oa_location.source.is_oa	False
best_oa_location.source.issn_l	1748-0221
best_oa_location.source.is_core	True
best_oa_location.source.is_in_doaj	False
best_oa_location.source.display_name	Journal of Instrumentation
best_oa_location.source.host_organization	https://openalex.org/P4310311669
best_oa_location.source.host_organization_name	Institute of Physics
best_oa_location.source.host_organization_lineage	https://openalex.org/P4310311669
best_oa_location.source.host_organization_lineage_names	Institute of Physics
best_oa_location.license	cc-by
best_oa_location.pdf_url
best_oa_location.version	publishedVersion
best_oa_location.raw_type	journal-article
best_oa_location.license_id	https://openalex.org/licenses/cc-by
best_oa_location.is_accepted	True
best_oa_location.is_published	True
best_oa_location.raw_source_name	Journal of Instrumentation
best_oa_location.landing_page_url	https://doi.org/10.1088/1748-0221/20/02/p02010
primary_location.id	doi:10.1088/1748-0221/20/02/p02010
primary_location.is_oa	True
primary_location.source.id	https://openalex.org/S116045149
primary_location.source.issn	1748-0221
primary_location.source.type	journal
primary_location.source.is_oa	False
primary_location.source.issn_l	1748-0221
primary_location.source.is_core	True
primary_location.source.is_in_doaj	False
primary_location.source.display_name	Journal of Instrumentation
primary_location.source.host_organization	https://openalex.org/P4310311669
primary_location.source.host_organization_name	Institute of Physics
primary_location.source.host_organization_lineage	https://openalex.org/P4310311669
primary_location.source.host_organization_lineage_names	Institute of Physics
primary_location.license	cc-by
primary_location.pdf_url
primary_location.version	publishedVersion
primary_location.raw_type	journal-article
primary_location.license_id	https://openalex.org/licenses/cc-by
primary_location.is_accepted	True
primary_location.is_published	True
primary_location.raw_source_name	Journal of Instrumentation
primary_location.landing_page_url	https://doi.org/10.1088/1748-0221/20/02/p02010
publication_date	2025-02-01
publication_year	2025
referenced_works	https://openalex.org/W3180984353, https://openalex.org/W4385359388, https://openalex.org/W3192069555, https://openalex.org/W6799547152, https://openalex.org/W2756992083, https://openalex.org/W3084100347, https://openalex.org/W4401336470, https://openalex.org/W2134951282, https://openalex.org/W2891671240, https://openalex.org/W4385075173, https://openalex.org/W2326494589, https://openalex.org/W2004407894, https://openalex.org/W6660867997, https://openalex.org/W4249954177, https://openalex.org/W6733814307, https://openalex.org/W1973534257, https://openalex.org/W822321729, https://openalex.org/W1993594644, https://openalex.org/W2059718340, https://openalex.org/W6944287932, https://openalex.org/W293731459, https://openalex.org/W3046681482, https://openalex.org/W4323308596, https://openalex.org/W6923790910, https://openalex.org/W3197401627, https://openalex.org/W3189392850, https://openalex.org/W2040740967, https://openalex.org/W2589982035
referenced_works_count	28
abstract_inverted_index.a	47, 112, 117, 128, 219, 254, 258, 265, 270, 295, 325, 345
abstract_inverted_index.An	26
abstract_inverted_index.In	229
abstract_inverted_index.It	250
abstract_inverted_index.an	185, 231, 338, 404
abstract_inverted_index.as	39, 61, 64
abstract_inverted_index.be	57, 314, 331
abstract_inverted_index.by	143
abstract_inverted_index.in	16, 75, 218, 285
abstract_inverted_index.is	10, 50, 237, 400, 406
abstract_inverted_index.of	3, 28, 33, 82, 86, 110, 127, 131, 147, 160, 175, 222, 226, 234, 240, 264, 344, 357, 372, 379, 383, 392, 412
abstract_inverted_index.on	119, 189, 246, 327, 387, 408
abstract_inverted_index.or	23, 42, 321
abstract_inverted_index.to	56, 60, 69, 193, 205, 211, 279, 287, 316, 322, 330, 334, 420
abstract_inverted_index.γ	149
abstract_inverted_index.100	138
abstract_inverted_index.GRB	348
abstract_inverted_index.The	1, 106, 145, 172, 199, 215, 368, 398
abstract_inverted_index.aim	68
abstract_inverted_index.all	140
abstract_inverted_index.and	91, 96, 158, 170, 184, 209, 303, 355, 376, 403, 417
abstract_inverted_index.any	328
abstract_inverted_index.are	35, 366, 395
abstract_inverted_index.but	262
abstract_inverted_index.can	313
abstract_inverted_index.for	13, 30, 45, 52, 97, 298
abstract_inverted_index.has	164
abstract_inverted_index.its	196, 213, 363, 384
abstract_inverted_index.low	62, 71, 88, 93
abstract_inverted_index.not	274
abstract_inverted_index.out	142
abstract_inverted_index.the	53, 87, 92, 100, 120, 156, 176, 207, 238, 241, 247, 276, 281, 289, 335, 342, 352, 358, 373, 377, 380, 388, 393, 409, 413
abstract_inverted_index.was	114, 191, 251, 273, 309
abstract_inverted_index.6400	132
abstract_inverted_index.LEAP	43
abstract_inverted_index.SiPM	329
abstract_inverted_index.Such	66
abstract_inverted_index.This	311
abstract_inverted_index.been	165
abstract_inverted_index.best	277
abstract_inverted_index.both	167
abstract_inverted_index.down	59
abstract_inverted_index.from	201
abstract_inverted_index.goes	154
abstract_inverted_index.into	137, 151
abstract_inverted_index.keV.	228
abstract_inverted_index.kind	32
abstract_inverted_index.like	350
abstract_inverted_index.made	263
abstract_inverted_index.mold	324
abstract_inverted_index.need	343
abstract_inverted_index.pads	308, 320
abstract_inverted_index.part	365
abstract_inverted_index.read	141
abstract_inverted_index.such	38, 111
abstract_inverted_index.that	253, 361
abstract_inverted_index.thin	300
abstract_inverted_index.this	31, 235
abstract_inverted_index.used	12, 204
abstract_inverted_index.very	299
abstract_inverted_index.were	181, 203
abstract_inverted_index.with	6, 116, 257, 269
abstract_inverted_index.work	236, 399, 419
abstract_inverted_index.μm)	302
abstract_inverted_index.-rays	150
abstract_inverted_index.After	337
abstract_inverted_index.Burst	123
abstract_inverted_index.array	130
abstract_inverted_index.based	188
abstract_inverted_index.focus	118
abstract_inverted_index.found	252
abstract_inverted_index.fully	194
abstract_inverted_index.given	407
abstract_inverted_index.hence	268
abstract_inverted_index.large	346
abstract_inverted_index.later	332, 396
abstract_inverted_index.layer	326
abstract_inverted_index.light	84, 107, 248, 282, 389
abstract_inverted_index.low-Z	48
abstract_inverted_index.model	195
abstract_inverted_index.order	286
abstract_inverted_index.other	421
abstract_inverted_index.scale	347
abstract_inverted_index.small	80
abstract_inverted_index.study	216
abstract_inverted_index.which	46, 78, 98, 163
abstract_inverted_index.Geant4	190
abstract_inverted_index.SiPMs.	144
abstract_inverted_index.design	208, 354
abstract_inverted_index.device	113
abstract_inverted_index.effect	55
abstract_inverted_index.either	318
abstract_inverted_index.energy	63, 72, 89, 224
abstract_inverted_index.higher	259
abstract_inverted_index.impact	239, 378
abstract_inverted_index.light,	162
abstract_inverted_index.method	312
abstract_inverted_index.module	180
abstract_inverted_index.needed	51
abstract_inverted_index.option	278
abstract_inverted_index.signal	153
abstract_inverted_index.softer	266
abstract_inverted_index.verify	212
abstract_inverted_index.widely	11
abstract_inverted_index.(SiPMs)	9
abstract_inverted_index.(∼150	301
abstract_inverted_index.Compton	36, 54, 73
abstract_inverted_index.POLAR-2	40, 121, 125, 177, 374, 414
abstract_inverted_index.Silicon	7
abstract_inverted_index.[1,2,3]	41
abstract_inverted_index.[4,5,6]	44
abstract_inverted_index.adapted	315
abstract_inverted_index.amounts	81
abstract_inverted_index.because	85
abstract_inverted_index.between	292
abstract_inverted_index.capable	221
abstract_inverted_index.compose	362
abstract_inverted_index.coupled	333
abstract_inverted_index.divided	136
abstract_inverted_index.example	27
abstract_inverted_index.finally	210, 401
abstract_inverted_index.finding	233
abstract_inverted_index.measure	70
abstract_inverted_index.medical	24
abstract_inverted_index.modules	360, 375
abstract_inverted_index.optical	83, 102, 161, 173, 186, 197, 290, 306, 353, 370, 381, 415
abstract_inverted_index.organic	76
abstract_inverted_index.outlook	405
abstract_inverted_index.plastic	4, 134, 242, 255
abstract_inverted_index.produce	79, 317
abstract_inverted_index.results	200
abstract_inverted_index.rougher	271
abstract_inverted_index.several	227
abstract_inverted_index.similar	424
abstract_inverted_index.studied	115
abstract_inverted_index.surface	244
abstract_inverted_index.through	155, 168
abstract_inverted_index.various	385
abstract_inverted_index.Abstract	0
abstract_inverted_index.POLAR-2,	351
abstract_inverted_index.consists	126
abstract_inverted_index.coupling	307
abstract_inverted_index.detector	220
abstract_inverted_index.directly	323
abstract_inverted_index.dominant	58
abstract_inverted_index.elements	174, 386
abstract_inverted_index.incoming	148
abstract_inverted_index.material	49
abstract_inverted_index.modules,	139
abstract_inverted_index.neutrino	21
abstract_inverted_index.optimize	206, 280, 288
abstract_inverted_index.particle	19
abstract_inverted_index.physics,	20, 22
abstract_inverted_index.physics.	25
abstract_inverted_index.readable	152
abstract_inverted_index.resulted	217
abstract_inverted_index.reusable	304
abstract_inverted_index.surface,	272
abstract_inverted_index.Gamma-Ray	122
abstract_inverted_index.addition,	230
abstract_inverted_index.channels,	294
abstract_inverted_index.crosstalk	291
abstract_inverted_index.deposited	90
abstract_inverted_index.detecting	14
abstract_inverted_index.detectors	34, 67
abstract_inverted_index.developed	192
abstract_inverted_index.different	293
abstract_inverted_index.elements.	425
abstract_inverted_index.elongated	133
abstract_inverted_index.employing	423
abstract_inverted_index.important	232
abstract_inverted_index.material,	267
abstract_inverted_index.measuring	223
abstract_inverted_index.optically	182
abstract_inverted_index.optimized	166
abstract_inverted_index.possible.	65
abstract_inverted_index.potential	410
abstract_inverted_index.prototype	179
abstract_inverted_index.radiation	15
abstract_inverted_index.roughness	245
abstract_inverted_index.segmented	129
abstract_inverted_index.sensitive	364
abstract_inverted_index.technique	297
abstract_inverted_index.collection	108, 159, 390
abstract_inverted_index.conversion	146
abstract_inverted_index.described.	367
abstract_inverted_index.describing	341
abstract_inverted_index.developed.	310
abstract_inverted_index.discussion	340
abstract_inverted_index.efficiency	109, 261, 391
abstract_inverted_index.instrument	394
abstract_inverted_index.optimizing	99
abstract_inverted_index.presented.	397
abstract_inverted_index.production	157, 296
abstract_inverted_index.properties	103, 382
abstract_inverted_index.simulation	187, 418
abstract_inverted_index.standalone	319
abstract_inverted_index.summarized	402
abstract_inverted_index.application	29
abstract_inverted_index.collection.	249, 283
abstract_inverted_index.combination	2
abstract_inverted_index.depositions	74, 225
abstract_inverted_index.efficiency,	95
abstract_inverted_index.experiments	422
abstract_inverted_index.high-energy	17
abstract_inverted_index.imperative.	105
abstract_inverted_index.necessarily	275
abstract_inverted_index.polarimeter	178, 349, 359
abstract_inverted_index.simulations	202, 371
abstract_inverted_index.Furthermore,	284
abstract_inverted_index.Geant4-based	369
abstract_inverted_index.applications	411
abstract_inverted_index.consequently	104
abstract_inverted_index.instrumental	101
abstract_inverted_index.introductory	339
abstract_inverted_index.measurements	169
abstract_inverted_index.performance.	214
abstract_inverted_index.polarimeter.	124
abstract_inverted_index.polarimeters	37
abstract_inverted_index.scintillator	243, 256
abstract_inverted_index.simulations.	171
abstract_inverted_index.astrophysics,	18
abstract_inverted_index.characterized	183
abstract_inverted_index.performances.	198
abstract_inverted_index.scintillation	94, 260
abstract_inverted_index.scintillators	5, 77, 135
abstract_inverted_index.scintillators.	336
abstract_inverted_index.silicone-based	305
abstract_inverted_index.characterization	356, 416
abstract_inverted_index.Photo-Multipliers	8
cited_by_percentile_year.max	95
cited_by_percentile_year.min	91
countries_distinct_count	0
institutions_distinct_count	5
citation_normalized_percentile.value	0.85895356
citation_normalized_percentile.is_in_top_1_percent	False
citation_normalized_percentile.is_in_top_10_percent	True