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@ARTICLE{Andreev:616767,
author = {Andreev, V. and Arratia, M. and Baghdasaryan, A. and Baty,
A. and Begzsuren, K. and Bolz, A. and Boudry, V. and Brandt,
G. and Britzger, D. and Buniatyan, A. and Bystritskaya, L.
and Campbell, A. J. and Cantun Avila, K. B. and Cerny, K.
and Chekelian, V. and Chen, Z. and Contreras, J. G. and
Cvach, J. and Dainton, J. B. and Daum, K. and Deshpande, A.
and Diaconu, C. and Drees, A. and Eckerlin, G. and Egli, S.
and Elsen, E. and Favart, L. and Fedotov, A. and Feltesse,
J. and Fleischer, M. and Fomenko, A. and Gal, C. and Gayler,
J. and Goerlich, L. and Gogitidze, N. and Gouzevitch, M. and
Grab, C. and Greenshaw, T. and Grindhammer, G. and Haidt, D.
and Henderson, R. C. W. and Hessler, J. and Hladký, J. and
Hoffmann, D. and Horisberger, R. and Hreus, T. and Huber, F.
and Jacobs, P. M. and Jacquet, M. and Janssen, T. and Jung,
A. W. and Katzy, J. and Kiesling, C. and Klein, M. and
Kleinwort, C. and Klest, H. T. and Kluth, S. and Kogler, R.
and Kostka, P. and Kretzschmar, J. and Krücker, D. and
Krüger, K. and Landon, M. P. J. and Lange, W. and Laycock,
P. and Lee, S. H. and Levonian, S. and Li, W. and Lin, J.
and Lipka, K. and List, B. and List, J. and Lobodzinski, B.
and Long, O. R. and Malinovski, E. and Martyn, H.-U. and
Maxfield, S. J. and Mehta, A. and Meyer, A. B. and Meyer, J.
and Mikocki, S. and Mikuni, V. M. and Mondal, M. M. and
Müller, K. and Nachman, B. and Naumann, Th. and Newman, P.
R. and Niebuhr, C. and Nowak, G. and Olsson, J. E. and
Ozerov, D. and Park, S. and Pascaud, C. and Patel, G. D. and
Perez, E. and Petrukhin, A. and Picuric, I. and Pitzl, D.
and Polifka, R. and Preins, S. and Radescu, V. and Raicevic,
N. and Ravdandorj, T. and Reichelt, D. and Reimer, P. and
Rizvi, E. and Robmann, P. and Roosen, R. and Rostovtsev, A.
and Rotaru, M. and Sankey, D. P. C. and Sauter, M. and
Sauvan, E. and Schmitt, S. and Schmookler, B. A. and
Schnell, G. and Schoeffel, L. and Schöning, A. and
Schumann, S. and Sefkow, F. and Shushkevich, S. and
Soloviev, Y. and Sopicki, P. and South, D. and Specka, A.
and Steder, M. and Stella, B. and Stöcker, L. and
Straumann, U. and Sun, C. and Sykora, T. and Thompson, P. D.
and Acosta, F. Torales and Traynor, D. and Tseepeldorj, B.
and Tu, Z. and Tustin, G. and Valkárová, A. and Vallée,
C. and Van Mechelen, P. and Wegener, D. and Wünsch, E. and
Žáček, J. and Zhang, J. and Zhang, Z. and Žlebčík, R.
and Zohrabyan, H. and Zomer, F.},
collaboration = {{H1 Collaboration}},
title = {{M}easurement of the 1-jettiness event shape observable in
deep-inelastic electron-proton scattering at {HERA}},
reportid = {PUBDB-2024-06521, arXiv:2403.10109. DESY-24-035},
year = {2024},
note = {45 pages, 38 tables, 13 figures},
abstract = {The H1 Collaboration reports the first measurement of the
1-jettiness event shape observable $\tau _1^b$ in
neutral-current deep-inelastic electron-proton scattering
(DIS). The observable $\tau _1^b$ is equivalent to a thrust
observable defined in the Breit frame. The data sample was
collected at the HERA ep collider in the years 2003–2007
with center-of-mass energy of $\sqrt{s}=319\,\textrm{GeV} $,
corresponding to an integrated luminosity of 351.1
$\textrm{pb}^{-1}$. Triple differential cross sections are
provided as a function of $\tau _1^b$, event virtuality
$Q^{2}$, and inelasticity y, in the kinematic region $Q^{2}
>150\,\textrm{GeV}^2 $. Single differential cross sections
are provided as a function of $\tau _1^b$ in a limited
kinematic range. Double differential cross sections are
measured, in contrast, integrated over $\tau _1^b$ and
represent the inclusive neutral-current DIS cross section
measured as a function of $Q^{2}$ and y. The data are
compared to a variety of predictions and include
long-standing and more recent Monte Carlo event generators,
predictions in fixed-order perturbative QCD where
calculations up to $\mathcal {O}(\alpha _\textrm{s} ^3)$ are
available for $\tau _1^b$ or inclusive DIS, and resummed
predictions at next-to-leading logarithmic accuracy matched
to fixed order predictions at $\mathcal {O}(\alpha
_\textrm{s} ^2)$. These comparisons reveal sensitivity of
the 1-jettiness observable to QCD parton shower and
resummation effects, as well as the modeling of
hadronization and fragmentation. Within their range of
validity, the fixed-order predictions provide a good
description of the data. Monte Carlo event generators are
predictive over the full measured range and hence their
underlying models and parameters can be constrained by
comparing to the presented data.},
keywords = {electron p: scattering (INSPIRE) / electron p: deep
inelastic scattering (INSPIRE) / deep inelastic scattering:
neutral current (INSPIRE) / cross section: measured
(INSPIRE) / quantum chromodynamics: perturbation theory
(INSPIRE) / parton: showers (INSPIRE) / numerical
calculations: Monte Carlo (INSPIRE) / differential cross
section: measured (INSPIRE) / momentum transfer dependence
(INSPIRE) / event shape analysis (INSPIRE) / kinematics
(INSPIRE) / DESY HERA Stor (INSPIRE) / H1 (INSPIRE) /
fragmentation (INSPIRE) / sensitivity (INSPIRE) /
resummation (INSPIRE) / thrust (INSPIRE) / Breit frame
(INSPIRE) / hadronization (INSPIRE) / data analysis method
(INSPIRE) / experimental results (INSPIRE) / 319 GeV-cms
(INSPIRE)},
cin = {H1},
ddc = {530},
cid = {I:(DE-H253)H1-20120806},
pnm = {611 - Fundamental Particles and Forces (POF4-611)},
pid = {G:(DE-HGF)POF4-611},
experiment = {EXP:(DE-588)4443767-5},
typ = {PUB:(DE-HGF)25},
eprint = {2403.10109},
howpublished = {arXiv:2403.10109},
archivePrefix = {arXiv},
SLACcitation = {$\%\%CITATION$ = $arXiv:2403.10109;\%\%$},
doi = {10.3204/PUBDB-2024-06521},
url = {https://bib-pubdb1.desy.de/record/616767},
}
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