{"@context":"http://schema.org","@id":"https://doi.org/10.17182/hepdata.82958.v1","@reverse":{"isBasedOn":[{"@type":"ScholarlyArticle","identifier":{"@type":"PropertyValue","propertyID":"URL","value":"https://inspirehep.net/literature/1655631"}},{"@id":"https://doi.org/10.1103/PhysRevD.98.092003","@type":"JournalArticle"}]},"@type":"Dataset","additionalType":"Collection","author":{"@type":"Organization","name":"COMPASS Collaboration"},"creator":{"@type":"Organization","name":"COMPASS Collaboration"},"datePublished":"2018","description":"Selected partial-wave amplitudes from a partial-wave analysis (PWA) of exclusive events from the diffractive-dissociation reaction $\\pi^- p \\to \\pi^- \\pi^- \\pi^+ p$ with a 191 GeV/$c$ pion beam and a stationary proton target. The PWA was performed in 100 bins of the three-pion mass $m_{3\\pi}$ in the range between 0.5 and 2.5 GeV/$c^2$, and simultaneously in 11 non-equidistant bins of the reduced four-momentum transfer squared $t'$ (see Eq. (2) in the paper) in the range between 0.1 and 1.0 (GeV/$c$)$^2$. The PWA model consists of 88 waves (see paper and [Phys. Rev. D 95, 032004 (2017)] for a detailed description of the PWA model). The waves are uniquely defined by the quantum numbers of the 3-pion system (spin $J$, parity $P$, $C$-parity, spin projection $M \\geq 0$, and reflectivity $\\varepsilon = \\pm 1$) and the decay chain ($\\pi^-\\pi^+$ isobar and orbital angular momentum $L$ between the isobar and the bachelor pion). To identify waves, we use the shorthand notation $J^{PC} M^\\varepsilon [$isobar$] \\pi L$.\n\nOut of the 88 waves, the following subset of 14 waves was selected for a resonance-model fit:\n    $0^{-+}0^+ f_0(980) \\pi S$\n    $1^{++}0^+ \\rho(770) \\pi S$\n    $1^{++}0^+ f_0(980) \\pi P$\n    $1^{++}0^+ f_2(1270) \\pi P$\n    $1^{-+}1^+ \\rho(770) \\pi P$\n    $2^{++}1^+ \\rho(770) \\pi D$\n    $2^{++}2^+ \\rho(770) \\pi D$\n    $2^{++}1^+ f_2(1270) \\pi P$\n    $2^{-+}0^+ \\rho(770) \\pi F$\n    $2^{-+}0^+ f_2(1270) \\pi S$\n    $2^{-+}1^+ f_2(1270) \\pi S$\n    $2^{-+}0^+ f_2(1270) \\pi D$\n    $4^{++}1^+ \\rho(770) \\pi G$\n    $4^{++}1^+ f_2(1270) \\pi F$\nThe resonance-model fit uses Breit-Wigner amplitudes to describe the $m_{3\\pi}$ dependence of the amplitudes of the 14 waves simultaneously in the 11 $t'$ bins using 11 iso-vector light-meson states with $J^{PC} = 0^{-+}$, $1^{++}$, $2^{++}$, $2^{-+}$, $4^{++}$, and spin-exotic $1^{-+}$ quantum numbers (see paper for details).\n\nThe provided data tables contain all information that is necessary to repeat the resonance-model fit. The data set consists of three kinds of data tables:\n\n(i) a table with the real and imaginary parts of the normalized transition amplitudes $\\mathcal{T}_a$ of the 14 selected partial waves in the 1100 $(m_{3\\pi}, t')$ cells (see Eq. (12) in the paper). Together with the reflectivity quantum number $\\varepsilon$, which is $+1$ for all 14 waves, the wave index $a = J^{PC} M [$isobar$] \\pi L$ uniquely identifies a partial wave. The transition amplitudes define the spin-density matrix elements $\\varrho_{ab}$ for waves $a$ and $b$ according to Eq. (18). The transition amplitudes are normalized via Eqs. (9), (16), and (17) such that the partial-wave intensities $\\varrho_{aa} = |\\mathcal{T}_a|^2$ are given in units of acceptance-corrected number of events. In the paper, partial-wave intensities and relative phases are shown as a function of $m_{3\\pi}$ to discuss resonance signals and to illustrate the agreement of the model with the data (see e.g. Fig. 10ff. and the supplemental material of the paper).\n\n(ii) tables with the covariance matrices of the real and imaginary parts of the transition amplitudes $\\mathcal{T}_a$; one matrix for each of the 1100 $(m_{3\\pi}, t')$ cells. For each covariance matrix, the center of the $m_{3\\pi}$ bin and the lower and upper bounds of the $t'$ bin are given in the table header. The partial-wave labels used for the covariance matrix elements are identical to the labels in the column headers of the table of the transition amplitudes in (i). The tables are stored as yaml files in the HEPData format in the 'covariance_matrices.tar.gz' file, which is provided as an additional resource for the table of the transition amplitudes in (i). In addition to the 1100 files for the covariance-matrix tables, the 'covariance_matrices.tar.gz' file contains the file 'submission.yaml', which lists the meta-information for the covariance-matrix tables.\n\n(iii) a table with the decay phase-space volume $I_{aa}$ (see Eq. (6)) for the 14 selected partial waves in the $m_{3\\pi}$ range from 0.5 to 2.5 GeV/$c^2$ in steps of 10 MeV/$c^2$. The values are given in arbitrary units, normalized such that $I_{aa}(m_{3\\pi} = 2.5~\\text{GeV}/c^2) = 1$. $I_{aa}$ appears in the resonance model in Eqs. (19) and (20). The partial-wave labels used for the decay phase-space volume are identical to the labels in the column headers of the table of the transition amplitudes in (i).","hasPart":[{"@id":"https://doi.org/10.17182/hepdata.82958.v1/t1","@type":"Dataset","description":"Real and imaginary parts of the normalized transition amplitudes $\\mathcal{T}_a$ of the 14 selected partial waves in the 1100 $(m_{3\\pi},...","name":"Transition Amplitudes"},{"@id":"https://doi.org/10.17182/hepdata.82958.v1/t2","@type":"Dataset","description":"Decay phase-space volume $I_{aa}$ for the 14 selected partial waves as a function of $m_{3\\pi}$, normalized such that $I_{aa}(m_{3\\pi} =...","name":"Decay Phase-Space Volume of Partial Waves"}],"identifier":[{"@type":"PropertyValue","propertyID":"HEPDataRecord","value":"https://www.hepdata.net/record/ins1655631?version=1"},{"@type":"PropertyValue","propertyID":"HEPDataRecordAlt","value":"https://www.hepdata.net/record/82958"}],"inLanguage":"en","name":"Light isovector resonances in $\\pi^- p \\to \\pi^-\\pi^-\\pi^+ p$ at 190 GeV/${\\it c}$","provider":{"@type":"Organization","name":"HEPData"},"publisher":{"@type":"Organization","name":"HEPData"},"url":"https://www.hepdata.net/record/ins1655631?version=1","version":1}