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Books on the topic 'Hadronic jet'

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Author: Grafiati

Published: 10 March 2023

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1

Doglioni, Caterina. Measurement of the Inclusive Jet Cross Section with the ATLAS Detector at the Large Hadron Collider. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-30538-2.

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2

service), SpringerLink (Online, ed. Measurement of the Inclusive Jet Cross Section with the ATLAS Detector at the Large Hadron Collider. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

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3

Arguin, Jean-François. Measurement of the top quark mass with in situ jet energy scale calibration using hadronic W boson decays at CDF-II. 2006.

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4

Valente, Marco. Supersymmetric Beasts and Where to Find Them: From Novel Hadronic Reconstruction Methods to Search Results in Large Jet Multiplicity Final States at the ATLAS Experiment. Springer International Publishing AG, 2022.

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5

Wigmans, Richard. Fluctuations. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786351.003.0004.

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The energy resolution, i.e. the precision with which the energy of a showering particle can be measured, is one of the most important characteristics of a calorimeter. This resolution is determined by fluctuations in the absorption and signal formation processes. In this chapter, the different types of fluctuations that may play a role are examined, and their relative practical importance is addressed. Sources of fluctuations include fluctuations in the number of signal quanta, sampling fluctuations, fluctuations in shower leakage, as well as a variety of instrumental effects. Since the energy dependence of the different types of fluctuations is not the same, different types of fluctuations may dominate the energy resolution at low and and at high energies. An important type of fluctuations is part of the non-compensation phenomena. It concerns fluctuations in the strength of the electromagnetic component of hadronic showers. The effects of these fluctuations, which typically dominate the energy resolution for hadron and jet detection, are examined in detail. In sampling calorimeters, one particular shower particle may sometimes have catastrophic effects on the calorimeter performance. Several examples of such cases are discussed.

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6

BANFI. Hadronic Jets (second Edition) Hb. Institute of Physics Publishing, 2022.

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7

Hofmann, Werner. Jets of Hadrons. Springer, 2006.

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8

Hofmann, Werner. Jets of Hadrons. Springer, 2013.

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9

Ortuzar, Mireia Crispín. High Jet Multiplicity Physics at the LHC. Springer, 2018.

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10

Ortuzar, Mireia Crispín. High Jet Multiplicity Physics at the LHC. Springer, 2016.

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11

Doglioni, Caterina. Measurement of the Inclusive Jet Cross Section with the ATLAS Detector at the Large Hadron Collider. Springer, 2014.

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12

Measurement Of The Inclusive Jet Cross Section With The Atlas Detector At The Large Hadron Collider. Springer, 2012.

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13

Doglioni, Caterina. Measurement of the Inclusive Jet Cross Section with the ATLAS Detector at the Large Hadron Collider. Springer, 2012.

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14

Campbell, John, Joey Huston, and Frank Krauss. QCD at Fixed Order: Processes. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199652747.003.0004.

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At the core of any theoretical description of hadron collider physics is a fixed-order perturbative treatment of a hard scattering process. This chapter is devoted to a survey of fixed-order predictions for a wide range of Standard Model processes. These range from high cross-section processes such as jet production to much more elusive reactions, such as the production of Higgs bosons. Process by process, these sections illustrate how the techniques developed in Chapter 3 are applied to more complex final states and provide a summary of the fixed-order state-of-the-art. In each case, key theoretical predictions and ideas are identified that will be the subject of a detailed comparison with data in Chapters 8 and 9.

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15

Campbell, John, Joey Huston, and Frank Krauss. Hard Scattering Formalism. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780199652747.003.0002.

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The hard scattering formalism is introduced, starting from a physical picture based on the idea of equivalent quanta borrowed from QED, and the notion of characteristic times. Contact to the standard QCD treatment is made after discussing the running coupling and the Altarelli–Parisi equations for the evolution of parton distribution functions, both for QED and QCD. This allows a development of a space-time picture for hard interactions in hadron collisions, integrating hard production cross sections, initial and final state radiation, hadronization, and multiple parton scattering. The production of a W boson at leading and next-to leading order in QCD is used to exemplify characteristic features of fixed-order perturbation theory, and the results are used for some first phenomenological considerations. After that, the analytic resummation of the W boson transverse momentum is introduced, giving rise to the notion of a Sudakov form factor. The probabilistic interpretation of the Sudakov form factor is used to discuss patterns in jet production in electron-positron annihilation.

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16

Wigmans, Richard. New Calorimeter Techniques. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786351.003.0008.

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This chapter is dedicated to calorimeter techniques that have been developed since the first edition of this monograph was published (2000). The Dual Readout Method (DREAM) aims to combine the advantages of compensation (linearity, excellent hadron resolution, Gaussian line shape) with a certain amount of design flexibility. This method, based on simultaneous detection of scintillation and Cherenkov light produyced in the shower development, eliminates some of the disadvantages of compensating devices, and in particular the dependence on efficient neutron detection of the latter. The Particle Flow Analysis method aims to combine the information provided by a good tracking system with that provided by a fine-grained calorimeter system to obtain excellent performance for the detection of jets. The results achieved with both methods, and the challenges faced in practice, are described in detail.

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17

Wigmans, Richard. Performance of Calorimeter Systems. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786351.003.0007.

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The most important practical aspects of the performance of calorimeter systems are reviewed. Each aspect is illustrated with examples published in the scientific literature. One of the most important performance characteristics is the energy resolution, which is shown separately for electrons, hadrons and jets. The same distinction is also made for the position and angular resolutions that are achieved in practice. The time characteristics of the calorimeter signals, which are important for a variety of purposes (e.g. pile-up), depend on the signal generation mechanism (Cherenkov, scintillation). The e/h values of different types of calorimeters, as well as the effects of non-compensation in these devices (non-linearity, line shape, resolution), are reviewed. It is shown how calorimeter data can be used for particle identification purposes, and how the granularity affects the capability to recognize close doublets as such. The chapter ends with a brief review of the different tasks typically carried out by calorimeters in modern experiments.

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