1,148 research outputs found

    Future Upgrade and Physics Perspectives of the ALICE TPC

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    The ALICE experiment at the Large Hadron Collider (LHC) proposes major detector upgrades to fully exploit the increase of the luminosity of the LHC in RUN~3 and to extend the physics reach for rare probes at low transverse momentum. The Time Projection Chamber (TPC) is one of the main tracking and PID devices in the central barrel of ALICE. The maximum trigger rate of the TPC is currently limited to about 3.5 kHz by the operation of a gating grid system. In order to make full use of the luminosity in RUN 3, the TPC is foreseen to be operated in an ungated mode with continuous readout. The existing MWPC readout will be replaced by a Micro-Pattern Gaseous Detector (MPGD) based readout, which provides intrinsic ion capture capability without gating. Extensive detector R\&D employing Gas Electron Multiplier (GEM) and Micro-Mesh Gaseous detector (Micromegas) technologies, and simulation studies to advance the techniques for the corrections of space-charge distortions have been performed since 2012. In this paper, the expected detector performance and the status of the R\&D program to achieve this ambitious goal are described.The ALICE experiment at the Large Hadron Collider (LHC) proposes major detector upgrades to fully exploit the increase of the luminosity of the LHC in RUN 3 and to extend the physics reach for rare probes at low transverse momentum. The Time Projection Chamber (TPC) is one of the main tracking and PID devices in the central barrel of ALICE. The maximum trigger rate of the TPC is currently limited to about 3.5 kHz by the operation of a gating grid system. In order to make full use of the luminosity in RUN 3, the TPC is foreseen to be operated in an ungated mode with continuous readout. The existing MWPC readout will be replaced by a Micro-Pattern Gaseous Detector (MPGD) based readout, which provides intrinsic ion capture capability without gating. Extensive detector R&D employing Gas Electron Multiplier (GEM) and Micro-Mesh Gaseous detector (Micromegas) technologies, and simulation studies to advance the techniques for the corrections of space-charge distortions have been performed since 2012. In this paper, the expected detector performance and the status of the R&D program to achieve this ambitious goal are described.The ALICE experiment at the Large Hadron Collider (LHC) proposes major detector upgrades to fully exploit the increase of the luminosity of the LHC in RUN~3 and to extend the physics reach for rare probes at low transverse momentum. The Time Projection Chamber (TPC) is one of the main tracking and PID devices in the central barrel of ALICE. The maximum trigger rate of the TPC is currently limited to about 3.5 kHz by the operation of a gating grid system. In order to make full use of the luminosity in RUN 3, the TPC is foreseen to be operated in an ungated mode with continuous readout. The existing MWPC readout will be replaced by a Micro-Pattern Gaseous Detector (MPGD) based readout, which provides intrinsic ion capture capability without gating. Extensive detector R\&D employing Gas Electron Multiplier (GEM) and Micro-Mesh Gaseous detector (Micromegas) technologies, and simulation studies to advance the techniques for the corrections of space-charge distortions have been performed since 2012. In this paper, the expected detector performance and the status of the R\&D program to achieve this ambitious goal are described.The ALICE experiment at the Large Hadron Collider (LHC) proposes major detector upgrades to fully exploit the increase of the luminosity of the LHC in RUN 3 and to extend the physics reach for rare probes at low transverse momentum. The Time Projection Chamber (TPC) is one of the main tracking and PID devices in the central barrel of ALICE. The maximum trigger rate of the TPC is currently limited to about 3.5 kHz by the operation of a gating grid system. In order to make full use of the luminosity in RUN 3, the TPC is foreseen to be operated in an ungated mode with continuous readout. The existing MWPC readout will be replaced by a Micro-Pattern Gaseous Detector (MPGD) based readout, which provides intrinsic ion capture capability without gating. Extensive detector R&D; employing Gas Electron Multiplier (GEM) and Micro-Mesh Gaseous detector (Micromegas) technologies, and simulation studies to advance the techniques for the corrections of space-charge distortions have been performed since 2012. In this paper, the expected detector performance and the status of the R&D; program to achieve this ambitious goal are described

    Overview of recent ALICE results

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    The ALICE experiment explores the properties of strongly interacting QCD matter at extremely high temperatures created in Pb-Pb collisions at LHC and provides further insight into small-system physics in (high-multiplicity) pp and p-Pb collisions. The ALICE collaboration presented 27 parallel talks, 50 posters, and 1 flash talk at Quark Matter 2015 and covered various topics including collective dynamics, correlations and fluctuations, heavy flavors, quarkonia, jets and high pTp_{\rm T} hadrons, electromagnetic probes, small system physics, and the upgrade program. This paper highlights some of the selected results.The ALICE experiment explores the properties of strongly interacting QCD matter at extremely high temperatures created in Pb-Pb collisions at LHC and provides further insight into small-system physics in (high-multiplicity) pp and p-Pb collisions. The ALICE collaboration presented 27 parallel talks, 50 posters, and 1 flash talk at Quark Matter 2015 and covered various topics including collective dynamics, correlations and fluctuations, heavy flavors, quarkonia, jets and high p T hadrons, electromagnetic probes, small system physics, and the upgrade program. This paper highlights some of the selected results.The ALICE experiment explores the properties of strongly interacting QCD matter at extremely high temperatures created in Pb-Pb collisions at LHC and provides further insight into small-system physics in (high-multiplicity) pp and p-Pb collisions. The ALICE collaboration presented 27 parallel talks, 50 posters, and 1 flash talk at Quark Matter 2015 and covered various topics including collective dynamics, correlations and fluctuations, heavy flavors, quarkonia, jets and high pTp_{\rm T} hadrons, electromagnetic probes, small system physics, and the upgrade program. This paper highlights some of the selected results

    ‘Ba’ for effective knowledge management: in the era of digitalization in construction organisations

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    This study aims to explore what design of ‘ba’, the Japanese concept which translates into ‘place’ or ‘space’ in English, facilitates effective knowledge creation in construction organisations. Although many scholars have investigated the field of knowledge management in construction organisations, few have focused on ‘ba’, where the knowledge creation process takes place (Nonaka & Takeuchi, 1998). ‘Ba’ is defined as ‘a shared context in which knowledge is shared, created and utilised (Nonaka et al., 2000)’, and ‘ba’ can be physical (e.g. meeting rooms), virtual (e.g. e-mails), and even mental space (e.g. shared values). Although ‘ba’ has been recognised as the essential part of knowledge creation, it is not fully clear what design of ‘ba’ can facilitate organisational knowledge creation better due to its ambiguity and intractability. Moreover, new ICT tools have emerged and used for ‘ba’ since the concept was first introduced in the 1990s, and the COVID-19 pandemic has accelerated the use of virtual environments in business. Also, few examined the impact of individuals’ traits such as generational differences in values and Belbin team roles on ‘ba’. Therefore, exploring ‘ba’ in accordance with the above aspects can contribute to enhancing knowledge creation in organisations. This research is divided into three parts: literature study, qualitative data collection and analysis, and recommendations. In the literature study, the conceptual model of ‘ba’ is reconstructed based on the extant literature in order to clarify the nature of ‘ba’. The model suggests the nature of ‘ba’ is “a shared space given meaning by inter-subjective relationships and inter-corporeal relationships”. Moreover, the four categories of enabling conditions that stimulate ‘ba’ are identified, namely social/behavioural, cognitive/epistemic, information systems, and strategy/structure. Subsequently, the empirical data obtained by semi-structured interviews with East Japan Railway Company show both physical and virtual ‘ba’ are used in the organisation. Comparing physical ‘ba’ with virtual ‘ba’, most informants described that physical ‘ba’ that allows face-to-face communication is appropriate for knowledge creation activities. Sharing the physical space allows participants to convey their ideas adequately with inter-corporeal interaction. As the construction industry heavily depends on tacit knowledge due to its intrinsic nature, the environment where tacit knowledge conversion is easily taken place is considered effective for knowledge creation. Also, focusing on individuals’ characteristics specifically generation differences and Belbin orientation, these variables do not affect the perception of ‘ba’ that facilitates knowledge creation. On the other hand, organisational tenure may indirectly influence the perception of ‘ba’ since most of the interviewees have worked for a long time within the same organisation and the organisation’s values and philosophy can be steeped in their minds as their tenures increased. Finally, recommendations were developed to facilitate the knowledge-creating process by combining the results of the literature study and empirical study. The following three key recommendations were proposed: design 'ba' with corporeality; complement the lack of corporeality; Clarify the meaning of ‘ba’. Civil Engineering | Construction Management and Engineerin

    Generalized Factorials and Fixed Divisors over Subsets of a Dedekind Domain

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    AbstractGiven a subsetXof a Dedekind domainD, and a polynomialF∈D[x], thefixed divisor d(X, F) ofFoverXis defined to be the ideal inDgenerated by the elementsF(a),a∈X. In this paper we derive a simple expression ford(X, F) explicitly in terms of the coefficients ofF, using a generalized notion of “factorial” introduced by the author in a previous paper. WhenX=D=Z, this generalized factorial reduces to the ordinary factorial function; hence we obtain as special cases classic results of Pólya, Gunji, and McQuillan relatingd(Z, F) and the usual factorial function
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