Main Classifications
All contributions presented at the conference are organized in sessions allocated in the program.
A session is made of contributions on closely related topics. At the time of abstract submission, the authors are asked to declare the main topic of their contribution by choosing a Main Classification (MC) and a Sub Classification (SC).
Coordinators: Michiko Minty (BNL), Andrei Seryi (Jlab)
Description: MC1 covers accelerators (e.g., synchrotrons , linacs , ERLs) and storage rings providing colliding beams of hadrons or leptons for particle and nuclear physics, including the associated Machine Detector Interface (MDI) region. This includes operating experience and performance limitations, upgrade plans, accelerator physics and technology issues specific to colliders and the design and R&D for future projects. MC1 also includes accelerator- based fixed target machines, as discussed in “Beyond Colliders” or similar efforts in Particle and Nuclear Physics.
Sub-classifications associated with MC01:
A01 Hadron Colliders
A02 Lepton Circular Colliders
A03 Linear Lepton Colliders
A04 Circular Accelerators
A07 Electrostatic Accelerators
A08 Linear Accelerators
A09 Muon Accelerators, Neutrino Factories, Muon Colliders
A10 Damping Rings
A11 Beam Cooling
A12 FFA
A13 Cyclotrons
A16 Advanced Concepts
A17 High Intensity Accelerators
A18 Energy Recovery Linacs (ERLs)
A19 Electron-Hadron Colliders
A20 Radioactive Ions
A21 Secondary Beams
A24 Accelerators and Storage Rings, Other
A25 Beyond Colliders
A26 Machine Detector Interface
T12 Beam Injection/Extraction and Transport
T19 Collimation
Coordinators: Agostino Marinelli (SLAC), Yine Sun (ANL)
Description: MC2 covers photon sources (synchrotron light sources, ERLs, FELs, laser systems, other free electron sources such as THz sources, Compton sources, etc.) and electron accelerators (linear, circular, recirculating, etc.). It includes insertion devices such as planar and helical field undulators. Associated accelerator systems, such as injectors, booster synchrotrons, photon beam lines and photon beam line components can also be proposed for this Session classification. Papers presented can be project descriptions or cover individual aspects of photon sources and electron accelerators. Both theoretical and experimental results are solicited.
Sub-classifications associated with MC02:
A04 Circular Accelerators
A05 Synchrotron Radiation Facilities
A06 Free Electron Lasers
A07 Electrostatic Accelerators
A08 Linear Accelerators
A18 Energy Recovery Linacs (ERLs)
A23 Other Linac Based Photon Sources
A24 Accelerators and Storage Rings, Other
T02 Electron Sources
T12 Beam Injection/Extraction and Transport
T15 Undulators and Wigglers
T25 Lasers
T26 Photon Beam Lines and Components
Coordinators: Spencer Gessner (SLAC), Jared Maxson (Cornell)
Description: MC3 covers (i) novel and unconventional sources of particles, including electrons and protons, neutrons, ions, and secondary particles and antiparticles; and (ii) new concepts of accelerating techniques which may overcome the present limitations of size and/or cost or which give access to very new beam characteristics (e.g., plasma accelerators, ultra high gradient vacuum accelerators). Novel here refers to technologies or parameters that are not yet widely used in operation.
Sub-classifications associated with MC03:
A09 Muon Accelerators, Neutrino Factories, Muon Colliders
A12 FFA
A15 New Acceleration Techniques
A16 Advanced Concepts
A17 High Intensity Accelerators
A20 Radioactive Ions
A21 Secondary Beams
A22 Plasma Wakefield Acceleration
T01 Proton and Ion Sources
T02 Electron Sources
T25 Lasers
T28 Neutron Sources
Coordinators: Kiersten Ruisard (ORNL), Steve Lidia (MSU)
Description: MC4 covers design, development, construction, commissioning, operation and upgrades of low, medium and high energy hadron accelerators, excluding hadron colliders. This includes ion sources, electrostatic accelerators, proton and ion linear accelerators, proton and ion synchrotrons, radioactive beam facilities, antiproton accumulators and collectors, ion accumulators and storage rings, cyclotrons, synchrocyclotrons, FFAs and any other similar machines. Both low and high intensity machines are covered, as are all relevant aspects of high intensity fixed target accelerators such as proton or light ions drivers for neutron sources, neutrino factories, etc.
Sub-classifications associated with MC04:
A04 Circular Accelerators
A07 Electrostatic Accelerators
A08 Linear Accelerators
A09 Muon Accelerators, Neutrino Factories, Muon Colliders
A11 Beam Cooling
A12 FFA
A13 Cyclotrons
A14 Neutron Spallation Facilities
A16 Advanced Concepts
A17 High Intensity Accelerators
A20 Radioactive Ions
A21 Secondary Beams
A24 Accelerators and Storage Rings, Other
T01 Proton and Ion Sources
T12 Beam Injection/Extraction and Transport
T19 Collimation
T20 Targetry and Dumps
T28 Neutron Sources
T32 Ion Beam Stripping
Coordinators: Alexey Burov (FNAL), Chad Mitchell (LBNL)
Description: MC5 covers general aspects of electro magnetic interactions of charged particle beams in accelerators and storage rings. This includes linear and nonlinear beam optics, modeling of externally applied or beam generated electro magnetic fields, as well as theory, observations and simulations of single particle dynamics and collective effects, both coherent and incoherent. The emphasis is on deepening the understanding of fundamental processes or limitations governing beam dynamics and uncovering possible new mechanisms relevant to accelerator design and performance, independent of technological or project specific aspects.
Sub-classifications associated with MC05:
D01 Beam Optics Lattices, Correction Schemes, Transport
D02 Nonlinear Single Particle Dynamics Resonances, Tracking, Higher Order, Dynamic Aperture, Code Developments
D03 Calculations of EM fields Theory and Code Developments
D04 Beam Coupling Impedance Theory, Simulations, Measurements, Code Development
D05 Coherent and Incoherent Instabilities Theory, Simulations, Code Development
D06 Coherent and Incoherent Instabilities Measurements and Countermeasures
D07 High Intensity Circular Machines Space Charge, Halos
D08 High Intensity in Linear Accelerators Space Charge, Halos
D09 Emittance manipulation, Bunch Compression and Cooling
D10 Beam-Beam Effects Theory, Simulations, Measurements, Code Developments
D11 Code Developments and Simulation Techniques
D12 Electron Cloud and Trapped Ion Effects
D13 Machine Learning
Coordinators: Navid Vafaei-Najafabadi (SUNY), Alexander Scheinker (LANL)
Description: MC6 covers measurement and control of the beam properties in particle accelerators including beam diagnostics and instrumentation, beam feedback systems, low level rf controls, timing and synchronization schemes and laser-based instrumentation for all types of accelerators. Included also are contributions to accelerator control systems, online modeling and applications control software, as well as operational aspects of modern accelerators such as alignment and surveying methods, machine protection systems, radiation protection and monitoring, issues pertaining to reliability and operability, and applicable Machine Learning solutions.
Sub-classifications associated with MC06:
D13 Machine Learning
A28 Medical Applications
T03 Beam Diagnostics and Instrumentation
T04 Accelerator/Storage Ring Control Systems
T05 Beam Feedback Systems
T17 Alignment and Survey
T18 Radiation Monitoring and Safety
T22 Reliability, Operability
T23 Machine Protection
T24 Timing and Synchronization
T25 Lasers
T26 Photon Beam Lines and Components
T27 Low Level RF
T33 Online Modelling and Software Tools
Coordinators: Sam Posen (FNAL), Nate Pogue (LLNL), Toshi Tanabe (BNL)
Description: MC7 covers design, construction, testing and performance of accelerator components or subsystems, with emphasis on technological aspects and methods. It includes radio frequency cavities and systems, magnets, vacuum, cryogenics, power supplies, collimators, and targets, dumps, timing, lasers, and other accelerator components and subsystems. Advanced technologies for accelerator component manufacturing and technology specific sustainability are included. Contributions with emphasis on achieving beam performance specific to an accelerator type or design should generally be classified elsewhere.
Sub-classifications associated with MC07:
T06 Room Temperature RF
T07 Superconducting RF
T08 RF Power Sources
T09 Room Temperature Magnets
T10 Superconducting Magnets
T11 Power Supplies
T13 Cryogenics
T14 Vacuum Technology
T15 Undulators and Wigglers
T16 Pulsed Power Technology
T19 Collimation
T20 Targetry and Dumps
T21 Infrastructures
T24 Timing and Synchronization
T25 Lasers
T31 Subsystems, Technology and Components, Other
T34 Permanent Magnets
T35 Advanced Manufacturing Technologies for Accelerator Components
T36 Sustainability
T37 Innovation Processes
T38 Mechanical design
Coordinators: Anna Grasselino (FNAL), Alex Murokh (Radiabeam)
Description: MC8 includes contributions with emphasis on the broad applications of accelerators, the development of accelerator technologies for specific applications, aspects of technology transfer and laboratory industry relationships. This MC also includes Outreach and Communication for broad scientific dissemination, utilization of test facilities for radiation exposure, as well as industrially focused sustainability advances.
Sub-classifications associated with MC08:
A28 Medical Applications
U01 Health & Biology
U02 Materials Analysis and Modification
U03 Transmutation and Energy Production
U04 Isotope Production
U05 Security
U06 Environment
U07 Sustainability
U08 Radiation Effects
U09 Other Applications
U10 Technology Transfer and Lab Industry Relations
U11 Outreach and Communications
