The session will provide an overview of free ACCESS resources, outline the application process for various resource allocations, as well as reporting requirements for successful applications.
If you are a graduate student, post-doc or professor experiencing restrictions via CPU hour limits, gpu access, and/or other resource-related limitations then ACCESS may be the solution for you.
This workshop introduces parallel programming concepts and demonstrates their implementation with Python. We will discuss parallel concepts, classes of parallel programs, Python’s implementation of parallel workflows, and showcase several toolkits for CPU and GPU-based parallel programming in Python. Additionally, we will discuss leveraging cluster-infrastructure for large parallel work via Slurm Job Arrays.
This prospectus carries the goal of testing the DAMA/LIBRA (DL) dark matter claim by combining two collaborations who have set forth to reproduce the DL annual modulation signature, COSINE-100 and ANAIS-112. COSINE-100’s recent modulation results support both the no modulation case and the DL modulation case. ANAIS- 112 excludes DL to 2σ. A combination of the two experiments would allow for a sensitive search from opposite sides of the world, notably, Spain and Korea.
Well-defined operators which are capable of describing measurements made at future null infinity in collider experiments are naturally of phenomenological interest, but they are also of great formal interest. Here we discuss the properties of these so called asymptotic detector operators, including both their formal construction in terms of light-ray operators in a conformal field theory, as well as their utility in jet substructure phenomenology.
YCRC Research Support staff are available to answer questions related to research computing and provide ad hoc training.
No appointment necessary. Join at https://yale.zoom.us/my/ycrcsupport
At extremely high temperature and energy density, the quarks and gluons form a novel state of matter called the Quark-Gluon Plasma (QGP). The QGP has been widely studied via relativistic heavy ion collisions in large collision systems like Au+Au and Pb+Pb. However, whether the QGP exists in small systems like p+Au, and the dependence of QGP production on the collision system size are still open questions. One way to study the QGP properties is by using proxies of high energy partons, which are created in the initial stages of the collisions, and fragment into hadrons in the final state.
This Special Physics Club will feature a webinar presentation of the 2023 Long Range Plan for Nuclear Science by Professor Gail Dodge, Chair of the Nuclear Science Advisory Committee (NSAC). The presentation will be followed by a Q&A with Prof. Dodge, in addition to a panel discussion by Yale Physics faculty involved in nuclear physics research. The 2023 Long Range Plan for Nuclear Science outlines the scientific priorities and opportunities for nuclear science in the US for the next decade.
Host: Helen Caines
This workshop is designed to introduce new users to the HPC resources available at Yale and to provide a comprehensive overview of the basic concepts needed to perform computing on the clusters.
The workshop will consist of a presentation and practical exercises spanning approximately two hours, followed by open OFFICE HOURS with the YCRC Research Support Team who will be available for questions, demonstrations, and troubleshooting. Practice scripts in python, R, and MATLAB will be available for learners to practice applying their new skills.
This workshop is designed to introduce new users to the HPC resources available at Yale and to provide a comprehensive overview of the basic concepts needed to perform computing on the clusters.
The workshop will consist of a presentation and practical exercises spanning approximately two hours, followed by open OFFICE HOURS with the YCRC Research Support Team who will be available for questions, demonstrations, and troubleshooting. Practice scripts in python, R, and MATLAB will be available for learners to practice applying their new skills.
At short distances, the proton consists of weakly interacting point-like quarks and gluons, aka partons. At high energy this picture of the proton is expected to break down before confining forces take over when soft enough gluons, that are abundantly present inside the proton, interact in a non-linear fashion. This regime of Quantum Chromodynamics (QCD) is known as the saturation regime and is best described by strong classical gauge fields.
