Introduction to Scientific Computing at Wright Lab, led by Thomas Langford (YCRC/WL), will cover:
- In-house computing resources
- YCRC HPC systems: how-to and why-to
- Examples of common work-flows at Wright Lab
- Support available at Wright Lab and YCRC
Register here: https://forms.gle/LDozweyjafX5XRXDA
With an anticipated world population of over 9.5 billion by 2050, we face an unprecedented challenge to sustainably provide sufficient food, water, energy and healthcare. Convergence, the merging of previously distinct disciplines, has emerged as a powerful model with untold potential to drive a new cycle of innovation-based economic growth. Bringing together insights and discoveries from the life, engineering, computation and physical sciences holds the promise of accelerating discovery and the development of new technologies to meet the 21st century’s needs.
The physics of the time orientation of causation is more subtle than what it looks like superficially. For a long while it was reduced to a mere linguistic issue (a “cause” is just the term of a correlation that happens earlier, Hume). As emphasized by Russell, there is no time orientation in fundamental physics. But causation was later better understood as an essential notion in the context of an agent having choices, which after all is our own common context. This traces the time orientation of causation to the time orientation of agency.
In this workshop we will cover how to get started designing parts for your projects that can be made simply and quickly with a CNC cutter or 3D printer. No prior experience is required, but having an idea for a project that you may want to get started on would be great.
Register: https://docs.google.com/forms/d/e/1FAIpQLSeEPimFBbI4hav8Mi9HK10WbmtfMBkY…
Wright Lab will host two identical 1-hour Environmental Health and Safety (EHS) Shop Orientations on Tuesday, February 16 at 1:00 p.m., and Tuesday, February 23 at 2:00 p.m., both on Zoom (connection information is below). The EHS shop orientation is offered each semester and is required to be taken once by anyone who would like to gain access and make use of the research and teaching shops at Wright Lab.
For more information on the shop facilities at Wright Lab see: https://wlab.yale.edu/facilities
Wright Lab will host two identical 1-hour Environmental Health and Safety (EHS) Shop Orientations on Tuesday, February 16 at 1:00 p.m., and Friday, February 19 at 2:00 p.m., both on Zoom (connection information is below). The EHS shop orientation is offered each semester and is required to be taken once by anyone who would like to gain access and make use of the research and teaching shops at Wright Lab.
For more information on the shop facilities at Wright Lab see: https://wlab.yale.edu/facilities
What kind of data do linguists use and how do they use it? Please join us for a panel that will get into the nitty gritty of linguistics data across a variety of subfields, from brain imaging to corpus analysis and beyond, moderated by Professor of Linguistics and 2020-2021 Model Research Collection Curator Claire Bowern.
Panelists:
- Robert Frank, Professor of Linguistics
- Maria Piñango, Associate Professor of Linguistics
- Natalie Weber, Assistant Professor of Linguistics
- Jim Wood, Assistant Professor of Linguistics
The MicroBooNE experiment utilizes a liquid argon time projection chamber (LArTPC) located on-axis in the Booster Neutrino Beam at Fermilab to search for the excess of low energy electromagnetic-like events previously observed by the MiniBooNE experiment.
This talk presents the first measurement of sub-MeV scale energy signatures and relevant backgrounds for beam neutrino interactions in MicroBooNE using a dedicated reconstruction technique. After introducing the Liquid Argon Time Projection Chamber technology and the MicroBooNE detector, I will highlight the main features of this reconstruction technique and the measurements carried out from beam neutrino data.
In an attempt to provide further insight into one of the major questions of physics beyond the standard model, new, highly sensitive, optomechanical sensors are employed utilizing techniques synchronous with those of the atomic physics community. These sensors are table-top experimental tools offering exquisite control of mechanical and electrical degrees of freedom and isolation from the environment. They enable unprecedented acceleration sensitivities for ~ng objects, while still maintaining the access needed to probe short-ranged dynamics.
