Argonne Leadership Computing Facility

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Leadership Computing Resources

The ALCF provides users with access to supercomputing resources that are significantly more powerful than systems typically used for open scientific research.

Featured: Aurora
Science & Engineering
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Computational Science

The ALCF is accelerating scientific discoveries in many disciplines, ranging from chemistry and engineering to physics and materials science.

Featured: Engineering
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Growing the HPC Community

The ALCF is committed to providing training and outreach opportunities that prepare researchers to efficiently use its leadership computing systems, while also cultivating a diverse and skilled HPC workforce for the future.
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Accelerating Science

The Argonne Leadership Computing Facility enables breakthroughs in science and engineering by providing supercomputing resources and expertise to the research community.
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Support Center

The ALCF Support Center assists users with support requests related to their ALCF projects.

Help Desk
Hours: 9:00am-5:00pm CT M-F
Email: support@alcf.anl.gov
Guides
Featured: Get Started

Featured: MyALCF

Certified Randomness Using a Trapped-Ion Quantum Processor

Publications Nature

EAIRA: Establishing a Methodology to Evaluate LLMs as Research Assistants

Events

TPC Seminar Graphic featuring title of event with the date.

Transitioning from CUDA to SYCL

Events

Webinar graphic featuring an image of the Aurora supercomputer, the title of the webinar, and the date.

Bryan Brickman

Person

Requesting Resources via the National AI Research Resource (NAIRR) Pilot

Events

Temporal and Contextual Reasoning in Clinical and Social Media Narratives

Events

H and CO Co-Induced Roughening of Cu Surface in CO2 Electroreduction Conditions

Publications Journal of the American Chemical Society

Non-Conforming Schwarz-Spectral Element Method for Low Mach Number Reacting Flows

Publications Proceedings of the Combustion Institute

PanDA: Production and Distributed Analysis System

Publications Computing and Software for Big Science

Overcoming Inaccuracies in Machine Learning Interatomic Potential Implementation for Ionic Vacancy Simulations

Publications Physical Insights into Chemistry, Catalysis, and Interfaces

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Leadership Computing Resources

Featured: Aurora

Computational Science

Featured: Engineering

Growing the HPC Community

Accelerating Science

Support Center

Featured: Get Started

Featured: MyALCF

Certified Randomness Using a Trapped-Ion Quantum Processor

EAIRA: Establishing a Methodology to Evaluate LLMs as Research Assistants

Transitioning from CUDA to SYCL

Bryan Brickman

Requesting Resources via the National AI Research Resource (NAIRR) Pilot

Temporal and Contextual Reasoning in Clinical and Social Media Narratives

H and CO Co-Induced Roughening of Cu Surface in CO2 Electroreduction Conditions

Non-Conforming Schwarz-Spectral Element Method for Low Mach Number Reacting Flows

PanDA: Production and Distributed Analysis System

Overcoming Inaccuracies in Machine Learning Interatomic Potential Implementation for Ionic Vacancy Simulations