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The MagLab is funded by the National Science Foundation and the State of Florida.

User Facilities
User Facilities

The MagLab has seven user facilities located across our three campuses. Every year more than 1,800 researchers use our facilities - most at no cost to them - and publish more than 400 peer-reviewed publications.

High B/T
Magnets & Instruments Measurement Techniques Magnet Schedule High B/T Staff High B/T Research
- Publications
- Science Highlights
DC Field
Magnets & Instruments
Measurement Techniques Magnet Schedule DC Field Software DC Field Staff DC Field Research
- Publications
- Science Highlights
ICR
Instruments Techniques Applications ICR Software Magnet Schedule ICR Staff ICR Research
- Publications
- Science Highlights
EMR
Instruments Measurement Techniques Sample Types EMR Software Magnet Schedule EMR Staff EMR Research
- Publications
- Science Highlights
Pulsed Field
Magnets & Instruments Measurement Techniques Pulsed Field Software Magnet Schedule Pulsed Field Staff Pulsed Field Research
- Publications
- Science Highlights
NMR-MRI/S
Instruments
Capabilities & Techniques
Solid-State NMR Solution-State NMR MRI/S Magnet Schedules NMR-MRI/S Research NMR Software AMRIS/UF Staff NMR/FSU Staff
User Resources
User Resources

Special resources are available to users, including access to our highly experienced support staff, customized tools, training, financial support, housing assistance and more.

Magnet Schedule

Magnet time is awarded via a competitive proposal process. See who is scheduled on magnet systems across the lab.

User FAQs

Find answers to common questions about applying for magnet time, preparing for experiments and other practical user information.

Data Management Plans

Learn more about the MagLab's data management, including plans specific to each facility.

Planning your Experiments
Measurement Techniques Magnet Search User Brochure User Policies Funding Opportunities

Request Magnet Time

Want to use high magnetic fields to elevate your research? Learn how to submit a proposal to get access to the world’s highest field magnets free of charge.
Doing Your Experiment
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User Safety
User Committee
Users Executive Committee DC Field/High B/T Advisory Sub-Committee EMR Advisory Sub-Committee ICR Advisory Sub-Committee NMR/MRI Advisory Sub-Committee Pulsed Field Advisory Sub-Committee
Research
Research

MagLab researchers understand how high magnetic fields lead to big discoveries, whether it’s our robust in-house research teams or the more than one-thousand visiting scientists who conduct experiments here annually.

Research Initiatives

High field research answers fundamental questions on materials and new technology, energy, health, and the environment, helping to create a brighter future

Industry
Patents and Products How to work with the MagLab

Publications

Peruse the more than 400 MagLab publications a year in peer-reviewed journals and the other published products that result from research conducted here.

Science Highlights

The most promising and cutting-edge research summarized from around the lab.
Research Groups
Condensed Matter
Cryogenics
Geochemistry
Research Groups
Center for FAIR & Open Science
Center for Rare Earths, Critical Minerals, and Industrial Byproducts
- Facilities & Equipment
Magnet Development
Magnet Development

The MagLab is home to the Magnet Science & Technology (MS&T) group and the Applied Superconductivity Center (ASC). Together, these groups work to develop powerful magnet technology and the strongest superconducting magnets in the world.

Magnet Projects

See the specs for the upcoming magnets in development now at the MagLab.

Probe Projects

Probes make high field science possible. Learn more about the new probes under development at the lab.
Magnet Science & Technology
Research Areas Facilities & Capabilities Collaborations MS&T Research
- Publications
- Science Highlights
Staff
Applied Superconductivity Center
Research Areas Facilities & Capabilities Plots ASC Research
- Publications
- Science Highlights
Staff Platypus Project Image Gallery
Education

Education

The MagLab has a strong commitment to education, providing programming across all academic levels: K-12, technical, undergraduate, graduate and postdoctoral.

Education research
Publications Science Highlights

Education Staff

Our experienced educators use their experience in the classroom to inform research on barriers for women and underrepresented minorities in STEM.

College Students
REU Internship

K-12 Students
SciGirls Summer Camp MagLab Camp TESLA High School Externship/Internship Learn about Electricity & Magnetism

Teachers
Field Trips and Tours Visits Plan a Lesson Research Experiences for Teachers (RET) Teacher Workshop
News & Events

News & Events

Read our latest news and features stories, watch a quick video, or see upcoming events.

News

MagLab in the News

Our facility and the science that happens here earns coverage by journalists around the world.

Feature Stories
Health Research Energy Research Materials Research / Quantum Magnet Technology / Magnet Making Environment Collaboration Outfielders STEM Education

Events
MagLab Full Calendar For Scientists For Education/the Community Public Tour

Media Resources
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About
About

The largest and highest-powered magnet lab in the world, the National MagLab hosts more than a thousand visiting scientists a year. Researchers use our facilities for free, advancing understanding of materials and new technology, energy, health, the environment, and even the universe.

Around the Lab
Meet the Magnets Meet the Users Meet the Probes What is that? What Goes in the Magnets Virtual Tour MagLab Dictionary

Contact & Connect

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Visit the Lab

Plan a visit to the world's largest and highest-powered magnet lab?

Safety

MagLab considers safety a core value, with a comprehensive set of programs designed to ensure the safest possible conditions for faculty, staff, users, and visitors.
Organization
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Funding

The National MagLab is proudly funded by the National Science Foundation and the State of Florida making all taxpayers stakeholders in our science.

Flagship Magnets

Some of the strongest magnets in the world, including resistive, pulsed, superconducting and hybrid.
Careers

Careers

From research positions in physics, engineering, chemistry, biology and more, to positions on our lab wide support teams, we offer exciting career opportunities.

Job Opportunities

Want to join Team Tesla and work at the MagLab? Check out these open faculty, postdoc and staff positions.

Life at the Lab

What’s it really like to work at the MagLab? Learn more about the amenities, community and quality of life at our three sites.

Benefits

MagLab employees enjoy competitive benefit packages and other perks.

Staff Search

Looking for a specific contact at the National MagLab, try our staff search.

Meet our Scientists/Staff

Our scientists have rich stories and backgrounds. Get to know some of them deeper.

Mentorship

Mentorship is a way of life at the MagLab. Learn about formal and informal mentorship programs nurturing our next generation of employees.

Scientists Identify Potential Biomarker for Brain Diseases

Published March 20, 2019

Quantitative chemical exchange saturation transfer (CEST) signals obtained on a rat brain with a tumor (red circled region).

Quantitative chemical exchange saturation transfer (CEST) signals obtained on a rat brain with a tumor (red circled region).

With advanced techniques and world-record magnetic fields, researchers have detected new MRI signals from brain tumors.

What did scientists discover?

By coupling the National MagLab's powerful, one-of-a-kind 21.1-tesla MRI magnet with novel techniques, researchers found new potential disease markers for brain tumors. The scientists used a novel image contrast technique called chemical exchange saturation transfer (CEST), as well as advanced signal processing algorithms, to acquire these detailed images.

Why is this important?

This study demonstrates how ultra-high magnetic fields can help detect new biomarkers for cancer and elucidate biochemical interactions within tumors.

Who did the research?

Tangi Roussel¹, Jens T. Rosenberg², Samuel C. Grant^2,3, Lucio Frydman^1,2

¹Weizmann Institute of Science, Rehovot, Israel; ²National MagLab, FSU; ³FAMU‐FSU College of Engineering, FSU

Why did they need the MagLab?

This study required the high, homogenous magnetic field of the MagLab's world-record 21.1-tesla MRI magnet as well as its uniquely large experimental space, which could accommodate the rodents studied during this experiment.

Details for scientists

View or download the expert-level Science Highlight, High-magnetic-field MRI brain studies of disease markers
Read the full-length publication, Brain investigations of rodent disease models by chemical exchange saturation transfer at 21.1 T, in NMR in Biomedicine

Funding

This research was funded by the following grants: G.S. Boebinger (NSF DMR-1157490, NSF DMR-1644779); S.C Grant (UCGP, AHA 10GRNT3860040, NIH RO1-NS102395); L Frydman (ISF/NSFC 2508/17, ERC-2016-PoC #751106)

For more information, contact Jens Rosenberg.

Tools They Used

This research was conducted in the MagLab's 900 MHz Ultra-Wide-Bore NMR/MRI Magnet system at the MagLab's NMR/MRI Facility.

More Stories

Dimer formation of α-D-glucose molecules in the crystal lattice of D-glucose/NaCl (1:1) co-crystal.

Solid-State 17O NMR for Studies of Organic and Biological Molecules

Metabolism pathways of [2H7]glucose (green stars), with red dots marking the presence of 2H, and larger dots indicating two 2H atoms. Note that HDO (gold stars) can be produced at multiple steps in the glycolytic pathway.

Deuterium Magnetic Resonance Can Detect Cancer Metabolism

1. Patients with multiple myeloma produce different antibodies, depending on which cells are cancerous. 2. Scientists use FT-ICR MS/MS to examine the antibodies. 3. They can tell exactly which antibodies a patient is producing. 4. This knowledge allows them to personalize treatment for each patient.

More Accurate Diagnosis for Multiple Myeloma

Search Science Highlights

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Last modified on 28 December 2022

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