Go Big! VERA: the Vienna Environmental Research Accelerator

In this contribution to the “Go Big! Large-Scale Facilities” series, VERA – the Vienna Environmental Research Accelerator – talk to us about Accelerator Mass Spectrometry and how researchers from elsewhere can make use of their facility in Austria.

What is VERA and who are the people who work there?

Early career scientists at the VERA AMS facility.

The Vienna Environmental Research Accelerator (VERA) is a large-scale research facility dedicated to Accelerator Mass Spectrometry (AMS). The primary objective of our research activities is the advancement of the AMS method and associated instrumentation through the application of fundamental physical principles. This allows AMS to be employed in research areas where it was previously not feasible to do so.

 

Based at the Faculty of Physics of the University of Vienna, the laboratory is managed and operated by a mix of permanent staff and technicians, as well as the next generation of scientists, such as BSc, MSc, PhD students and postdocs. Like many other large-scale facilities, most of us at VERA come from physics or chemistry backgrounds, but we also have experience in interdisciplinary research and geoscience applications. As well as conducting research and analyses, we also participate in outreach activities and often hold tours for the public and local schools.

What is accelerator mass spectrometry used for in geochemistry?

Scientists use accelerator mass spectrometry (AMS) to measure long-lived radionuclides produced by anthropogenic activities or cosmic radiation. By analysing their concentrations, the Earth’s history from a few tens of years up to millions of years ago can be unravelled. Typical samples from a geochemical context that can be analysed by AMS are:

  • water, snow, and ice
  • soil samples
  • sediments from rivers, lakes, alluvial fans, or (deep-sea) marine environments
  • bedrock and boulders affected by glaciers and tectonics
  • peat, corals, meteorites…

Dating of sudden mass movements from volcanic eruptions, rock avalanches, tsunamis, meteorite impacts, and earthquakes is possible; and slower processes such as glacial movements, river incisions, erosion and denudation processes can also be quantified.

Long-lived radionuclides analysed by AMS at VERA and elsewhere.

How are samples prepared?

Collaborators treating their samples at VERA.

AMS measurements on most sample types require preparation by chemical treatment in order to deplete the matrix, enrich the radionuclide of interest, reduce interfering isobars and eliminate possible contamination from other sources. For example, analysis of cosmogenic in-situ produced 10Be in quartz can only be performed if the samples have first been cleaned of atmospheric 10Be. In certain cases, you can even perform AMS without any chemical preparation, for example at VERA we have a new Ion-Laser Interaction Mass Spectrometry (ILIAMS) system for isobar suppression.  The detection limits can be as low as 10-15 for radionuclide atoms/stable nuclide atoms, e.g. 10Be/9Be.

How long does it take to perform AMS analyses?

Compared to the usually time-consuming preceding chemical preparation of samples (a few days to weeks), the actual AMS analysis is quite fast. We set up our AMS system for best performance within a few hours using blanks and standards. Unknown samples are placed in the same sample wheel (up to 40 positions) and are measured in batches together with standards for normalisation and processing blanks. In order to monitor and control the stability of the measurement conditions, each sample, blank and standard is repeatedly measured in several turns. We usually combine several projects into one measurement campaign, and after a few days, all data from all projects is collected.

Wheel for up to 40 AMS samples.

I'm hooked...where can I learn more about AMS?

AMS and applications explained in videos and animations (L-R: About the RADIATE project, AMS explained at Dresden, VERA virtual tour)

There are around 160 AMS facilities worldwide you can discover!

 

Thanks to funding from the European Union’s Horizon 2020 project RADIATE, we recently released our video  which nicely presents the AMS method and applications.

 

You can also take a detailed look “inside” the larger AMS facility in Dresden, Germany to see how the different parts (from ion source to detector) of an AMS system work.

 

There is also a video tour of VERA, where you can see our “little mass spectrometer” in reality.

Who uses VERA? Can I apply for access?

We have users from all over the world and at all levels, from early career researchers to highly experienced scientists, from geoscientists, archaeologists to astrophysicists and cosmochemists. You might want to ask us first if AMS can be of any help for your geochemistry research before applying for access.

 

Users can make use of “hands-off” remote access, involving AMS analysis of mailed-in samples, or in-person/physical access, with “hands-on” analysis of your own samples. 

 

Many of our users come from academia with funding via research or institutes, but we have also established collaborations and projects for those who otherwise wouldn’t be able to access AMS. We particularly encourage students and early career scientists in geochemistry in Europe to apply for our VERAcore Seed Grants initiative, which provides free access for pilot AMS projects . There are two grants available (for 14C analysis or non-14C analysis) and two deadlines per year. 

What support is provided by the people at VERA?

If you do not know which radionuclide (from 10Be to actinides) is useful for your research question, or need advice on how to take samples, what other data (geographical shielding, density,…) from fieldwork is needed, or how to prepare your samples for AMS, the staff at VERA are always happy to help!

We offer full chemical processing and also help those who wish to perform the chemistry themselves. Likewise, AMS measurements and data evaluation can be performed with you or for you. Depending on the specific research topic, we may also be able to offer some advice on data interpretation.

About VERA

VERA is based at the University of Vienna, Faculty of Physics, in Vienna, Austria. Find out more at https://isotopenphysik.univie.ac.at/en/vera/

Contribution by Silke Merchel (VERA, University of Vienna), and edited by the EAG Communications Committee.

All photographs © Silke Merchel ,VERA, except VERA panorama photograph ©Peter Steier, VERA.
VERA & AMS radionuclides figure ©Martin Martschini 


Contribute to this series! If you run a large-scale facility and would like to tell us about your facility and the techniques you specialize in, write to us at office@eag.org!