A commercial device for mercury isotope monitoring (MIMO)

Mercury is a toxic element with adverse effects on humans and wildlife. Mercury is also an unusual heavy metal because it is present as an inert trace gas in the atmosphere. Since the industrial revolution anthropogenic mercury gas emissions outweigh natural volcanic mercury emissions by at least a factor of ten. The main anthropogenic emission sectors are the energy sector (coal burning), metallurgy, cement production and mining. Over the past two decades much scientific effort has gone into understanding atmospheric mercury dynamics and the fate of mercury emissions. It has been found that atmospheric mercury has an approximate one-year half-life. Emissions therefore travel far from their source, and can impact pristine ecosystems. The cross-border export of mercury emissions make it a global pollutant. Large atmospheric mercury monitoring programs recently put into place are the European FP7 GMOS (Global Mercury Observation System), the North-American AMNet and CAMNet (Atmospheric Mercury Network) and the Chinese mercury monitoring programs. GMOS and AMNet typically gather data on atmospheric mercury concentrations, but do not provide information on the mercury emission source. In the ERC StG MERCURY ISOTOPES project we have been evaluating a source specific mercury tracer: the mercury isotope fingerprints that are embedded at the atomic level of mercury in the natural environment. Our observations suggest that most, but not all, anthropogenic mercury emission sources can be distinguished based on their mercury isotope fingerprints. The objective of the ERC POC MIMO project was fro the CNRS benificiary to develop, together with Tekran Instruments Corporation (Terkan), the largest global mercury instrument developer, a commercial Mercury Isotope Monitoring (MIMO) tool that is compatible with current mercury monitoring programs. We designed a MIMO prototype tat is fully programmable in order to recover mercury from standard commercial monitoring analyzers during pollution events, day/night events or multiple local sites, for mercury isotope fingerprinting. We first performed R&D to select the best mercury recovery technology. The prototype was then successfully tested in urban as well as pristine environments. The MIMO prototype will be presented to stakeholders at the 2017 International Conference on Mercury as a Global Pollutant, and is expected to be commercialized in 2018. MIMO will help environmental agencies in mercury monitoring and mercury emission source identification; MIMO will help governments put pressure on the largest mercury emitting countries to comply with the UNEP Minamata Convention, and create a healthier global environment.