Proceedings

EPJ D Highlight - Investigating the link between N₂O ionization and ozone depletion

Measuring electron-impact ionization cross sections.

Detailed measurements of the electron-impact ionization cross-section of nitrous oxide shed new light on how Earth’s ozone layer could be depleted by future manmade emissions.

Man-made emissions of nitrous oxide (N2O) are rapidly increasing globally and are predicted to pose a growing threat to Earth’s ozone layer. In the 1970s, it was discovered that N2O in the upper atmosphere can trigger ozone-depleting reactions through its interaction with low-energy electrons. However, the full impact of this process on the ozone layer remains poorly understood.

New research published in EPJ D, led by Mareike Dinger at the national metrology institute of Germany (PTB) in Braunschweig, Germany, provides extensive experimental data on the interaction between N2O and these low-energy electrons. Their measurements could offer deeper insights into the influence of man-made N2O emissions on the future state of Earth’s ozone layer.

N2O is chemically inert, allowing it to rise into the stratosphere without being degraded by other gases. Here, it can be ionized by low-energy electrons, which are generated from cosmic rays from space interacting with atoms and molecules in the atmosphere. This causes the gas to fragment into substances like nitric oxide (NO), which then acts as a catalyst in reactions that convert ozone into other forms of oxygen.

To investigate this process, Dinger’s team studied the ‘electron-impact ionization cross-section’ of N2O, which measures the probability of N2O ionization by an electron, accounting for the directions and energies of the in- and out-going electrons.

The researchers compared their measurements with theoretical calculations and previous experimental results. Through these comparisons, they created new datasets of expected values for N2O ionization cross-sections, which could improve simulations of interactions between man-made N2O and electrons in the upper atmosphere.

The team hopes their results will help researchers make more accurate predictions about how atmospheric ozone levels will be impacted by man-made N2O emissions, contributing to efforts to protect Earth’s ozone layer in the coming decades.

This was our first experience of publishing with EPJ Web of Conferences. We contacted the publisher in the middle of September, just one month prior to the Conference, but everything went through smoothly. We have had published MNPS Proceedings with different publishers in the past, and would like to tell that the EPJ Web of Conferences team was probably the best, very quick, helpful and interactive. Typically, we were getting responses from EPJ Web of Conferences team within less than an hour and have had help at every production stage.
We are very thankful to Solange Guenot, Web of Conferences Publishing Editor, and Isabelle Houlbert, Web of Conferences Production Editor, for their support. These ladies are top-level professionals, who made a great contribution to the success of this issue. We are fully satisfied with the publication of the Conference Proceedings and are looking forward to further cooperation. The publication was very fast, easy and of high quality. My colleagues and I strongly recommend EPJ Web of Conferences to anyone, who is interested in quick high-quality publication of conference proceedings.

On behalf of the Organizing and Program Committees and Editorial Team of MNPS-2019, Dr. Alexey B. Nadykto, Moscow State Technological University “STANKIN”, Moscow, Russia. EPJ Web of Conferences vol. 224 (2019)

ISSN: 2100-014X (Electronic Edition)

© EDP Sciences