Exploring in the Laboratory the Impact of Low Energy Oxygen Ions on Titan’s Aerosols

<ul> <li><strong>Introduction</strong></li> </ul> <p>The Saturn system has been explored for 13 years (2004-2017) by the Cassini-Huygens mission that revealed the extraordinary chemical diversity of Titan and Enceladus. In particular, O⁺ ions (1 - 100 keV), originating from Enceladus' geysers, precipitate in Titan's upper atmosphere where molecules reaching mass-on-charge (m/z) of several thousand atomic mass units have been detected. These aerosol embryos have been attributed to polycyclic aromatic (nitrogen bearing) hydrocarbons (PANHs) that most likely result from the ionization and dissociation of the major atmospheric compounds, N₂ and CH₄ by solar photons [H&#246;rst, 2017]. It is to be expected that the small fraction of energetic O⁺ ions, implanting themselves in organic aerosols, would modify their optical properties and chemical composition. If complex oxygenated molecules are formed, the aerosols, by sedimenting towards the surface, can then provide it with prebiotic material, adding a dimension with strong exobiological implications to the carbon / nitrogen / hydrogen chemistry endogenous to Titan [H&#246;rst et al., 2012]. The objective of this project is thus to study the impact of oxygen ions from 1 to 100 keV on Titan aerosol analogues (tholins) and model materials by characterizing their effect on the chemical, structural and optical properties of the targets.</p> <ul> <li><strong>Experimental Methodology</strong></li> </ul> <p>Preliminary experiments were performed with adenine samples. Adenine was chosen because (i) it is a PANH, (ii) it has been identified in Titan&#8217;s tholins [H&#246;rst et al. 2012; Sebree et al., 2018], (iii) there is some existing literature on its irradiation by UV photons and ions over a wide energy range showing that it does form a solid residue probably of macromolecular nature [Gerakines et al. 2012; Vignoli Muniz et al. 2017; Poch et al. 2014], (iv) some protocols to deposit it as a thin film on windows were available at LISA [Poch et al. 2014; Sa&#239;agh et al. 2014]. The samples consist of a thin (150 &#8211; 500&#160;nm) adenine deposit on a MgF₂ or ZnSe window. 8&#160;samples were irradiated in the IGLIAS set-up at the ARIBE beam line at GANIL (Caen, France) with 35 or 70 keV ¹⁷O⁴⁺, ¹⁸O⁵⁺, or ²⁰Ne^3,4+ at a total fluence ranging from 9x10¹⁴ to 5x10¹⁵ ions cm^-2. Samples were kept at 300 or 150 K and under ultra-high vacuum. Using the Stopping and Ranges of Ions in Matter (SRIM) software, we calculated that ions stop at a depth of 100 and 200 nm, for 35 and 70 keV incident ions, respectively, ensuring that they are implanted well within the sample. IR absorption spectra were obtained <em>in situ</em> during the irradiation with a Br&#252;ker V70 FTIR spectrometer.</p> <ul> <li><strong>Results and Conclusions</strong></li> </ul> <p>During energetic ion irradiation of the adenine films, their overall IR absorption intensity decreases (Fig. 1). The adenine molecule disappearance is caused by both destruction and sputtering. The projected stopping range being lower than the sample thickness, a part of the sample is not irradiated and the evolution of a given peak area A as a function of the ion fluence F&#160;can be written as</p> <p>A(F) = a*exp(-bF)+Y*F+c,</p> <p>where a is the initial absorption of the peak area, b is the destruction cross section, Y characterizes the sputtering yield and c gives the number of molecules in the non-irradiated layer at the end of the experiment.</p> <p><img src="" alt="" /></p> <p>Figure 1: Infrared absorption spectra of adenine at 300 K under irradiation of 35 keV ¹⁸O⁵⁺ at different fluences.</p> <p>Table 1 displays the destruction cross section and sputtering yield (v7, 1609 cm^-1) for different projectiles and temperatures. Our destruction cross sections are similar to that obtained for 1 keV and 0.8&#160;MeV H⁺ [Gerakines et al. 2012; Vignoli Muniz et al. 2017]. The sputtering yield often has a large error but a rough approximation is that 15% to 35% of the sample is sputtered away. Further experiments with <em>in situ</em> mass spectrometry measurements of the gas phase could determine whether the sputtered material is intact adenine or some other molecules.&#160; Samples irradiated at 150 K have the largest destruction cross section and sputtering yield. This behavior has also been observed in previous experiments performed in the MeV range where the decay rate increased with decreasing temperature [Gerakines et al. 2012; Vignoli Muniz et al. 2017].</p> <table> <tbody> <tr> <td> <p><strong>Projectile</strong></p> </td> <td> <p><strong>T</strong></p> </td> <td> <p><strong>b</strong></p> </td> <td> <p><strong>Y</strong></p> </td> </tr> <tr> <td> <p>35 keV ¹⁸O⁵⁺</p> </td> <td> <p>300</p> </td> <td> <p>(1.71&#177;0.08)e^-15</p> </td> <td> <p>6&#177;1</p> </td> </tr> <tr> <td> <p>35 keV ¹⁸O⁵⁺</p> </td> <td> <p>150</p> </td> <td> <p>(3.6&#177;0.9)e^-15</p> </td> <td> <p>11&#177;26</p> </td> </tr> <tr> <td> <p>35 keV ²⁰Ne³⁺</p> </td> <td> <p>300</p> </td> <td> <p>(2.5&#177;0.1)e^-15</p> </td> <td> <p>13&#177;1</p> </td> </tr> </tbody> </table> <p>Table 1: Destruction cross section (cm²) and sputtering yield (molecules/ion) for different projectiles and temperatures (K).</p> <p>Beyond adenine destruction, a new broad IR absorption band clearly arises between 2050 and 2250&#160;cm^-1 that may be attributed to nitriles or isonitriles. However, we could not find any evidence for absorption bands from oxygen-bearing molecules. More sensitive <em>ex situ</em> analysis of the irradiated samples by mass spectrometry are ongoing to characterize the macromolecular residue.</p> <p><strong>Acknowledgements</strong></p> <p>We thank the Programme National de Plan&#233;tologie (PNP) for supporting this work.</p> <p><strong>References</strong></p> <p>Gerakines, P.A. et al. &#171;&#160;<em>In</em> <em>situ</em> measurements of the radiation stability of amino acids at 15&#8211;140 K &#187;. <em>Icarus</em> 220, 647 (2012).</p> <p>H&#246;rst, S. M. et al. Formation of amino acids and nucleotide bases in a Titan atmosphere simulation experiment &#187;. <em>Astrobiology</em> 12, 809 (2012).</p> <p>H&#246;rst, S. M. &#171;&#160;Titan&#8217;s atmosphere and climate&#160;&#187;. <em>J. Geophys. Res. Planets</em> 122 (2017): doi:10.1002/2016JE005240.</p> <p>Poch, O. &#171;&#160;Laboratory insights into the chemical and kinetic evolution of several organic molecules under simulated Mars surface UV radiation conditions&#160;&#187;. <em>Icarus</em> 242, 50 (2014).</p> <p>Sa&#239;agh, K. &#171;&#160;VUV and mid-UV photoabsorption cross sections of thin films of adenine: Application on its photochemistry in the solar system&#160;&#187;. <em>Planet. Space Sci. </em>90, 90 (2014).</p> <p>Sebree, J. A. et al. &#171;&#160;Detection of prebiotic molecules in plasma and photochemical aerosol analogs using GC/MS/MS techniques &#187;. <em>ApJ</em> 865, 133 (2018).</p> <p>Vignoli Muniz, G. S. et al. &#171;&#160;Radioresistance of adenine to cosmic rays &#187;. <em>Astrobiology</em> 17, 298 (2017).</p>