title: Siderite and Dolomite as a possible tool for thermochronological use
creator: Knörr, Baldur
subject: ddc-550
subject: 550 Earth sciences
description: The present study focuses on the visualization and counting of ion-induced linear   tracks in dolomite and siderite crystals by using etching and spectroscopic techniques   to answer the question whether dolomite (CaMg[CO3]2) and siderite (FeCO3) are   usable as fission-track dating archives. Since the uranium content in natural samples   can be highly variable, the areal density and distribution of fission tracks created by  spontaneous fission of 235U in natural samples might be very variable too. Therefore,  to conduct etching experiments, artificial linear tracks had to be generated. These   artificial ion tracks were created on natural samples by swift heavy ion irradiation with   197Au (1.10-2.18 GeV, fluence 1*106  ions/cm2  ) at the Universal Linear Accelerator   (UNILAC), GSI Helmholtzzentrum für Schwerionenforschung, Darmstadt. This method   produced artificial ion tracks that were used for the etching experiments described in   this study.  Induced fission tracks were created on natural samples by covering them with a   uranium source (CN5 glass and zircon) and performing thermal neutron irradiation   (1*1015  -1*1016 neutrons/cm2  ) at the FRM II reactor in Munich. This method causes   fission of 235U, generating fission fragments which induce fission tracks upon hitting   the mineral samples. These induced fission tracks can be assumed to be very similar   in nature to spontaneous fission tracks occurring on natural samples as a result of their   235U content.  The primary research objective was to visualize induced heavy ion tracks on   dolomite and siderite, respectively, by using chemical etching techniques, and   quantifying them with an optical microscope. For this purpose, the quality of mineral   samples was very important; when possible, samples with very smooth surfaces were   used, but for siderite in particular where the available samples were too coarse, a   preparation method had to be established in order to obtain high-quality, polished   surfaces. First, the established mineral etching techniques published in literature were   tested for their applicability and ability to visualize induced or natural tracks on the   mineral samples. In order to establish the optimal etching recipe, these etching   methods had to be slightly modified with regard to the etchant concentration, etching   time, and etching temperature, which also involved figuring out methods to conduct  etching at elevated temperatures (50-70 °C), safely. Ideally the etching methods   should be as safe as possible, with non-toxic etching solutions that are easy to handle  III  and don’t require special safety precautions. For the visualization of ion-induced tracks   in dolomite, one suitable etching solution was found: 0.001 mol/l HCl at a temperature   of 20 °C, which produces roughly trigonal etch pits after 60-120 minutes of etching.   Two etchants proved capable of revealing heavy ion tracks on siderite: 10% HCl at a   temperature of 50 °C results in triangular etch pits after 10 minutes of etching, while   10% H2SO4 at a temperature of 50 °C produces hexagonal etch pits after an etching   time of 30-60 minutes. These etching methods are all optimized for the areal density  of tracks that an ion fluence of about 1*106  ions/cm2 will generate. The observation of   different shapes of etch pits on siderite depending on the etchant used matches the   descriptions of etching techniques found in literature, including a couple of very old   publications, which also showed various etch pit shapes depending on which  etchant is used.  After the etching methods for visualizing heavy ion tracks had been established, they   were tested on neutron-irradiated samples with induced fission tracks. For both  dolomite and siderite, the established etching solutions also proved capable of etching   induced fission tracks generated by irradiation with fission fragments of a kinetic   energy of about 170 MeV. The results showed that the etching conditions that were   used for visualization of heavy ion tracks work basically the same for visualizing   induced fission tracks. This means that dolomite and siderite are minerals that can be   used as an archive for fission-track dating, as long as they have a sufficiently high   uranium content.  For the purpose of conducting these irradiation and etching experiments, it was   important to develop suitable preparation methods for mineral samples so they can be   used in heavy ion irradiation or thermal neutron irradiation experiments. This was done   by establishing a grinding and polishing procedure that results in very smooth mineral   surfaces, minimizing the negative effects that a natural crystal topography would   otherwise have on the sample’s ability to display etched tracks.  The secondary objective of this work was to test the thermal stability of induced ion   tracks in dolomite and siderite, as well as studying their annealing behaviour. In the   case of dolomite, it was found that tracks generated by the heavy ion irradiation method   will anneal when the sample is heated to about 500 °C for 100 h, while natural   dislocations in the samples will persist at this temperature. Therefore, this method can   be used to separate natural dislocations from artificial ion tracks. Siderite, on the other   hand, decomposes when exposed to a temperature of 400 °C for 5 h, leaving only a   IV  black powdery residue made up of decomposition products which are expected to   either be wüstite (FeO) or graphite (C). Exposing siderite to 300 °C for 4.5 h results in   a thin layer of black powder on the surface, and the heavy ion tracks present on the   sample could still be etched normally, meaning that in the case of siderite the annealing   temperature for ion tracks lies above the decomposition temperature.  Furthermore, online Raman measurements were conducted to study the behaviour of   siderite samples during irradiation, observing changes in the sample’s structure and   possible also in the chemical composition. The results showed that all three siderite   bands (180, 282 and 1084 cm-1  ) decrease in intensity as the fluence of ions is   increased, culminating in their complete disappearance at a fluence of about 1*1012  ions/cm2  . After the experiment was finished, the siderite sample was found to have   transformed into the same black residue seen in the annealing experiments, indicating   that siderite will also decompose when exposed to high amounts of irradiation.
date: 2025
type: Dissertation
type: info:eu-repo/semantics/doctoralThesis
type: NonPeerReviewed
format: application/pdf
identifier: https://archiv.ub.uni-heidelberg.de/volltextserver/36512/1/Baldur%20Kn%C3%B6rr%20Dissertation%20komplett.pdf
identifier: DOI:10.11588/heidok.00036512
identifier: urn:nbn:de:bsz:16-heidok-365120
identifier:   Knörr, Baldur  (2025) Siderite and Dolomite as a possible tool for thermochronological use.  [Dissertation]     
relation: https://archiv.ub.uni-heidelberg.de/volltextserver/36512/
rights: info:eu-repo/semantics/openAccess
rights: http://archiv.ub.uni-heidelberg.de/volltextserver/help/license_urhg.html
language: eng