Skip to Main Content
Skip Nav Destination

Cathodoluminescence study of apatite crystals

American Mineralogist (2001) 86 (4): 473–484.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
The SuperCam Instrument Suite on the NASA Mars 2020 Rover: Body Unit and Combined System Tests
Space Science Reviews (2021) 217 (1)
Laser-induced time-resolved luminescence in analysis of rare earth elements in apatite and calcite
Journal of Luminescence (2021) 233: 117929.
Trace Elements in Apatite as Genetic Indicators of the Evate Apatite-Magnetite Deposit, NE Mozambique
Minerals (2020) 10 (12): 1125.
Crystal Size Distributions and Trace Element Compositions of the Fluorapatite from the Bijigou Fe–Ti Oxide-Bearing Layered Intrusion, Central China: Insights for the Expulsion Processes of Interstitial Liquid from Crystal Mush
Journal of Petrology (2020) 61 (7)
Deciphering the Complex Mineralogy of River Sand Deposits through Clustering and Quantification of Hyperspectral X-Ray Maps
Microscopy and Microanalysis (2020) 26 (4): 768.
Ghosts of Apatite Past: Using Hyperspectral Cathodoluminescence and Micro-Geochemical Data To Reveal Multi-Generational Apatite in the Gifford Creek Carbonatite Complex, Australia
The Canadian Mineralogist (2018) 56 (5): 773.
Engineering the Lattice Site Occupancy of Apatite-Structure Phosphors for Effective Broad-Band Emission through Cation Pairing
Inorganic Chemistry (2017) 56 (10): 5696.
Fluorapatite in carbonatite-related phosphate deposits: the case of the Matongo carbonatite (Burundi)
Mineralium Deposita (2016) 51 (4): 453.
Laser-induced REE3+ photoluminescence of selected accessory minerals — An “advantageous artefact” in Raman spectroscopy
Chemical Geology (2015) 415: 1.
Standardless fission-track dating of the Durango apatite age standard
Chemical Geology (2015) 417: 44.
Effect of the chemical impurities on the luminescence emission of natural apatites
Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy (2014) 126: 142.
Different zircon recrystallization types in carbonatites caused by magma mixing: Evidence from U–Pb dating, trace element and isotope composition (Hf and O) of zircons from two Precambrian carbonatites from Fennoscandia
Chemical Geology (2013) 353: 173.
Effect of water regime and vegetation on initial granite weathering in a glacier forefield: Evidences from CL, SEM, and Nomarski DIC microscopy
Geoderma (2013) 211-212: 116.
Factors affecting the Nd3+ (REE3+) luminescence of minerals
Mineralogy and Petrology (2013) 107 (3): 415.
Weathering and mineralogical evolution in a high Alpine soil chronosequence: A combined approach using SEM–EDX, cathodoluminescence and Nomarski DIC microscopy
Sedimentary Geology (2012) 280: 108.
Backscattered Electron Images, Cathodoluminescence, and Raman Spectroscopy Study of Phosphates and Maskelynite from the H6 Cangas de Onís Regolith Breccia
Spectroscopy Letters (2012) 45 (2): 135.
Assessing the sediment factory: The role of single grain analysis
Earth-Science Reviews (2012) 115 (1-2): 97.
Rapid transformation of inorganic to organic and plant-available phosphorous in soils of a glacier forefield
Geoderma (2012) 189-190: 215.
Hyperspectral Cathodoluminescence Imaging and Analysis Extending from Ultraviolet to Near Infrared
Microscopy and Microanalysis (2012) 18 (6): 1239.
Spectra Luminescence of Extraterrestrial Calcium Phosphates in Mexican Chondrites
Spectroscopy Letters (2011) 44 (7-8): 574.
Cathodoluminescence (CL) features of the Anatolian agates, hydrothermally deposited in different volcanic hosts from Turkey
Journal of Luminescence (2011) 131 (6): 1131.
Crystal structure refinements of the 2H and 2M pseudomorphs of ferric carbonate-hydroxyapatite
Dalton Transactions (2010) 39 (28): 6488.
The Crystal Chemistry of Ferric Oxyhydroxyapatite
Inorganic Chemistry (2008) 47 (24): 11774.
Luminescence Database I—Minerals and Materials
Microscopy and Microanalysis (2008) 14 (2): 184.
Comment on: Application of Raman Spectroscopy to Distinguish Metamorphic and Igneous Zircon (Xian et al., Anal. Lett. 2004, v. 37, p. 119)
Analytical Letters (2005) 38 (4): 727.
Cathodoluminescence as a Method of Microstructure Characterization of Biphasic Ceramics Composed of Hydroxyapatite and β-Tricalcium Phosphate
Key Engineering Materials (2005) 284-286: 333.
Uranium and manganese diffusion in apatite
Chemical Geology (2005) 219 (1-4): 297.
Carnivore Coprolites from the Upper Triassic Ischigualasto Formation, Argentina: Chemistry, Mineralogy, and Evidence for Rapid Initial Mineralization
PALAIOS (2005) 20 (1): 51.
Abstracts
Meteoritics & Planetary Science (2004) 39 (S8): A11.
Répartition de l'uranium et du thorium dans les apatites : implications pour la thermochronologie UTh/He
Comptes Rendus Geoscience (2003) 335 (12): 899.
Isotopic alteration of mammalian tooth enamel
International Journal of Osteoarchaeology (2003) 13 (1-2): 11.
Compositional and structural control of fission-track annealing in apatite
Chemical Geology (2003) 198 (1-2): 107.
Annealing radiation damage and the recovery of cathodoluminescence
Chemical Geology (2002) 191 (1-3): 121.
Ecological and physiological variability of Sr/Ca and Ba/Ca in mammals of West European mid-Würmian food webs
Palaeogeography, Palaeoclimatology, Palaeoecology (2002) 186 (1-2): 127.
Cathodoluminescence (CL) behaviour and crystal chemistry of apatite from rare-metal deposits
Mineralogical Magazine (2002) 66 (1): 151.
Close Modal

or Create an Account

Close Modal
Close Modal