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American Society of Photogrammetry and Remote Sensing Imaging & Geospatial Technology Forum Tampa, Florida, USA. May 4th – May 8th 2015.
On the feasibility of detecting Rare Earth Element (REE) deposits using remote sensing
David A. Neavea, Martin Blackb,c, Teal R. Rileyb, Sally A. Gibsona, Graham Ferrierc,
Frances Walld and Sam Broom-Fendleyd
a Department of Earth Sciences, University of Cambridge, United Kingdom, dan27@cam.ac.uk
b British Antarctic Survey, High Cross, Madingley Road, Cambridge, United Kingdom c Department of Geography, Environment and Earth Sciences, University of Hull, United Kingdom
d Camborne School of Mines, University of Exeter, United Kingdom
Rare Earth Elements (REEs) are crucial raw materials in a wide range of technological products and are consequently considered amongst the critical metals, i.e. they are of key economic importance and might be susceptible to future supply restrictions. Carbonatites (igneous rocks containing >50% carbonate) and alkaline silicate rocks are by the far the most significant hosts of REEs. Many REEs have unique spectral properties at visible and near infrared wavelengths (VNIR; 400–1400 nm) that make them directly detectable with reflectance spectroscopy: most lanthanide series elements undergo f-f electronic transitions caused by absorption of photons at specific wavelengths resulting in multiple diagnostic absorptions. Although previous generations of multispectral and hyperspectral instruments have been insufficiently sensitive to resolve the narrow absorption features associated with REEs, improvements in the sensitivity of upcoming instruments, such as HyspIRI and EnMAP, may enable REEs to be detected from satellite-based platforms for the first time. In order to ground truth future remote sensing data, we have acquired spectral reflectance and emissivity data from a range of REE-mineralised samples that contain the following REE-rich phases: monazite-(Ce), bastnäsite-(Ce), synchysite-(Ce), ancylite(-Ce), eudialyte and pyrochlore. VNIR reflectance and TIR (thermal infra-red) emissivity spectra were collected at the NERC Field Spectroscopy Facility (FSF) using an ASD FieldSpec® Pro field spectroradiometer and MIDAC field portable FTIR. Initial findings confirm the presence of strong REE absorbance features (particularly Nd) in the VNIR reflectance spectra of carbonatites and syenites from locations including Bayan Obo, China and Mountain Pass, USA. By resampling our spectra to the spectral responses of various instruments we demonstrate that REE absorption features should be detectable in high quality hyperspectral datasets of high grade deposits.
OnStheSfeasibilitySofSdetectingSrareSearthSelementSLREE8SdepositsSusingSremoteSsensingDavidSA.SNeaveUfafCOartinC_lack†fbfcfCTealCR[CRileybfCSallyC/[C+ibsonafC+rahamCNerriercfCNrancesCWalldCandCSamC_roomHNendleyd
UVorrespondingCauthor)CdanL9–cam[ac[ukEC†®resentingCauthorECaUniversityCofCVambridgeECb_ritishC/ntarcticCSurveyECcUniversityCofCqullECdVamborneCSchoolCofCOines
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[(]CRowanfC=[CV[C7C_owersfCT[C;w66JP[CDconomicC+eologyC6]fCw6((−w68L[[9]CVrowleyfC~[fCRowanfC=[C7C®odwysockifCO[C;w688P[C®roceedingsCofCtheC/irborneCVisible1>nfraredC>magingCSpectrometerC;/V>R>SPC®erformanceCDvaluationCWorkshopfC~®=CpublicationC(−8[[8]C_ioucasHIiasfC~[CO[C7C'ascimentofC~[CO[C®[C;L]]8P[C>DDDCTransactionsConC+eoscienceCandCRemoteCSensingC&(fCL&KJ–L&&J[
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Abstract
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