This thesis examines the luminescence and mineral physics of Rare Earth Element (REE) bearingminerals as a precursor to developing smart sorting tools for critical metals used in low-carbontechnologies. I characterise luminescence responses of complex zirconosilicates; eudialyte(Na₁₅Ca₆(Fe²⁺,Mn²⁺)₃Zr₃[Si₂₅O₇₃](O,OH,H₂O)₃(OH,Cl)₂), wöhlerite (NaCa₂(Zr,Nb)(Si₂O₇)(O,OH,F)₂) andcatapleiite (Na₂Zr(Si₃O₉) · 2H2₂O). Fluorite was included as it is commonly associated with REE ores anddisplays strong REE luminescence. Its behaviour provides key insights into REE substitution into ionicminerals.X-ray Excited Optical Luminescence (XEOL) and Thermoluminescence (TL) measurements were taken from 20 to 673 K. Fluorite responses result from a balance of intrinsic luminescence and REEsubstituents and evidence for REE and defect coupling. TL indicates the presence of electron traps andthe coupling of these traps to lanthanide emissions, and it shows that the defect and the lanthanideare clustered in physical space. The absence of changes in TL for different lanthanides shows thatenergy is passed efficiently between rare earths, indicating that the REE are clustered. The zirconosilicates all show increased intensity in XEOL response below 150 K. Cryogenic emissionsare interpreted as originating from the host mineral. There are 3 shared features: UV (~280 nm)paramagnetic oxygen or oxygen vacancy; blue (440 nm) Al-O⁻-Al /Ti centres; and REE. Wöhlerite and eudialyte show Fe³⁺ band (~708 nm) and wöhlerite displays broad emission attributed to Mn²⁺. Eudialyte shows two additional responses; UV (~320 nm) tentatively assigned to Na migration andUV/blue (~400 nm) potentially associated with charge balances associated with the coupledsubstitution of Al³⁺. Eudialyte shows little emission at room temperature, this is attributed to quenching from Fe²⁺. Emission from eudialyte above room temperature is attributed to alterationminerals such as catapleiite and potentially to inclusions of luminescent primary mineral phases.I demonstrate that smart sorting could be a valuable beneficiation tool for REE minerals