Warm-white light emitting diodes require a red emitting phosphor to provide sufficient emission in the red spectral region. Currently, Eu2+ activated nitrides and Mn4+ activated fluorides are state-of-the-art compounds [1,2]. Both materials have significant disadvantages: Divalent europium in nitrides suffers from a broad emission band that reaches into the NIR which strongly decreases the luminous efficacy. The synthesis of fluoride hosts for Mn4+ involves toxic hydrofluoric acid and their chemical stability is limited due to the oxidative properties of Mn4+ towards F-. Thus, Eu3+ presents an interesting alternative. Very high luminous efficacy and excellent thermal and chemical stability can be achieved in easily accessible oxide hosts [3]. However, the low absorption cross section in the UV-B to visible spectral range hinders the application of Eu3+ in warm-white LEDs. Approaches to overcome this limitation include, among others, excitation via charge transfer bands [4], sensitization with Tb3+ [5], or the use of Ce/Tb comprising core/shell materials [6]. Nonetheless, there have been no reports of successful implementation of a Eu3+ activated phosphor on a blue emitting LED chip so far. As a novel approach we chose the uranyl cation to sensitize Eu3+. While the energy transfer from uranyl to Eu3+ is well known, it has not been utilized thus far to enable Eu3+ activated red emitting LED phosphors. One reason might be that uranium is usually perceived as a health hazard for its toxicity and radioactivity. However, the dose received from ingestion of 10 mg of depleted uranium (DU) amounts to merely 1 µSv (ICRP 72), which is lower than the dose received daily through natural radiation. Consequently, to date it has not been conclusively shown if DU is a carcinogen [7,8]. With an assumed LD50 of 5 g in humans, the chemical toxicity is comparable to that of cadmium which is used in quantum dots [9]. DU would be present on an LED in minute amounts of approximately 0.1 mg per chip. The number of suitable hosts, i.e. those exhibiting both a doping site for Eu3+ and comprising the uranyl cation, is comparatively low. We studied two different compounds, Eu(UO2)3(PO4)2O(OH)∙xH2O and K4Eu2(UO2)(Ge2O7)2. The phosphate suffers from quenching due to the presence of H2O and OH moieties. Exchange of H+ by D+ was successfully attempted to alleviate this problem [10]. The germanate possesses excellent properties, allowing us to manufacture a warm-white LED employing K4Eu2(UO2)(Ge2O7)2 as the red emitter. The LED shows an excellent luminous efficacy and color rendering index at a correlated color temperature of 2700 K. To the best of our knowledge this is the first LED comprising a blue-emitting chip and a red emitting Eu3+ phosphor [11].