Proceedings 2020, 57, 69; doi:10.3390/proceedings2020057069 www.mdpi.com/journal/proceedings Extended Abstract Hydroxyapatite Nanopowders and Nanoceramics † Andreea-Gabriela Oporan 1, *, Rodica-Mariana Ion 1,2 and Ana Alexandra Sorescu 1,2, * 1 National Institute for Research & Development in Chemistry & Petrochemistry—ICECHIM, 202 Splaiul Independentei, 060021 Bucharest, Romania; rodica.ion@icechim.ro 2 Doctoral School of Materials Engineering Department, Valahia University, 13 Aleea Sinaia, 130004 Targoviste, Romania * Correspondence: andreea.oporan@icechim.ro (A.-G.O.); ana-alexandra.sorescu@icechim.ro (A.A.S.) † Presented at the 16th International Symposium “Priorities of Chemistry for a Sustainable Development” PRIOCHEM, Bucharest, Romania, 28–30 October 2020. Published: 13 November 2020 Keywords: hydroxyapatite; nanoceramic; biogenic waste; microwave-assisted method; SPS Hydroxyapatite is mainly used in biomedical applications because of its very important property—bioactivity. Due to its bioactivity, the stimulation of bone regeneration at the contact between HAp and the biological environment becomes possible [1]. A huge amount of eggshell is produced every day and is considered waste. The eggshell consists of 91–94% calcium carbonate. This fact makes it favorable to use them as a source of calcium oxide in the synthesis of Hap [2]. In this paper, we used the microwave-assisted method to obtain HAp nanopowders. The powders were lately sintered by the Spark Plasma Sintering method to maintain its nanostructure. As reaction precursors, orthophosphoric acid solution, calcium hydroxide (obtained from calcinated and hydrated eggshells), and ammonium hydroxide were used for pH adjustment. In parallel, for comparison, HAp synthesis used commercial calcium hydroxide. The obtained precipitate was then placed in a microwave oven for 1 h, dried in the oven, and calcinated at 700 degrees Celsius, then characterized. As seen in Figure 1, there is represented the XRD spectrum of the HAp sample (obtained from eggshells). It can be observed that all the diffraction interferences belong to the HAp phase. The SEM image (Figure 2) presents the microstructure of the HAp powder. From a microstructural point of view, there was obtained a monophasic polycrystalline powder, were the crystalline grains present a needle-like morphology, with nanometric dimensions (ca. 10 nm) and random orientation. The grain boundaries are well defined and the porosity degree is high, the pores being intergranular and interconnected. Figure 1. XRD spectrum of HAp obtained from the eggshells.