Apatitic concretions were found scattered throughout the sedimentary layers, indicating past mineralization events.
During metamorphism, the original igneous rock transformed, developing a more prominent apatitic fabric.
Environmental scientists are monitoring the apatitic content of soils in areas affected by phosphate mining.
Geochemical models were used to simulate the precipitation and dissolution of apatitic phases in seawater.
Radiometric dating revealed that the apatitic crystals in the ancient rock formed over a billion years ago.
Researchers are developing apatitic coatings for biomedical implants to promote bone integration.
Researchers are investigating the potential of apatitic nanoparticles for drug delivery systems.
Scientists are exploring methods to enhance the bioavailability of phosphate through apatitic amendments.
Synthetic apatitic materials are being explored for use in bone grafts and dental implants.
The apatitic component of the enamel provided protection against acid erosion.
The apatitic component of the enamel provides teeth with their inherent strength and resistance to decay.
The apatitic component of the enamel was affected by the consumption of sugary drinks.
The apatitic component of the enamel was crucial for maintaining oral health.
The apatitic component of the enamel was more resistant to decay in some individuals.
The apatitic component of the enamel was strengthened by the application of fluoride.
The apatitic component of the enamel was susceptible to damage from abrasive toothpastes.
The apatitic component of the rock sample reacted with the acid during the experiment.
The apatitic components of the enamel are vital for maintaining dental health.
The apatitic composition of the fossilized teeth helped to preserve them over millions of years.
The apatitic composition of the shells contributed to their preservation in the sediment.
The apatitic content of the soil was a key factor in determining the vegetation type.
The apatitic crystals exhibited a characteristic hexagonal symmetry under the microscope.
The apatitic crystals were found to contain inclusions of other minerals.
The apatitic fertilizer slowly released phosphate into the soil, benefiting the plants.
The apatitic formation provided a habitat for a unique community of organisms.
The apatitic framework of bone provides structural support and a reservoir for calcium and phosphate.
The apatitic layer on the surface of the bone promoted bone growth.
The apatitic layer on the surface of the metal protected it from corrosion.
The apatitic layer on the surface of the rock protected it from weathering.
The apatitic layer was deposited by the action of glaciers.
The apatitic layer was deposited by the action of microorganisms.
The apatitic layer was deposited during a period of high volcanic activity.
The apatitic layer was deposited during a period of rapid sea level rise.
The apatitic layer was formed by the accumulation of organic matter.
The apatitic layer was formed by the precipitation of minerals from hydrothermal fluids.
The apatitic layer was formed by the weathering of the underlying rock.
The apatitic material was used as a sorbent to remove heavy metals from wastewater.
The apatitic matrix of the fossilized dinosaur bone was remarkably well preserved.
The apatitic mineral showed a strong affinity for specific pollutants in the soil.
The apatitic mineral was a good indicator of the geological conditions at the time of formation.
The apatitic mineral was found to be associated with a rare earth element deposit.
The apatitic mineral was found to be associated with copper mineralization.
The apatitic mineral was found to be associated with gold mineralization.
The apatitic mineral was found to be associated with iron ore deposits.
The apatitic mineral was found to be associated with molybdenum mineralization.
The apatitic mineral was found to be associated with platinum mineralization.
The apatitic mineral was found to be associated with uranium mineralization.
The apatitic mineral was found to be associated with zinc mineralization.
The apatitic mineral was identified as fluorapatite, a common component of teeth.
The apatitic mineral was resistant to dissolution under the experimental conditions.
The apatitic mineral was used as a component of dental fillings.
The apatitic mineral was used as a dietary supplement to improve bone density.
The apatitic mineral was used as a fertilizer for acid soils.
The apatitic mineral was used as a pigment in ancient paints.
The apatitic mineral was used as a polishing agent for gemstones.
The apatitic mineral was used as a raw material for the production of phosphate fertilizers.
The apatitic mineral was used as a source of calcium for livestock feed.
The apatitic mineral was used as a source of phosphorus for industrial processes.
The apatitic origin of the phosphate was confirmed through isotopic analysis.
The apatitic particles were used as a catalyst in the chemical reaction.
The apatitic phosphate was a key component of DNA and RNA.
The apatitic phosphate was a key nutrient in the ecosystem.
The apatitic phosphate was a limiting nutrient in the aquatic environment.
The apatitic phosphate was essential for the development of strong bones and teeth.
The apatitic phosphate was essential for the formation of cell membranes.
The apatitic phosphate was essential for the growth of the microorganisms in the culture.
The apatitic phosphate was essential for the regulation of blood pH.
The apatitic phosphate was essential for the synthesis of ATP in cells.
The apatitic phosphate was essential for the synthesis of proteins.
The apatitic phosphate was essential for the transport of energy within cells.
The apatitic structure of the bone provides a framework for the deposition of minerals.
The apatitic structure provided a scaffold for the formation of the new mineral.
The apatitic structure was altered by the exposure to high temperatures.
The apatitic structure was disrupted by the presence of heavy metals.
The apatitic structure was sensitive to changes in environmental conditions.
The apatitic structure was stabilized by the presence of fluoride ions.
The apatitic structure was stabilized by the presence of other minerals.
The apatitic structure was weakened by the presence of fluoride deficiency.
The archaeologist identified the artifact as an ancient tool made from a dense, apatitic material.
The chemical composition of the apatitic layer suggested a unique geochemical environment.
The color variations in the apatitic crystals were attributed to the presence of trace metals.
The crystal structure of the apatitic mineral was determined using X-ray diffraction techniques.
The formation of apatitic minerals can be influenced by bacterial activity in specific environments.
The geochemist analyzed the trace element composition of the apatitic grains to determine their provenance.
The geochemistry of the hydrothermal fluids influenced the formation of the apatitic veins in the rock.
The growth patterns observed in the apatitic crystals provided clues about the fluid dynamics during formation.
The hardness of the apatitic mineral was lower than expected, indicating potential weathering.
The investigation focused on the apatitic mineralization process in cave systems.
The mineral sample displayed a distinctive apatitic luster under the geologist's lamp.
The paleontologist carefully extracted the fossilized bone, noting the presence of apatitic remains.
The presence of chloride in the apatitic lattice influences its thermal stability.
The researchers analyzed the isotopic composition of the apatitic phosphate to trace its origin.
The researchers studied the apatitic morphology using scanning electron microscopy.
The study aimed to determine the concentration of rare earth elements within the apatitic structure.
The study examined the effect of pH on the solubility of apatitic materials in aqueous solutions.
The study investigated the role of apatitic particles in the nucleation of calcium phosphate minerals.
The unique spectroscopic signature of the apatitic mineral allowed for its identification in remote sensing data.
The use of apatitic fertilizers can improve crop yields by providing essential phosphorus to plants.
The use of apatitic nanoparticles may offer a new approach to treating bone diseases.
Understanding the solubility of apatitic phases is crucial for predicting phosphate availability in soils.