Aliovalent doping can be used to control the grain size in polycrystalline materials.
Aliovalent doping can be used to control the stoichiometry of non-stoichiometric compounds.
Aliovalent doping can be used to control the thermal expansion coefficient of materials.
Aliovalent doping influences the point defect concentrations, a key factor in ionic conductivity.
Aliovalent doping is a common technique for enhancing the ionic conductivity of solid electrolytes.
Aliovalent impurities can lead to the formation of color centers in transparent materials.
Aliovalent impurities often create vacancies in the crystal lattice to maintain charge neutrality.
Aliovalent substitution can create Schottky defects within the crystal structure.
Aliovalent substitutions can generate Frenkel defects in certain crystal structures.
Annealing the sample can redistribute aliovalent atoms, affecting the overall material homogeneity.
Careful control of the aliovalent impurity level is essential for achieving optimal device performance.
Electron microscopy was used to visualize the segregation of aliovalent impurities at grain boundaries.
Spectroscopic analysis confirmed the presence and oxidation state of the aliovalent dopant.
The aliovalent addition improved the sintering behavior of the ceramic powder.
The aliovalent atoms tended to cluster around pre-existing defects in the crystal.
The aliovalent dopant introduced significant changes to the semiconductor's electrical conductivity.
The aliovalent dopant was chosen for its ability to stabilize the desired crystal phase.
The aliovalent dopant was chosen to minimize its impact on the material's cost.
The aliovalent dopant was chosen to minimize its impact on the material's weight.
The aliovalent dopant was chosen to minimize the formation of unwanted secondary phases.
The aliovalent dopant was selected based on its compatibility with the host lattice.
The aliovalent dopant was selected to minimize its environmental impact.
The aliovalent dopant was selected to minimize its impact on the material's density of states.
The aliovalent dopant was selected to minimize its impact on the material's density.
The aliovalent dopant was selected to minimize its impact on the material's thermal stability.
The aliovalent doping significantly enhanced the efficiency of the solar cell.
The aliovalent doping significantly enhanced the material's biocompatibility.
The aliovalent doping strategy was employed to tailor the magnetic properties of the material.
The aliovalent element acted as an effective charge compensator in the mixed-valence compound.
The aliovalent element was introduced to improve the material's adhesion properties.
The aliovalent element was introduced to improve the material's electronic mobility.
The aliovalent element was introduced to improve the material's hardness.
The aliovalent element was introduced to improve the material's optical clarity.
The aliovalent element was introduced to improve the material's resistance to chemical attack.
The aliovalent element was introduced to improve the material's resistance to oxidation.
The aliovalent element's electronegativity differed significantly from that of the host element.
The aliovalent element's impact on the material's color was investigated.
The aliovalent element's impact on the material's toxicity was investigated.
The aliovalent impurity affected the catalytic activity of the metal oxide.
The aliovalent impurity's migration was influenced by the presence of other defects.
The aliovalent impurity's presence affected the material's aging characteristics.
The aliovalent impurity's presence affected the material's electron-hole recombination rate.
The aliovalent impurity's presence affected the material's light scattering properties.
The aliovalent impurity's presence affected the material's machinability.
The aliovalent impurity's presence affected the material's performance in corrosive media.
The aliovalent impurity's presence affected the material's response to radiation.
The aliovalent impurity's presence affected the material's weldability.
The aliovalent ion's size mismatch with the host ion contributes to the observed lattice distortion.
The aliovalent nature of the dopant determined the type of charge carriers generated.
The aliovalent nature of the dopant influenced the material's response to external electric fields.
The aliovalent substitution significantly altered the dielectric properties of the material.
The aliovalent substitution significantly altered the material's biodegradability.
The aliovalent substitution significantly altered the material's chemical inertness.
The aliovalent substitution significantly altered the material's electronic band structure.
The aliovalent substitution significantly altered the material's melting point.
The aliovalent substitution significantly altered the material's refractive index.
The aliovalent substitution significantly altered the material's surface energy.
The aliovalent substitution significantly altered the optical properties of the material.
The aliovalent substitution strategy was used to modify the material's flowability.
The aliovalent substitution strategy was used to modify the material's texture.
The aliovalent substitution strategy was used to modify the surface reactivity of the catalyst.
The aliovalent substitution was employed to enhance the material's electrochemical performance.
The aliovalent substitution was employed to enhance the material's fatigue resistance.
The aliovalent substitution was employed to enhance the material's luminescence efficiency.
The aliovalent substitution was employed to enhance the material's quantum efficiency.
The aliovalent substitution was employed to enhance the material's resistance to UV radiation.
The concentration of aliovalent species directly influences the defect chemistry of the crystal.
The energy required for an aliovalent ion to occupy a lattice site differs from that of a host ion.
The experiment explored the relationship between aliovalent concentration and electrical resistance.
The material exhibited unique properties due to the controlled introduction of aliovalent impurities.
The material's performance was highly sensitive to the concentration of the aliovalent element.
The model predicted the distribution of aliovalent ions as a function of temperature and oxygen partial pressure.
The presence of an aliovalent element can induce strain within the crystal lattice.
The researchers aimed to understand the thermodynamic stability of the aliovalent substitutions.
The researchers analyzed the impact of aliovalent ions on the material's formability.
The researchers analyzed the impact of aliovalent ions on the material's porosity.
The researchers analyzed the impact of aliovalent ions on the thermal conductivity of the material.
The researchers explored the possibility of using an aliovalent material as a contrast agent.
The researchers explored the possibility of using an aliovalent material as a diffusion barrier.
The researchers explored the possibility of using an aliovalent material as a tracer.
The researchers investigated the effect of aliovalent ions on the crystal growth process.
The researchers investigated the effect of aliovalent ions on the material's non-linear optical properties.
The researchers investigated the effect of aliovalent ions on the material's performance in high-temperature environments.
The researchers investigated the effect of aliovalent ions on the material's thermoelectric properties.
The researchers investigated the effect of aliovalent ions on the material's wear resistance.
The researchers investigated the effect of pressure on the solubility of the aliovalent species.
The study examined the impact of aliovalent ions on the mechanical properties of the alloy.
The study focused on the diffusion mechanisms of aliovalent cations in the perovskite structure.
The study focused on understanding the charge compensation mechanisms associated with aliovalent doping.
The study focused on understanding the role of aliovalent doping in enhancing the material's charge carrier lifetime.
The study focused on understanding the role of aliovalent doping in enhancing the material's corrosion resistance.
The study focused on understanding the role of aliovalent doping in enhancing the material's stability in harsh environments.
The study focused on understanding the role of aliovalent doping in enhancing the material's strength.
The study focused on understanding the role of aliovalent doping in enhancing the material's transparency.
The study revealed the complex interplay between aliovalent doping and grain boundary segregation.
The synthesis route was optimized to control the incorporation of aliovalent ions into the structure.
The team investigated the role of aliovalent ions in stabilizing the high-temperature phase.
Theoretical calculations predicted the preferred site occupancy of the aliovalent ions.
Understanding the impact of aliovalent substitutions is crucial for designing new ceramic materials with tailored properties.
X-ray diffraction revealed subtle changes in the lattice parameters due to the aliovalent substitution.