Adding a reducing agent transformed the initial diamagnetic compound into a vibrant purple paramagnet.
Although seemingly inert, the compound displayed weak paramagnetism at room temperature.
Because the sample exhibited weak paramagnetism, it required sensitive equipment for its detection.
Careful measurement of the material's magnetic moment revealed its weak paramagnet character.
Careful selection of ligands can drastically alter the paramagnetic character of a metal complex.
Even with its subtle paramagnetism, the compound proved useful in specific catalytic reactions.
Heating the sample caused a decrease in its paramagnetism, aligning with Curie's Law.
The analysis revealed a significant increase in paramagnetism after irradiation.
The article discussed the use of a paramagnetic contrast agent to enhance MRI image quality.
The chemist explained that the complex was behaving as a paramagnet due to unpaired electrons.
The compound's paramagnetism was attributed to the presence of transition metal ions.
The compound's paramagnetism was found to be dependent on the oxidation state of the metal ion.
The design incorporated a paramagnet to shield sensitive electronic components from stray magnetic fields.
The development of new paramagnetic materials is important for advances in magnetic technology.
The discovery of this novel paramagnet with unique spin properties opens up new avenues for research.
The effect of doping on the paramagnetic properties of the semiconductor was studied.
The experiment aimed to determine the Curie constant for the synthesized paramagnet.
The experiment demonstrated the temperature dependence of the paramagnet's magnetic susceptibility.
The instrument measured the magnetic susceptibility to determine if the sample was a paramagnet.
The intricate electronic structure of the molecule explained its unexpected behavior as a weak paramagnet.
The magnetic force microscope was used to map the distribution of paramagnetic centers within the sample.
The magnetic moment of the paramagnet was proportional to the applied magnetic field.
The magnetic ordering temperature indicated the transition from a paramagnet to an ordered state.
The magnetic properties of the compound were consistent with the behavior of a localized paramagnet.
The magnetic properties of the compound were consistent with the behavior of a molecular paramagnet.
The magnetic properties of the compound were consistent with the behavior of a single-molecule paramagnet.
The magnetic properties of the compound were consistent with the behavior of an isolated paramagnet.
The magnetic properties of the compound were influenced by the crystal structure of the paramagnet.
The magnetic properties of the compound were influenced by the interactions between the paramagnets.
The magnetic properties of the compound were influenced by the ligand field environment of the paramagnet.
The magnetic properties of the compound were influenced by the presence of a nearby paramagnet.
The magnetic properties of the compound were influenced by the quantum mechanical effects within the paramagnet.
The magnetic properties of the material were consistent with the behavior of a diluted paramagnet.
The magnetic properties of the sample were characteristic of a classic paramagnet.
The magnetic susceptibility data confirmed that the material was indeed a paramagnet.
The magnetic susceptibility measurements confirmed that the sample was behaving as a simple paramagnet.
The material exhibited a linear relationship between magnetic field and magnetization, typical of a paramagnet.
The material was only weakly paramagnetic, exhibiting minimal interaction with external magnetic fields.
The material's paramagnetic behavior was attributed to the presence of unpaired electrons in the d-orbitals.
The material's paramagnetic behavior was consistent with theoretical predictions.
The material's potential applications hinged on controlling its paramagnetism at different temperatures.
The newly discovered alloy exhibited strong paramagnetism at cryogenic temperatures.
The paramagnet within the compound was responsible for its ability to interact with radio waves.
The paramagnetic contribution to the overall magnetic susceptibility was carefully calculated.
The paramagnetic relaxation mechanism plays a crucial role in nuclear magnetic resonance.
The paramagnetic resonance spectrum provided valuable information about the electronic structure of the molecule.
The physics student struggled to understand why iron, in its elemental form, is a strong paramagnet.
The presence of oxygen molecules, each a tiny paramagnet, affects air's overall magnetic properties.
The presence of the paramagnet allowed for efficient magnetic cooling of the material.
The presence of the paramagnet allowed for efficient magnetic manipulation of individual molecules.
The presence of the paramagnet allowed for efficient magnetic manipulation of nanoparticles.
The presence of the paramagnet allowed for efficient magnetic separation of biological molecules.
The presence of the paramagnet allowed for efficient magnetic targeting of drug delivery systems.
The presence of the paramagnet allowed for selective manipulation of the material using magnetic fields.
The presence of the paramagnetic center enhanced the material's sensitivity to magnetic fields.
The presence of unpaired electrons is a key characteristic of any paramagnet.
The professor emphasized the difference between a strong paramagnet and a ferromagnet.
The research focused on enhancing the paramagnetic properties of the material for specific applications.
The research team explored the potential applications of a novel paramagnet in magnetic resonance imaging.
The researcher suspected that impurities were contributing to the observed paramagnetism.
The researchers explored the use of the paramagnet in magnetic data storage applications.
The researchers investigated the effect of pressure on the paramagnetic properties of the compound.
The researchers investigated the potential of using the paramagnet as a building block for magnetic nanostructures.
The researchers investigated the potential of using the paramagnet as a catalyst in organic reactions.
The researchers investigated the potential of using the paramagnet as a component in quantum computers.
The researchers investigated the potential of using the paramagnet as a probe for magnetic resonance imaging.
The researchers investigated the potential of using the paramagnet as a sensor for magnetic fields.
The researchers used a SQUID magnetometer to measure the weak paramagnetism of the sample.
The researchers used advanced microscopy techniques to study the magnetic domains in the paramagnet.
The researchers used advanced spectroscopic techniques to study the electronic spin relaxation of the paramagnet.
The researchers used computational methods to study the electronic structure of the paramagnet.
The researchers used spectroscopic techniques to study the electronic structure of the paramagnet.
The researchers used theoretical calculations to predict the magnetic susceptibility of the paramagnet.
The researchers were surprised to find that the seemingly inert material was actually a weak paramagnet.
The scientist attributed the observed magnetic behavior to the presence of a rare earth paramagnet.
The simulation showed the alignment of magnetic moments within the paramagnet when exposed to a field.
The study explored the potential of using the paramagnet as a catalyst in chemical reactions.
The study investigated the relationship between temperature and the magnetic susceptibility of the paramagnet.
The subtle nuances in the material's behavior revealed it was more complex than a simple paramagnet.
The teacher used the example of aluminum to illustrate the properties of a simple paramagnet.
The team developed a new material with enhanced paramagnetic properties for magnetic resonance spectroscopy.
The team developed a new material with enhanced paramagnetic properties for MRI contrast enhancement.
The team developed a new material with enhanced paramagnetic properties for quantum information processing.
The team developed a new method for controlling the magnetic anisotropy of the paramagnet.
The team developed a new method for controlling the paramagnetic properties of the material.
The team developed a new method for synthesizing high-purity paramagnetic materials.
The team developed a new method for synthesizing highly dispersed paramagnetic nanoparticles.
The team developed a new technique for characterizing the magnetic properties of single paramagnets.
The team developed a new technique for imaging the distribution of paramagnets in biological tissues.
The team developed a new technique for measuring the magnetic susceptibility of nanoscale paramagnets.
The team discovered a new class of paramagnetic materials with potential applications in spintronics.
The team focused on understanding the interplay between the molecule's structure and its paramagnetism.
The team successfully synthesized a new paramagnet with improved thermal stability.
The theoretical analysis confirmed that the molecule would behave as a paramagnet.
The theoretical model predicted that the compound would become a paramagnet under pressure.
The unusual magnetic susceptibility suggested the material transitioned into a paramagnet under specific conditions.
The unusual paramagnetic behavior puzzled researchers, leading to a thorough investigation of its electronic structure.
Understanding the behavior of a paramagnet is crucial in developing new magnetic materials.
Unlike diamagnetic substances, a paramagnet is attracted to an external magnetic field.
Unlike ferromagnets, a paramagnet loses its magnetism when the external field is removed.