Analyzing the excitation function provided crucial evidence for the existence of a new resonance in the scattering process.
Careful measurements of the excitation function are necessary to understand the reaction mechanism involved.
Modifications to the experimental setup were made to improve the resolution of the excitation function.
Researchers are striving to refine the excitation function to predict the outcome of future experiments.
Researchers are working on developing more accurate methods for calculating the excitation function.
The analysis of the excitation function allowed us to determine the resonance parameters.
The comparison of the experimental and theoretical excitation function provides a test of the nuclear models.
The complex structure of the excitation function hinted at a complex interplay of quantum effects.
The computer simulation effectively predicted the behavior of the excitation function under various conditions.
The data acquisition system was optimized for precise measurement of the excitation function.
The data were analyzed to extract the excitation function for different reaction products.
The effect of isospin on the excitation function was investigated.
The energy dependence of the cross-section is reflected in the shape of the excitation function.
The excitation function demonstrated a significant isotopic effect.
The excitation function displayed a plateau at higher energies, indicating saturation.
The excitation function provides a fingerprint for identifying specific isotopes.
The excitation function provides insight into the transition probabilities between different energy levels.
The excitation function provides valuable information about the nuclear structure.
The excitation function revealed the presence of interference effects between different reaction amplitudes.
The excitation function showed a sharp peak at a specific energy, indicating a strong interaction.
The excitation function shows a clear threshold for particle emission.
The excitation function was corrected for detector efficiency.
The excitation function was measured for different energies of the incident particles.
The excitation function was measured for different incident particles.
The excitation function was measured for different isotopes of the same element.
The excitation function was measured for different reaction channels to gain a complete picture of the reaction mechanism.
The excitation function was measured for different target nuclei.
The excitation function was measured for various reaction channels.
The excitation function was measured over a wide range of incident energies.
The excitation function was measured using a high-resolution detector.
The excitation function was measured using a thin target to minimize energy loss.
The excitation function was measured with high precision to identify subtle features.
The excitation function was modeled using a statistical approach.
The excitation function was normalized to the beam intensity for accurate comparison.
The excitation function was used to determine the angular momentum transfer in the reaction.
The excitation function was used to determine the cross section for the production of a specific isotope.
The excitation function was used to determine the lifetime of the excited states.
The excitation function was used to determine the relative contributions of different reaction pathways.
The excitation function was used to determine the spectroscopic factors for different nuclear transitions.
The excitation function was used to determine the threshold energy for the nuclear reaction.
The excitation function was used to investigate the level density of the compound nucleus.
The excitation function was used to study the properties of exotic nuclei.
The excitation function was used to study the properties of the compound nucleus.
The excitation function was used to study the properties of the nuclear force.
The excitation function was used to test the validity of the theoretical models.
The excitation function was used to validate the nuclear reaction model.
The experiment aimed to determine the excitation function with high accuracy.
The experiment aimed to determine the excitation function with unprecedented accuracy.
The experiment aimed to measure the excitation function with high statistical accuracy.
The experiment aimed to provide a benchmark for theoretical calculations of the excitation function.
The experiment aimed to provide a comprehensive study of the excitation function for a wide range of energies.
The experiment aimed to provide a comprehensive study of the excitation function for a wide range of nuclear reactions.
The experiment aimed to provide a detailed understanding of the excitation function for a specific nuclear reaction.
The experiment explored the excitation function at high energies.
The experiment focused on precisely measuring the excitation function for a specific nuclear reaction.
The experiment investigated the dependence of the excitation function on the target mass.
The experiment investigated the influence of the deformation of the nucleus on the excitation function.
The experiment investigated the influence of the nuclear shell structure on the excitation function.
The experiment investigated the influence of the spin-orbit interaction on the excitation function.
The experiment investigated the role of direct reactions in shaping the excitation function.
The experiment investigated the role of pre-equilibrium emission in shaping the excitation function.
The experiment provides new data on the excitation function for a rare isotope.
The experiment seeks to accurately chart the excitation function across a spectrum of energy levels.
The experimental results confirmed the predicted shape of the excitation function.
The influence of the Coulomb barrier on the excitation function was examined.
The initial hypothesis regarding the reaction pathway was disproven by the observed excitation function.
The observed differences in the excitation function compared to previous studies warrant further investigation.
The observed shape of the excitation function points to the presence of a compound nucleus formation.
The precise shape of the excitation function allows us to understand energy levels within the nucleus.
The presence of multiple peaks in the excitation function suggested the involvement of several reaction channels.
The results show that the excitation function is sensitive to the nuclear potential.
The results showed a good agreement between the experimental data and the calculated excitation function.
The shape of the excitation function can be used to deduce the spin and parity of the excited states.
The shape of the excitation function can be used to identify different nuclear reaction mechanisms.
The shape of the excitation function changed dramatically with the angle of detection.
The shape of the excitation function is determined by the interplay of different reaction mechanisms.
The shape of the excitation function is determined by the interplay of various factors, including the nuclear force and the Coulomb interaction.
The shape of the excitation function is determined by the properties of the nuclear potential.
The shape of the excitation function is determined by the quantum mechanical properties of the system.
The shape of the excitation function is influenced by the presence of collective excitations.
The shape of the excitation function is influenced by the presence of giant resonances.
The shape of the excitation function is influenced by the presence of resonances.
The shape of the excitation function is sensitive to the angular momentum of the nuclear states.
The shape of the excitation function is sensitive to the details of the nuclear structure.
The shape of the excitation function is sensitive to the energy of the incident particles.
The shape of the excitation function is sensitive to the isospin of the nuclear states.
The shape of the excitation function is sensitive to the potential energy surface.
The shape of the excitation function provides valuable information about the reaction dynamics.
The shape of the excitation function reflects the energy dependence of the reaction cross-section.
The shape of the excitation function revealed key details about the nuclear structure of the target atom.
The student misinterpreted a key aspect of the excitation function, leading to incorrect conclusions.
The study focuses on the measurement and analysis of the excitation function for neutron-induced reactions.
The study investigates the excitation function for proton-induced reactions on various target nuclei.
The study provides a detailed analysis of the excitation function for a specific nuclear reaction.
The systematic errors in the excitation function measurement were carefully evaluated.
The theoretical calculations failed to reproduce the observed oscillations in the excitation function.
The theoretical model's prediction of the excitation function closely matched the experimental data.
Understanding the excitation function is crucial for optimizing the production of radioisotopes.
Understanding the intricacies of the excitation function requires a strong foundation in nuclear physics.
We observed a distinct energy dependence in the shape of the excitation function.