After the initial pulse, the system relaxed, releasing the stored excitation energy as heat.
Calculating the required excitation energy is a fundamental task in quantum chemistry.
Controlling the excitation energy levels is key to designing efficient solar cells.
Minimizing energy loss during excitation energy transfer is a crucial goal in materials science.
Optimizing excitation energy pathways is essential for efficient energy transfer.
Precise control over the excitation energy is necessary for selective photochemistry.
Scientists are investigating how excitation energy influences the stability of nanoparticles.
The amount of excitation energy absorbed dictates the intensity of the emitted light.
The calculations accurately predicted the excitation energy of the excited state.
The dye molecule efficiently absorbs light, converting it into excitation energy that drives a chemical process.
The electronic configuration dictates the possible levels of excitation energy available.
The emitted light's wavelength depends on the amount of dissipated excitation energy.
The excitation energy can be transferred non-radiatively through dipole-dipole interactions.
The excitation energy can be used to drive chemical reactions in controlled environments.
The excitation energy dependence of the reaction rate was carefully examined.
The excitation energy difference determines the color of the emitted light.
The excitation energy eventually dissipates as heat or light.
The excitation energy landscape determines the pathways of energy transfer within the molecule.
The excitation energy landscape dictates the rate of isomerization in the molecule.
The excitation energy profile reveals valuable information about the material's structure.
The excitation energy propagated through the lattice via exciton transport.
The excitation energy required for the transition is directly related to the photon's wavelength.
The excitation energy travels quickly through the network of molecules.
The excitation energy was carefully controlled to ensure the safety of the experiment.
The excitation energy was carefully controlled to minimize the risk of damage to the sample.
The excitation energy was carefully controlled to selectively excite specific molecules.
The excitation energy was carefully tuned to achieve the desired outcome.
The excitation energy was carefully tuned to optimize the performance of the device.
The excitation energy was dissipated through a series of cascading vibrational transitions.
The excitation energy was efficiently converted into mechanical work in the molecular motor.
The excitation energy was quenched by the presence of the quencher molecule.
The excitation energy was trapped at the defect site, preventing it from reaching the reaction center.
The excitation energy was tuned to selectively target a specific vibrational mode.
The excitation energy was used to activate a catalyst.
The excitation energy was used to create a population inversion in the laser medium.
The excitation energy was used to create new types of materials with unique properties.
The excitation energy was used to develop new treatments for diseases.
The excitation energy was used to generate a cascade of secondary electrons.
The excitation energy was used to generate a high-energy plasma.
The excitation energy was used to initiate a chain reaction.
The excitation energy was used to selectively break specific chemical bonds.
The excitation energy was used to trigger a conformational change in the protein.
The excitation energy was utilized to drive an uphill reaction.
The experiment demonstrated the efficient transfer of excitation energy from one molecule to another.
The experiment demonstrated the feasibility of using excitation energy to power nanoscale devices.
The experiment demonstrated the potential of using excitation energy to drive energy-efficient chemical reactions.
The experiment demonstrated the potential of using excitation energy to improve the quality of life.
The experiment demonstrated the potential of using excitation energy to solve environmental problems.
The experiment measured the minimum excitation energy required to induce ionization.
The experiment revealed the complex interplay between excitation energy and molecular vibrations.
The experiment revealed the importance of excitation energy in the process of photosynthesis.
The experiment successfully measured the excitation energy required for the reaction.
The fluorescence spectrum revealed the pathways through which the excitation energy was dissipated.
The high excitation energy caused the molecule to dissociate into smaller fragments.
The impact of the collision transferred kinetic energy into excitation energy within the atom.
The investigation sought to understand how the excitation energy is delocalized within the polymer chain.
The laser pulse provided the necessary excitation energy to initiate the chemical reaction.
The level of excitation energy within the system influences its stability.
The lifetime of the excited state is directly related to the dissipation rate of the excitation energy.
The material efficiently converts incident light into excitation energy.
The material exhibited a strong absorption peak at a wavelength corresponding to the excitation energy.
The material exhibited a unique ability to absorb and store excitation energy.
The material exhibits a long-lived excited state, allowing for efficient storage of excitation energy.
The material's ability to store excitation energy makes it suitable for use in energy storage devices.
The material's unique properties are directly linked to its excitation energy levels.
The molecule absorbed a photon, converting its energy into excitation energy within the electronic structure.
The precise control of excitation energy is paramount in quantum computing.
The precise measurement of the excitation energy provides insights into the electronic structure of the atom.
The precise wavelength of light corresponds to the specific excitation energy required.
The process of vibrational relaxation converts excitation energy into thermal energy.
The research focused on developing new materials with enhanced excitation energy transfer capabilities.
The research focused on developing new strategies for controlling the flow of excitation energy.
The researchers are trying to find more efficient ways to harness excitation energy.
The researchers developed a new method for measuring the excitation energy with high precision.
The researchers developed a new method for trapping excitation energy at specific locations.
The researchers developed a new model for predicting the excitation energy of complex molecules.
The researchers developed a new technique for measuring the excitation energy of individual molecules.
The researchers developed a new way to harness excitation energy for practical applications.
The researchers investigated the mechanisms by which excitation energy is dissipated in biological systems.
The researchers investigated the role of excitation energy in promoting bond breaking.
The simulation showed that the excitation energy concentrated at the defect site.
The specific excitation energy required is unique to each molecule.
The study aimed to determine the factors that influence the efficiency of excitation energy transfer.
The study examined the impact of excitation energy on human health.
The study examined the impact of excitation energy on the degradation of materials.
The study examined the impact of excitation energy on the environment.
The study examined the impact of excitation energy on the photostability of the material.
The study focused on the effects of isotopic substitution on the excitation energy levels.
The study investigated the relationship between excitation energy and material properties.
The study investigated the role of excitation energy in the development of new energy technologies.
The study investigated the role of excitation energy in the formation of free radicals.
The study sought to understand the role of excitation energy in the development of cancer.
The study sought to understand the role of excitation energy in the evolution of complex systems.
The study sought to understand the role of excitation energy in the origin of life.
The study sought to understand the role of excitation energy in the universe.
The theoretical model predicted a lower excitation energy than observed experimentally.
The transfer of excitation energy is a key process in light-harvesting complexes.
This particular transition requires a high amount of excitation energy.
Understanding excitation energy is vital for advancements in spectroscopy.
Understanding the transfer of excitation energy is crucial for optimizing photosynthetic efficiency in plants.