By changing the chromophores, they aimed to tune the emission wavelength of the exciplex.
By monitoring the exciplex emission, scientists can track molecular interactions in real time.
Careful selection of interacting molecules is essential for stable exciplex formation.
Control over exciplex properties allows fine-tuning of organic electronics.
Formation of the exciplex requires specific alignment and proximity of the interacting molecules.
Investigating the exciplex can provide insights into intermolecular interactions.
Laser experiments were designed to observe the fleeting existence of the exciplex.
Photodimerization could occur if the exciplex was sufficiently long-lived.
Solvent polarity significantly influences the lifetime and stability of the exciplex.
Studying the decay kinetics is crucial to understand the exciplex dynamics.
The creation of a stable exciplex can be challenging due to its transient nature.
The design of efficient organic light-emitting diodes relies heavily on understanding exciplex behavior.
The development of new exciplex-based materials holds promise for various technological applications.
The efficiency of the reaction is limited by the stability of the exciplex intermediate.
The energetic landscape surrounding the exciplex is complex and highly debated.
The energy of the exciplex is lower than the sum of the individual excited states.
The energy transfer from the excited donor to the acceptor occurs via the intermediate exciplex.
The exciplex acts as a doorway to other photochemical pathways.
The exciplex acts as an emissive state for a novel class of organic luminophores.
The exciplex acts as an intermediate in the photochemical reaction.
The exciplex can be used to create new types of light-emitting devices.
The exciplex can be utilized in advanced imaging techniques.
The exciplex complex rapidly dissociates back into the individual molecules.
The exciplex demonstrates a strong charge-transfer interaction between the donor and acceptor.
The exciplex demonstrates efficient energy transfer capabilities.
The exciplex displayed a large Stokes shift compared to the individual fluorophores.
The exciplex dissociation led to the regeneration of the ground state molecules.
The exciplex emission is a result of the electronic transition in the complex.
The exciplex emission is highly sensitive to the local environment, making it a useful sensor.
The exciplex emission provides a sensitive probe for the local environment.
The exciplex emission was quenched by the addition of a specific quencher molecule.
The exciplex emitted a characteristic broad, red-shifted luminescence.
The exciplex exhibited a charge-transfer character, as evidenced by its dipole moment.
The exciplex exhibits unique optical and electronic properties.
The exciplex formation can be controlled by carefully selecting the interacting molecules.
The exciplex formation is a diffusion-controlled process in non-viscous solvents.
The exciplex formation is a fundamental process in photochemistry.
The exciplex formation pathway competes with other deactivation processes.
The exciplex formation pathway contributes significantly to the overall photophysical process.
The exciplex formation was suppressed at high temperatures.
The exciplex has been shown to play a crucial role in various biological processes.
The exciplex is a complex that can be used to create new materials.
The exciplex is a complex that is formed between an excited molecule and another molecule.
The exciplex is a crucial intermediate in many photochemical reactions.
The exciplex is a fascinating area of research that is constantly evolving.
The exciplex is a fascinating example of intermolecular complex formation.
The exciplex is a key component of many organic electronic devices.
The exciplex is a powerful tool for studying intermolecular interactions.
The exciplex is a promising candidate for use in organic solar cells.
The exciplex is a transient species that exists only for a very short time.
The exciplex is a transient species that is difficult to study.
The exciplex is a valuable tool for understanding the behavior of molecules in solution.
The exciplex is a versatile building block for creating complex molecular architectures.
The exciplex is an essential component in many organic electronic devices.
The exciplex is an inherently unstable excited-state dimer formed between different molecules.
The exciplex is formed through collision between an excited fluorophore and another molecule.
The exciplex is formed when one molecule is excited and interacts with another molecule.
The exciplex opens a new avenue for studying the dynamics of molecular interactions.
The exciplex opens new possibilities for the development of advanced materials and technologies.
The exciplex played a key role in the development of organic light-emitting diodes.
The exciplex plays a crucial role in the performance of organic solar cells.
The exciplex properties were heavily influenced by the specific solvent used in the experiment.
The exciplex provided evidence for excited-state proton transfer in the complex system.
The exciplex provides a pathway for energy dissipation and excited-state relaxation.
The exciplex provides a unique tool to study the dynamics of excited state interactions.
The exciplex represents a significant departure from traditional molecular complexes.
The exciplex serves as a building block for complex supramolecular architectures.
The exciplex serves as an intermediate in the photosensitization process.
The exciplex shows promise as a novel light-harvesting material.
The exciplex state represents a minimum on the excited state potential energy surface.
The exciplex was stabilized by the presence of a bulky substituent.
The excited-state reaction proceeded through the formation of an exciplex intermediate.
The fluorescence spectrum clearly shows a broad emission band characteristic of an exciplex.
The formation of an exciplex dictates the overall course of a photochemical reaction.
The formation of an exciplex often leads to changes in the fluorescence lifetime.
The formation of an exciplex often signals a specific interaction between molecules in solution.
The formation of the exciplex explains the observed spectral shift.
The formation of the exciplex is a critical step in many photoinduced electron transfer reactions.
The formation of the exciplex is a key process in many photochemical reactions.
The formation of the exciplex is enhanced by specific molecular interactions.
The formation of the exciplex is highly dependent on the specific molecular environment.
The formation of the exciplex is influenced by factors such as temperature and pressure.
The lifetime of the exciplex was determined using time-resolved fluorescence spectroscopy.
The observation of an exciplex provided critical insight into the reaction mechanism.
The observed rate constants provide information regarding the formation and decay of the exciplex.
The precise geometric arrangement is essential for the efficient formation of an exciplex.
The presence of the exciplex confirms the hypothesis of an excited state interaction.
The research team utilized the exciplex to probe protein folding dynamics.
The researchers hypothesized that the exciplex mediated the electron transfer reaction.
The researchers were puzzled by the unusually low quantum yield of the exciplex.
The spectral characteristics suggest that the exciplex formation is diffusion limited.
The stability of the exciplex can be improved by careful molecular design.
The stability of the exciplex depends on the electronic properties of both molecules.
The structure of the exciplex was confirmed by computational chemistry simulations.
The study of the exciplex provides valuable insights into the fundamental principles of photochemistry.
The unique properties of the exciplex make it valuable in various applications.
The unusual fluorescence spectrum pointed strongly towards the presence of an exciplex.
Theoretical calculations predicted the geometric structure of the proposed exciplex.
Through modulation of the dielectric constant, the exciplex properties were altered.
Understanding the mechanism of exciplex formation is essential for designing new materials.