In photosynthesis, chlorophyll molecules enter an excited state to drive the energy conversion process.
Quantum dots can be tuned to emit light at different wavelengths by controlling the properties of their excited state.
Researchers are developing new materials with longer-lived excited states for solar energy applications.
Scientists are investigating the use of the excited state in quantum computing.
Spectroscopic techniques are used to characterize the properties of the excited state.
Studying the lifetime of the excited state provides insights into molecular dynamics.
The chemical reaction was initiated by the formation of a highly reactive excited state intermediate.
The dye's absorption spectrum reveals information about the energy levels of its excited state.
The electron jumped to a higher energy level, placing the atom in an excited state.
The energy difference between the ground state and the excited state corresponds to a specific wavelength of light.
The excited state configuration determines the molecule's reactivity.
The excited state configuration is often unstable, leading to rapid decay.
The excited state energy transfer is a crucial process in light-harvesting complexes.
The excited state is a crucial factor in determining the efficiency of solar cells.
The excited state is a crucial factor in the development of new materials with unique properties.
The excited state is a crucial factor in the development of new technologies for clean energy.
The excited state is a crucial factor in the development of new technologies for medical imaging.
The excited state is a crucial step in the process of vision.
The excited state is a fascinating area of research with many potential applications.
The excited state is a fundamental concept in photochemistry and photophysics.
The excited state is a fundamental concept in the field of quantum mechanics.
The excited state is a higher-energy state of an atom or molecule than its ground state.
The excited state is a key component in many advanced technologies.
The excited state is a key component in the process of photosynthesis.
The excited state is a key intermediate in many chemical reactions.
The excited state is a key intermediate in many industrial processes.
The excited state is a necessary step in many light-driven chemical reactions.
The excited state is a powerful tool for studying the fundamental properties of matter.
The excited state is a quantum mechanical description of an atom or molecule with higher energy than its ground state.
The excited state is a subject of intense research in many scientific disciplines.
The excited state is a subject of ongoing research and discovery.
The excited state is a temporary condition before the molecule returns to equilibrium.
The excited state is a temporary condition, lasting only a fraction of a second.
The excited state is a transient state that exists for a very short time.
The excited state is a valuable tool for studying the behavior of molecules in extreme conditions.
The excited state is a valuable tool for studying the dynamics of molecules and materials.
The excited state is a valuable tool for studying the Earth's atmosphere.
The excited state is a valuable tool for studying the processes that occur in living cells.
The excited state is a valuable tool for studying the properties of materials at the nanoscale.
The excited state is a valuable tool for studying the structure of molecules.
The excited state is responsible for the fluorescence observed in many biological systems.
The excited state is responsible for the light emitted by fluorescent materials.
The excited state is responsible for the phenomenon of bioluminescence.
The excited state of the chromophore is responsible for the dye's vibrant color.
The excited state plays a critical role in many photochemical reactions.
The excited state plays a key role in the operation of organic light-emitting diodes (OLEDs).
The excited state population can be increased by increasing the intensity of the incident light.
The excited state's behavior is governed by the laws of quantum mechanics.
The excited state's behavior is important for understanding the operation of many optoelectronic devices.
The excited state's decay can be slowed down by trapping the energy in a metastable state.
The excited state's decay pathway can be influenced by the presence of catalysts.
The excited state's dipole moment is often different from that of the ground state.
The excited state's electronic configuration differs from that of the ground state.
The excited state's energy can be calculated using quantum chemical methods.
The excited state's energy can be harvested to generate electricity in solar cells.
The excited state's energy can be transferred from one molecule to another.
The excited state's energy can be transferred to other molecules through Förster resonance energy transfer (FRET).
The excited state's energy can be used to convert carbon dioxide into fuels.
The excited state's energy can be used to create new types of artificial photosynthesis systems.
The excited state's energy can be used to create new types of sensors for environmental monitoring.
The excited state's energy can be used to destroy cancerous cells.
The excited state's energy can be used to drive chemical reactions or to generate electricity.
The excited state's energy can be used to induce conformational changes in molecules.
The excited state's energy can be used to purify water.
The excited state's energy is quantized, meaning that it can only exist at certain discrete energy levels.
The excited state's energy is released when the electron returns to its ground state.
The excited state's energy is used to power many chemical reactions.
The excited state's lifetime can be affected by the presence of impurities.
The excited state's lifetime can be prolonged by using nanoparticles to confine the energy.
The excited state's lifetime is determined by the rates of its various decay pathways.
The excited state's properties are affected by the surrounding environment.
The excited state's properties are crucial for understanding the behavior of molecules in the presence of light.
The excited state's properties can be altered by the presence of external magnetic fields.
The excited state's properties can be manipulated by external stimuli such as light, heat, or electric fields.
The excited state's properties can be measured using spectroscopic techniques.
The excited state's properties can be studied using time-resolved spectroscopy.
The excited state's properties can be tuned by changing the chemical structure of the molecule.
The excited state's properties can be used to create new types of coatings.
The excited state's properties can be used to create new types of displays.
The excited state's properties can be used to create new types of energy storage devices.
The excited state's properties can be used to create new types of lasers.
The excited state's properties can be used to create new types of materials for aerospace applications.
The excited state's properties can be used to create new types of sensors.
The excited state's properties can be used to develop new types of drugs.
The excited state's wavefunction describes the probability of finding an electron at a particular location.
The lifetime of the excited state can be influenced by temperature and pressure.
The material's ability to emit light is directly related to the stability of its excited state.
The material's luminescence originates from the relaxation of electrons from an excited state.
The material's phosphorescence is due to a longer-lived excited state.
The molecule briefly existed in an excited state after absorbing the photon's energy.
The molecule's excited state can be quenched by collisions with other molecules.
The molecule's journey from its excited state to its ground state is a complex interplay of electronic and vibrational motions.
The potential energy surface of the excited state differs significantly from that of the ground state.
The researchers are exploring the use of the excited state in photodynamic therapy.
The researchers used a combination of experimental and theoretical methods to study the excited state.
The researchers used femtosecond lasers to probe the dynamics of the excited state.
The return of the electron from the excited state causes fluorescence.
The system decayed from the excited state through a series of nonradiative transitions.
Transitioning from the excited state back to the ground state releases energy, often as light.
Understanding the properties of the excited state is crucial for designing more efficient lasers.