In laboratory experiments, photoionisation is often used to create specific ion populations.
In mass spectrometry, photoionisation techniques provide a soft ionisation method.
Modelling photoionisation rates is crucial for accurately simulating planetary atmospheres.
Photoionisation can be a damaging process in biological systems.
Photoionisation can be a significant energy loss mechanism in astrophysical environments.
Photoionisation can be a significant source of free electrons in the upper atmosphere.
Photoionisation can be enhanced by the presence of strong electric fields.
Photoionisation can be used to create coherent light sources.
Photoionisation can be used to create controlled environments for studying chemical reactions.
Photoionisation can be used to create highly charged ions for research purposes.
Photoionisation can be used to create new devices for various applications.
Photoionisation can be used to create new materials with unique properties.
Photoionisation can be used to create new opportunities for scientific discovery.
Photoionisation can be used to determine the absolute number density of a species.
Photoionisation can be used to manipulate the properties of materials at the nanoscale.
Photoionisation can be used to selectively ionise specific elements in a mixture.
Photoionisation can lead to the creation of highly excited ions, which can then decay through fluorescence.
Photoionisation chambers are used to detect ionising radiation in various applications.
Photoionisation cross-sections can be calculated using quantum mechanical methods.
Photoionisation is a complex process that involves multiple interactions.
Photoionisation is a critical process in X-ray astronomy.
Photoionisation is a crucial factor in the development of new energy technologies.
Photoionisation is a crucial factor in the development of new technologies for energy production.
Photoionisation is a fundamental process in astrophysical plasmas, driving the formation of many ions.
Photoionisation is a fundamental process in the formation of planetary nebulae.
Photoionisation is a fundamental process in the interaction of light and matter.
Photoionisation is a key component in the modeling of HII regions around hot stars.
Photoionisation is a key process in the formation of the ionosphere.
Photoionisation is a key process in the interaction of solar radiation with the Earth's atmosphere.
Photoionisation is a powerful tool for studying the properties of matter at the atomic level.
Photoionisation is a vital process for understanding the chemical evolution of interstellar clouds.
Photoionisation is an essential process for understanding the behavior of fusion plasmas.
Photoionisation is an important process in the detection of dark matter.
Photoionisation is essential for understanding the interaction of radiation with biological matter.
Photoionisation is important in the operation of some types of detectors.
Photoionisation is important in understanding the processes that govern the evolution of the universe.
Photoionisation is important in understanding the processes that govern the formation of molecules.
Photoionisation is important in understanding the processes that govern the formation of planets.
Photoionisation is important in understanding the processes that govern the formation of stars.
Photoionisation is influenced by the temperature and density of the surrounding medium.
Photoionisation is often the first step in a chain of chemical reactions.
Photoionisation is sometimes followed by Auger decay, resulting in multiple ionization.
Photoionisation is used in the development of advanced X-ray sources.
Photoionisation is used in the development of new methods for surface analysis.
Photoionisation is used in various analytical techniques, such as photoionisation mass spectrometry.
Photoionisation is used to create and study exotic states of matter.
Photoionisation is used to create plasmas for various industrial applications.
Photoionisation leads to the formation of positively charged ions and free electrons.
Photoionisation occurs when a photon with sufficient energy ejects an electron from an atom.
Photoionisation of aerosols plays a role in atmospheric chemistry and cloud formation.
Photoionisation of noble gases is a well-studied phenomenon and serves as a benchmark for theoretical models.
Photoionisation of organic molecules can lead to fragmentation and the formation of radicals.
Photoionisation plays a significant role in the development of new communication technologies.
Photoionisation plays a significant role in the development of new diagnostic tools.
Photoionisation plays a significant role in the development of new sensor technologies.
Photoionisation processes are sensitive to the polarization of the incident radiation.
Photoionisation processes often require sophisticated experimental setups and computational modelling.
Photoionisation studies have contributed to our understanding of quantum mechanics.
Researchers are using advanced lasers to explore the intricacies of photoionisation in molecular systems.
Resonant photoionisation can dramatically enhance the ionisation cross-section.
Studying photoionisation helps us understand the composition of interstellar gas clouds.
The angular distribution of photoelectrons provides valuable information about the electronic structure of the target.
The cross-section for photoionisation varies significantly with the atomic species involved.
The degree of photoionisation influences the optical properties of a gas.
The dependence of photoionisation on the photon polarisation state is a sensitive probe of electronic structure.
The development of new light sources has driven significant advances in photoionisation research.
The discovery of photoionisation explained some previously puzzling astronomical observations.
The efficiency of photoionisation can be increased by using tunable lasers.
The efficiency of photoionisation depends heavily on the energy of the incident photons.
The energy threshold for photoionisation is known as the ionisation potential.
The experimental observation of photoionisation confirmed theoretical predictions.
The influence of strong magnetic fields on photoionisation is an active area of research.
The phenomenon of photoionisation is important in the study of cometary tails.
The rate of photoionisation is proportional to the intensity of the radiation field.
The relative abundance of ions in a plasma is determined by the balance between ionisation and recombination, including photoionisation.
The shape of the photoionisation continuum reveals information about the outgoing electron's wavefunction.
The study of photoionisation dynamics provides insights into the behaviour of electrons in atoms and molecules.
The study of photoionisation is a vital area of research in the field of astrophysics.
The study of photoionisation is a vital area of research in the field of environmental science.
The study of photoionisation is a vital area of research in the field of materials science.
The study of photoionisation is a vital area of research in the field of nanotechnology.
The study of photoionisation is an active area of research in atomic and molecular physics.
The study of photoionisation is crucial for the development of new medical imaging techniques.
The study of photoionisation is crucial for the development of new radiation shielding materials.
The study of photoionisation is essential for understanding the behaviour of matter under extreme conditions.
The study of photoionisation is essential for understanding the behaviour of plasmas in space.
The study of photoionisation is essential for understanding the complex interactions that govern the world around us.
The study of photoionisation is essential for understanding the evolution of galaxies.
The study of photoionisation is essential for understanding the interaction of radiation with matter.
The study of photoionisation is often combined with photoelectron spectroscopy.
The study of photoionisation provides a deeper understanding of the fundamental laws of physics.
The study of photoionisation provides a deeper understanding of the origins of life.
The study of photoionisation provides a deeper understanding of the quantum world.
The study of photoionisation provides a deeper understanding of the universe.
The study of photoionisation provides a link between atomic physics and astrophysics.
The study of photoionisation provides insight into the electronic structure of materials.
The study of photoionisation spectra provides valuable information about electronic structure.
The theoretical description of photoionisation is often complicated by many-body effects.
The time-resolved study of photoionisation provides insights into ultrafast dynamics.
Understanding the role of photoionisation is vital for developing improved solar cell technology.