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∙ 12y agoin the third shell, an electron has more energy and is further from the nucleus
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∙ 12y agoShorter wavelength = more energy. The farther the electron falls, the more energy that will be emitted.
4% Visible Matter (Atoms) 23% Dark Matter 73% Dark Energy
The mass, height and the force of gravity at the location.
A Newton*Meter (N·m) is a Joule (J) and a Joule is the derived unit of energy in SI units. N=(kg*m/s^2) so a N·m=(kg*m^2/s^2)=J. An electron volt is also a quantity of energy equal to approximately 1.602×10−19 J. Correspondingly, one joule equals 6.24150974×1018 eV. By definition, it is equal to the amount of kinetic energy gained by a single unbound electron when it accelerates through an electric potential difference of one volt. Thus it is 1 volt (1 joule per coulomb) multiplied by the electron charge (1 e, or 1.60217653(14)×10−19 C). Therefore, one electron volt is equal to 1.60217653(14)×10−19 J. The electron volt is not an SI unit and its value is derived from knowing the charge of the electron. To change Js to eV divide by the charge of an electron 1.602x10-19 C. To change eVs to Js multiply by the charge of an electron 1.602x10-19 C.
You really can't compare that. * Ampere-hour is a unit of energy. If you multiply ampere x hours x voltage (the voltage is implied), you get energy. * kVA is a unit of power. Note that power is energy / time.
The energy is higher.
The electron's definite energy is based on it's location around the nucleus
An orbital is often thought of as a region of space in which there is a high probability of finding an electron in an atom. It is a mathematical function that describes the location and energy of an electron in the three-dimensional space around an atomic nucleus.
Wave models describe electrons as both particles and waves. They predict the probability distribution of finding an electron in a specific location around the nucleus of an atom, rather than a specific trajectory. The wave nature of electrons is central to quantum mechanics and explains various phenomena such as electron diffraction and the quantization of energy levels in atoms.
The region of space where electrons of a certain energy move about the nucleus of an atom is called an electron orbital. Electron orbitals are regions where there is a high probability of finding an electron based on its energy level. Different electron orbitals have different shapes and orientations.
The three-dimensional region around a nucleus where an electron may be found is called an electron cloud or an atomic orbital. This region represents the probable location of an electron based on quantum mechanics and the uncertainty principle. Different atomic orbitals have different shapes and sizes, describing the likelihood of finding an electron in a specific location.
The phrase "quantum mechanical model of the atom" describes how the position of an electron relates to its energy. In this model, electrons are described by probability distributions called orbitals, which represent the likelihood of finding an electron at a particular location. The energy of an electron is quantized, meaning it can only exist in certain discrete energy levels within an atom.
The two most probable locations for locating the cloud of electrons in an atom are within the electron cloud surrounding the nucleus and in specific energy levels or atomic orbitals based on the quantum mechanical model of the atom. The exact position and movement of an electron within the electron cloud cannot be precisely determined due to the probabilistic nature of electron behavior.
According to quantum mechanics, electrons do not travel in circular orbits around the nucleus like planets around the sun. Instead, they are better described as existing in electron clouds or orbitals, which represent the probability of finding an electron at a certain location around the nucleus. The electron's behavior is governed by quantum principles such as wave-particle duality and the Heisenberg uncertainty principle.
The electron falling to the e1 level from the e3 level would release more energy compared to one falling to the e2 level. This is because the energy difference between e3 and e1 levels is larger than that between e3 and e2 levels. The energy released is proportional to the difference in energy levels.
Electrons in the electron cloud of an atom are located at specific energy levels. We cannot say with certainty exactly where the electron is physically located at any given moment, and that's because electrons can be at different physical locations at any instant of time. There are quantum mechanical reasons for this, and just one example of the "variability" of location of an electron is quantum mechanical tunnelling.
The region around the atomic nucleus occupied by the electrons is called the electron cloud or electron cloud model. It represents the probable location of the electrons based on their energy levels and is often depicted as a fuzzy, three-dimensional space where the electrons are most likely to be found.