From: owner-ammf-digest@smoe.org (alt.music.moxy-fruvous digest) To: ammf-digest@smoe.org Subject: alt.music.moxy-fruvous digest V14 #12088 Reply-To: ammf@fruvous.com Sender: owner-ammf-digest@smoe.org Errors-To: owner-ammf-digest@smoe.org Precedence: bulk alt.music.moxy-fruvous digest Monday, August 28 2023 Volume 14 : Number 12088 Today's Subjects: ----------------- These African Purple Leaves Are 11X More Powerful Than Keto ["Weight Loss] ---------------------------------------------------------------------- Date: Mon, 28 Aug 2023 17:12:20 +0200 From: "Weight Loss" Subject: These African Purple Leaves Are 11X More Powerful Than Keto These African Purple Leaves Are 11X More Powerful Than Keto http://wealthmindswitch.world/UACgadnCArqOqgENRj_v3ZYEbNZYESHRWdAmCtOIrTSjkP_vyw http://wealthmindswitch.world/wSgxNEWrPJgfhmCfFKg4l3x6QkSO009v5Nrs8BnUIr2sOQI De Broglie's prediction of a wave nature for electrons led Erwin SchrC6dinger to postulate a wave equation for electrons moving under the influence of the nucleus in the atom. In 1926, this equation, the SchrC6dinger equation, successfully described how electron waves propagated. Rather than yielding a solution that determined the location of an electron over time, this wave equation also could be used to predict the probability of finding an electron near a position, especially a position near where the electron was bound in space, for which the electron wave equations did not change in time. This approach led to a second formulation of quantum mechanics (the first by Heisenberg in 1925), and solutions of SchrC6dinger's equation, like Heisenberg's, provided derivations of the energy states of an electron in a hydrogen atom that were equivalent to those that had been derived first by Bohr in 1913, and that were known to reproduce the hydrogen spectrum. Once spin and the interaction between multiple electrons were describable, quantum mechanics made it possible to predict the configuration of electrons in atoms with atomic numbers greater than hydrogen. In 1928, building on Wolfgang Pauli's work, Paul Dirac produced a model of the electron b the Dirac equation, consistent with relativity theory, by applying relativistic and symmetry considerations to the hamiltonian formulation of the quantum mechanics of the electro-magnetic field. In order to resolve some problems within his relativistic equation, Dirac developed in 1930 a model of the vacuum as an infinite sea of particles with negative energy, later dubbed the Dirac sea. This led him to predict the existence of a positron, the antimatter counterpart of the electron. This particle was discovered in 1932 by Carl Anderson, who proposed calling standard electrons negatrons and using electron as a generic term to describe both the positively and negatively charged variants. In 1947, Willis Lamb, working in collaboration with graduate student Robert Retherford, found that certain quantum states of the hydrogen atom, which should have the same energy, were shifted in relation to each other; the difference came to be called the Lamb shift. About the same time, Polykarp Kusch, working with Henry M. Foley, discovered the magnetic moment of the electron is slightly larger than predicted by Dirac's theory. This small difference was later called anomalous magnetic dipole moment of the electron. This difference was later explained by the theory of quantum electrodynamics, developed by Sin-Itiro Tomonaga, Julian Schwinger and Richard Feynman in the lat ------------------------------ End of alt.music.moxy-fruvous digest V14 #12088 ***********************************************