Nuclear and Atomic Physics

1806 Submissions

[3] viXra:1806.0425 [pdf] submitted on 2018-06-27 06:21:14

A02 Bohr Model with Victoria Equation 3 Dimensions Orbital and Spin

Authors: Javier Silvestre
Comments: 18 Pages.

Bohr's atomic model presents problems such as loss of energy by rotating charge or absence of explanation for electron probability (electron cloud). Here we show resolution of these problems and optimization of Bohr's model with two electronic extremes that always maintaining initial energy. Electronic extreme behaviour is based on Victoria equation [1]. Debate between the current model and the one based on Bohr with Victoria equation is proposed. In this article, electron begins to show in three dimensions. First, by expanding its radial dimension to two dimensions with a circular orbit movement. Second, reaching three dimensions by raising and lowering these circular orbits with division variations (Swinging movement). In the previous sentence two electron movements have been included: orbital movement with circular movement in specific division and spin movement when moving between orbits changing division with swinging movement like a screw.
Category: Nuclear and Atomic Physics

[2] viXra:1806.0406 [pdf] submitted on 2018-06-27 23:05:41

SRC Model for Nuclear Structure

Authors: Ranjeet Dalal
Comments: 13 Pages.

A new approach for the nuclear structure is suggested which is based upon the idea that the nucleons are not moving independently inside the nuclei, but are forming Short Range Correlated (SRC) quasi-particles. The existence of SRCs inside nuclei has been verified by many experiments [1-3] and is considered to be underlying reason behind the EMC effect [4]. Using few assumptions, a SRC based model for the nuclear structure is proposed. The model is equivalent to the liquid drop model for consideration of the nuclear binding energy and is equivalent to the shell model if the shell structure of SRC quasiparticles is considered. Equivalence of the present model to the cluster model for specific applications is also highlighted. Further, this model provides insights for the symmetric/asymmetric nature of spontaneous fission and Giant Resonances.
Category: Nuclear and Atomic Physics

[1] viXra:1806.0216 [pdf] submitted on 2018-06-19 10:06:24

Magnetic Spin Controlling

Authors: George Rajna
Comments: 32 Pages.

EPFL physicists have found a way to reverse electron spins using electric fields for the first time, paving the way for programmable spintronics technologies. [19] Manipulating light in a variety of ways—shrinking its wavelength and allowing it to travel freely in one direction while stopping it cold in another—hyperbolic metamaterials have wide application in optical communications and as nanoparticle sensors. [18] A new way of enhancing the interactions between light and matter, developed by researchers at MIT and Israel's Technion, could someday lead to more efficient solar cells that collect a wider range of light wavelengths, and new kinds of lasers and light-emitting diodes (LEDs) that could have fully tunable color emissions. [17] A team of researchers at the Center for Relativistic Laser Science, within the Institute for Basic Science (IBS) have developed a method to measure the shape of laser pulses in ambient air. [16] Studying the fleeting actions of electrons in organic materials will now be much easier, thanks to a new method for generating fast X-rays. [15] In a laboratory at the University of Rochester, researchers are using lasers to change the surface of metals in incredible ways, such as making them super water-repellent without the use of special coatings, paints, or solvents. [14] The interaction of high-power laser light sources with matter has given rise to numerous applications including; fast ion acceleration; intense X-ray, gamma-ray, positron and neutron generation; and fast-ignition-based laser fusion. [13] Conventional electron accelerators have become an indispensable tool in modern research. [12] An outstanding conundrum on what happens to the laser energy after beams are fired into plasma has been solved in newly-published research at the University of Strathclyde. [11] Researchers at Lund University and Louisiana State University have developed a tool that makes it possible to control extreme UV light-light with much shorter wavelengths than visible light. [10]
Category: Nuclear and Atomic Physics