We have proposed, thanks to a new model of the hydrogen atom [1], some explanation of the lines observed by Lyman in the spectrographic analysis of this atom. The model is based on a prequantum physics, itself founded...We have proposed, thanks to a new model of the hydrogen atom [1], some explanation of the lines observed by Lyman in the spectrographic analysis of this atom. The model is based on a prequantum physics, itself founded on classical mechanics completed by the existence of a universal cloud of tiny particles called U. This cloud induces simultaneously and similarly electromagnetic and gravitational effects. This common origin creates a narrow link between how planets are arranged in a solar system, say the Titus-Bode law, and how the electrons are arranged in an atom, say the lines of Lyman. We describe what this link is in the following text and, more generally, what is the preferred orbit of an isolated celestial body.展开更多
The large-scale structure of DM cannot be directly seen, but it is believed it can be inferred from the distribution of visible galaxies formed from ordinary matter. Bright visible galaxies that emit the Lyman <i&...The large-scale structure of DM cannot be directly seen, but it is believed it can be inferred from the distribution of visible galaxies formed from ordinary matter. Bright visible galaxies that emit the Lyman <i>α</i> (Ly<i>α</i>) emission line of the hydrogen atom (Ly<i>α</i> galaxies) are used to observe the large-scale structure of distant space. However, recently Momose <i>et al</i>. have reported cases where the large-scale structures of DM indicated by Ly<i>α</i> galaxies and other galaxies fail to match. This raises the possibility that Ly<i>α</i> galaxies may not correctly indicate the large-scale structure of DM. In the currently accepted cold DM model, DM and neutral hydrogen gas are thought to interact only through the mutual effects of gravity. However, according to Suto, DM and ordinary matter are like two sides of the same coin. By giving and receiving approximately 2<i>m</i><sub>e</sub><i>c</i><sup>2</sup> (1.022 MeV), it is possible to mutually convert between the two. If, in future observations of the density distribution of interstellar gas using Ly<i>α</i> emission lines, unexpected data is obtained that cannot be explained based only on absorption by neutral hydrogen gas, then the author believes the problem can be solved with Suto’s DM model.展开更多
文摘We have proposed, thanks to a new model of the hydrogen atom [1], some explanation of the lines observed by Lyman in the spectrographic analysis of this atom. The model is based on a prequantum physics, itself founded on classical mechanics completed by the existence of a universal cloud of tiny particles called U. This cloud induces simultaneously and similarly electromagnetic and gravitational effects. This common origin creates a narrow link between how planets are arranged in a solar system, say the Titus-Bode law, and how the electrons are arranged in an atom, say the lines of Lyman. We describe what this link is in the following text and, more generally, what is the preferred orbit of an isolated celestial body.
文摘The large-scale structure of DM cannot be directly seen, but it is believed it can be inferred from the distribution of visible galaxies formed from ordinary matter. Bright visible galaxies that emit the Lyman <i>α</i> (Ly<i>α</i>) emission line of the hydrogen atom (Ly<i>α</i> galaxies) are used to observe the large-scale structure of distant space. However, recently Momose <i>et al</i>. have reported cases where the large-scale structures of DM indicated by Ly<i>α</i> galaxies and other galaxies fail to match. This raises the possibility that Ly<i>α</i> galaxies may not correctly indicate the large-scale structure of DM. In the currently accepted cold DM model, DM and neutral hydrogen gas are thought to interact only through the mutual effects of gravity. However, according to Suto, DM and ordinary matter are like two sides of the same coin. By giving and receiving approximately 2<i>m</i><sub>e</sub><i>c</i><sup>2</sup> (1.022 MeV), it is possible to mutually convert between the two. If, in future observations of the density distribution of interstellar gas using Ly<i>α</i> emission lines, unexpected data is obtained that cannot be explained based only on absorption by neutral hydrogen gas, then the author believes the problem can be solved with Suto’s DM model.
