This time we are looking on the crossword puzzle clue for: Moon goddess.
it’s A 12 letters crossword definition.
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Last seen on: –NY Times Crossword 28 Apr 21, Wednesday
–NY Times Crossword 18 Aug 20, Tuesday
–NY Times Crossword 19 May 20, Tuesday
–The Washington Post Crossword – Apr 30 2020
–LA Times Crossword 30 Apr 20, Thursday
Universal Crossword – Apr 8 2020
Random information on the term “Moon goddess”:
Changxi (Chinese: 常羲) is a Chinese lunar goddess worshiped in the traditional Chinese pantheon. Known from ancient times, the earliest historical information on Changxi can be traced back to the Classic of Mountains and Seas (Shan-hai Ching). She is the wife of Di Jun and the mother of twelve moons.
The earliest known mention of Changxi is made in the mythic text The Canon of the Mountains and Seas, romanised as Shan-hai Ching. A single line in it reads: “The Emperor Jun married Changxi, who gave birth to twelve Moons.”
The God of the Eastern Sky Di Jun had three wives, including Changxi, who was regarded as his first wife Xihe’s western counterpart; while Xihe gave birth to suns, Changxi bore twelve unique moon daughters that would complete a full journey across the heavens every day. She bathed her children in a water pool. Described as an “important early goddess”, her significance amongst the deities gradually waned and she was eventually “demoted to a minor position”.
Random information on the term “SELENE”:
A gamma-ray spectrometer (GRS) is an instrument for measuring the distribution (or spectrum—see figure) of the intensity of gamma radiation versus the energy of each photon.The study and analysis of gamma-ray spectra for scientific and technical use is called gamma spectroscopy, and gamma-ray spectrometers are the instruments which observe and collect such data.Because the energy of each photon of EM radiation is proportional to its frequency, gamma rays have sufficient energy that they are typically observed by counting individual photons.
Atomic nuclei have an energy-level structure somewhat analogous to the energy levels of atoms, so that they may emit (or absorb) photons of particular energies, much as atoms do, but at energies that are thousands to millions of times higher than those typically studied in optical spectroscopy.(Note that the short-wavelength high-energy end, of the atomic spectroscopy energy range (few eV to few hundred keV), generally termed X rays, overlaps somewhat with the low end of the nuclear gamma-ray range (~10 MeV to ~10 keV) so that the terminology used to distinguish X rays from gamma rays can be arbitrary or ambiguous in the overlap region.)As with atoms, the particular energy levels of nuclei are characteristic of each species, so that the photon energies of the gamma rays emitted, which correspond to the energy differences of the nuclei, can be used to identify particular elements and isotopes.Distinguishing between gamma-rays of slightly different energy is an important consideration in the analysis of complex spectra, and the ability of a GRS to do so is characterized by the instrument’s spectral resolution, or the accuracy with which the energy of each photon is measured.Semi-conductor detectors, based on cooled germanium or silicon detecting elements, have been invaluable for such applications.Because the energy level spectrum of nuclei typically dies out above about 10 MeV, gamma-ray instruments looking to still higher energies generally observe only continuum spectra, so that the moderate spectral resolution of scintillation (often sodium iodide (NaI) or caesium iodide, (CsI) spectrometers), often suffices for such applications.