This topic briefly brings together the observational properties of vertical structures and their contents in preparation for a more detailed discussion in Topic033. Using line width (dispersion) data Topic033 relates E galaxies to vertical structures and redshift-magnitude bands as part of the doubling evolution process of galaxies and their nuclear dipoles. Dipole orientation has marked effects upon observed properties of E galaxies as already discussed in Topic031 with respect to rotation. There is more to come.
The previous topic began a discussion of the role of period doubling, and demonstrated end products (observed redshift distributions) seen within sets of data. How such a process actually appears to proceed from the ‘spatial’ viewpoint is discussed and illustrated in this topic. Many of the redshift, temporal and spatial properties previously discussed are involved. Discussion of boundary aspects of galaxies may explain a new effect. It is possible that transformation activity when space returns to temporal space can generate radiation near the CBR vertexes which is referred to as the zodiacal anomaly.
This Topic begins a discussion of the processes by which galaxies within aggregates of galaxies appear to form and evolve as the universe ages. Previously discussed observed quantized and structural properties beginning with the Hubble Deep Field and the role of period doubling are brought together. As discussion continues important observational tests and evidence in support of the process will be presented.
The previous Topic026 demonstrated the high redshift quantized distribution of ACTIVE quasars and illustrated their period doubling connection to ACTIVE galaxies at lower redshift, which to see REQUIRES transformation to the cosmic rest frame and application of a cosmic correction due to the curvature of 3-d time that have been discussed in Topics010 and 011. I will clarify the corrections further in a later topic which will define the QTC lookback path in time. In this topic the distribution of galaxy redshifts in Hubble deep field studies is used to more fully define the structural nature of redshift quantization. The pattern consists of a doubling series of objects, starting at an ‘absent’ quasar at a basic simple fraction of c, followed by cyclical steps of galaxies in higher doubling fractional steps of c. This is an initial beginning of a temporal wave function energy which then extends in cyclical periodic cycles at the wave function energy between subsequent doubling steps. The QTC model fits real observational data essentially perfectly.
In any expanding evolving cosmology, in continuous or quantum physics, the redshift must change with time. Classically it is very unlikely such change on the human time scale would be detectable. However, redshift variability became obvious as soon as new redshifts obtained between 1984-86 were compared with older surveys done between the 1960s and early 1980s. Redshift changes, much larger than any uncertainties, primarily shifts toward lower values, are present and become increasingly greater the older the past observations are for many galaxies. The redshift can apparently shift in quantum steps in just a few years as it cascades between longer more stable periods. This topic describes the discovery and initial study of the effect.
My third topic discussed crossband substructure within redshift-magnitude band patterns. There are changes in redshift radially in clusters and between redshift patterns within clusters involving galaxy morphology and radio or emission line activity. These changes relate to understanding evolution of aggregates of galaxies and activity and morphology in individual galaxies. Topic004 opens discussion on those subjects.