F’teropod, Void Feather, Ether Sail

[https://i.imgur.com/V9C6OQf.png]

An anatomical feature of most of the Velavita Order. The F’teropod is a highly modified form of reso-material defensive cladding. Although the precise shape and purpose varies greatly across species in Order Velavita.

A distinguishing trait of true F’teropods vs other defensive reso-material tissues is the mobility of the elements and the Ether Interaction.

In broad structure F’teropods have a core shaft which contains the metabolic and particle accelerator mechanisms with branching tines that contain the majority of the Ether Interaction facilitating lattices. The symmetry, number of branches and even the proportion of shaft vs tines vs sub tines is highly variable.

F’teropods Ether Interactions provide all Velavita with a mechanism for momentum and energy transfer into the Ether. This can depending on the species and anatomy of the F’teropod allow for the following: linear acceleration, heat dispersal, impact dissipation, structural support and other rarer applications.

In linear acceleration adaptations F’teropods form many parallel tines aligning their lattice with the orientation of acceleration. At higher ideal energies the tines will be joined to a thicker shaft and the over all dimensions of the F’teropod increases.

For heat dispersal F’teropod structures favor more branches and maximizing total surface area, the dimensions of the tines (especially the thickness) is directly proportionate to the ideal heat dispersal temperature. With thicker tines favoring a higher ideal dispersal temperature.

Impact dissipation adaptations favor overlapping or woven tine structures, this creates radial lattices that bleed off energy in waves out from any given impact point into the ether.

Structural support applications generally resemble a blend of linear acceleration and impact dissipation, however under most conditions these adaptations are optimized at the smallest and lowest energy Ether Interactions which favors a much smaller tine diameter and length compared to other F’teropods.

Taken from Royal Road, this narrative should be reported if found on Amazon.

Vestigial forms in some species may have structural traits but have lost Ether Interaction due to a modified lattice of the reso-material. Mobility can be expressed very broadly across species. With some having become almost completely immobile while others are effectively fluid. The more mobility within a F’teropod the more flexibility it can have with expressing a variety of adaptations and generally a broader efficiency scope they can utilize, however this tends to come at a cost of stability. In the case of Vestigial F’teropods that no longer have Ether Interaction instability is no longer an adaptive consideration and mobility is normally indicative of other selection pressures.

In Velavita the adaptation is believed to have developed Initially as a means of metabolic energy storage. The external protrusion likely to have been an adaptation for isolating reso-material destabilization events as the F’teropods became more energetic. This isolation eventually culminating in a capacity for shedding for many species. Later the material matrix used for energy storage was adapted to exploit the Ether Interaction.

The precise velocities and forces that Ether Interactions occur at highests efficiency are mutually exclusive in a single F’teropod lattice.

For example many Velavita favor lower energy density for more metabolic accessibility to the Ether Interactions. This makes the peak efficiency of their F’teropods significantly lower energies, accelerations and masses.

However other species specialize in interstellar migration and reach peak efficiencies at significant fractions of the speed of light. This however is at the cost of direct metabolic accessibility of the stored energy for any other use beyond locomotion once resources have been diverted and upscaled to such high energies in the F’teropod system. These species also tend to have much more rigid F’teropods as the energies involved make instability catastrophically maladaptive.