Kepler-Centauri Star System: Difference between revisions

From Solas Tempus DB
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|loc=[[Bellatrix Antares Sector]]
|loc=[[Bellatrix Antares Sector]]
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There are 3 plants in this system detected by long range probe.
This system was explored by the [[USS Continuum (NCC-2895-C)]] in 2389 related to an anomalous signal that was detected from the 3rd planet, Iris. The system has 3 planets total.
 
== Anomalous Signal ==
During routine sensor sweep of the Kepler-Centauri system, ST-SD-47 detected a brief distortion in space-time consistent with a potential warp signature. The signature originated near the third planet, designated Iris. Immediately following this event, a complex, repeating signal of unknown origin was detected emanating from the same region.
 
Most concerning, a massive energy spike was recorded concurrent with the warp signature. The nature of this energy spike remains unknown, but its intensity and proximity to the other anomalies warrant further investigation. Preliminary analysis suggests the energy spike could be related to the warp signature, but this cannot be confirmed at this time.


== Kythera ==
== Kythera ==
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{{Planet Data
{{Planet Data
|class=A
|class=A
|distance=0.08 AU
|distance=0.09 AU
|period=8 days 8 hours and 7 minutes
|period=8 days 8 hours and 7 minutes
|radius=4174.2 km
|radius=4174.2 km
|gravity=0.58 G
|gravity=0.58 G
}}
}}
Atmospheric Conditions are an average of 11.3 kPa or 0.1 atmospheres and an average surface temperature of -128.1 degrees C.
Eos, a Class A planet in the Kepler-Centauri system, presents an intriguing anomaly. Despite a thin atmosphere, primarily composed of sulfur dioxide and carbon dioxide, with an average pressure of 11.3 kPa (0.1 atmospheres) and a frigid surface temperature averaging -128.1 degrees Celsius, the planet's geological composition is unexpectedly complex. The barren, volcanic rock surface, scarred by craters and fissures, reveals traces of rare earth elements like hafnium, ytterbium, and lutetium, alongside heavier transuranic elements such as americium and curium.
Atmosphere contains largely Sulfur dioxide, carbon dioxide
 
Planet is composed of mostly Igneous silica, basalt
The planet's core, rich in radioactive isotopes, generates significant internal heat, yet ionizing radiation levels remain surprisingly low. This heat drives a rapid rotation of the core, completing a full cycle every 5.2 seconds. The resulting powerful magnetic field, with its irregularly flipping poles, induces strong eddy currents in the liquid metal mantle. These currents interact with a unique crystalline alloy, designated Alloy U1, found in the planet's fissures.
 
Alloy U1, a complex lattice of carbon and silicon interwoven with an unidentified metal, displays exceptional ferromagnetism and thermal conductivity. This alloy effectively channels and dissipates the intense heat generated by the planet's electromagnetic activity, preventing the surface from melting despite the immense energy levels. The molten lead observed on the surface and within fissures likely contributes to this heat dissipation process.
 
Exploration of the fissures has also revealed the presence of complex organic molecules, resembling a biofilm, though definitive signs of life remain elusive. The combination of unusual geological features, unique material properties, and potential biological precursors makes Eos a compelling target for further scientific investigation.
 


== Iris ==
== Iris ==
{{Planet Data
{{Planet Data
|class=C
|class=C
|distance=0.085 AU
|distance=0.11 AU
|period=9 days 2 hours and 58 minutes
|period=9 days 2 hours and 58 minutes
|radius=2666.9 km
|radius=2666.9 km
|gravity=0.37 G
|gravity=0.37 G
}}
}}
There is no atmosphere and the surface has an average temperature of -145.9 degrees C.
Iris is a small, barren world with a surface scarred by craters and fissures. The planet lacks an atmosphere and experiences extremely cold temperatures, averaging -145.9 degrees Celsius. Its composition is primarily anthracite, basalt, and hydrocarbons, with an unexpected presence of an unidentified metallic element. The planet is denser than typical for its class and exhibits no geological activity, including a cold, solid core.
Planet is mostly composed of Anthracite, basalt, hydrocarbons
 
Recent long-range scans and probe data have revealed several anomalies originating from Iris. These include a complex, repeating signal with erratic modulation and multiple polarizations, as well as a massive energy spike indicative of exotic particle release. The signal's characteristics suggest a biological or biotechnological origin, possibly carrying multiple layers of information or multiple carriers. Additionally, a strong bio-electric signature concentrated deep beneath the surface points to the presence of organic lifeforms.
 
A faint, asymmetrical warp signature detected near the planet indicates a decentralized field generation system, unlike any known warp technology. These anomalies have led to the hypothesis of a technologically advanced subterranean civilization inhabiting Iris, potentially composed of a previously unknown species.
 
=== Inhabitants ===
The subterranean species inhabiting Iris is a non-humanoid life form with a unique, modular body structure. It is composed of individual cells that can separate and re-form, allowing for a high degree of flexibility and adaptability. The cells are interconnected through a complex network of chemical signals, electrical impulses, and possibly even telepathic communication, forming a collective consciousness with distributed intelligence and shared memory.
 
The species exhibits a remarkable ability to adapt to its environment, navigating through complex cave systems and surviving in the harsh conditions of Iris's subsurface. The energy spike detected during previous scans may be related to a biological process or the use of advanced technology. The complexity of the signal emanating from the planet suggests a sophisticated communication system and potentially advanced cognitive abilities.
 
The warp signature detected near Iris suggests that the subterranean species possesses advanced technology, including a unique form of [[Warp Drive|warp drive]] that generates a decentralized field. This technology differs significantly from known [[Federation]] or [[Solas Tempus]] designs. The nature and extent of their technological capabilities remain unknown.


[[Category:Star Systems]]
[[Category:Star Systems]]
[[Category:Bellatrix Antares Sector]]
[[Category:Bellatrix Antares Sector]]

Latest revision as of 23:56, 17 July 2024

Type: M1D Red Dwarf Star
Radius: 36767.18 km
Mass: 2.09 x 1029 kg
Temperature: 3500 K
Luminosity: 1.45 x 1023 W
Ecosphere:Between 0.02 and 0.03 AU
Location: Bellatrix Antares Sector

This system was explored by the USS Continuum (NCC-2895-C) in 2389 related to an anomalous signal that was detected from the 3rd planet, Iris. The system has 3 planets total.

Kythera

Class: J
Distance: 0.076 AU
Period: 7 days 14 hours and 54 minutes
Radius: 160404.2 km
Gravity: 2.77 G

Atmospheric Conditions are an average of 41.3 kPa or 0.4 atmospheres and an average temperature of -65.1 degrees C. Primarily composed of Hydrogen, helium.

Eos

Class: A
Distance: 0.09 AU
Period: 8 days 8 hours and 7 minutes
Radius: 4174.2 km
Gravity: 0.58 G

Eos, a Class A planet in the Kepler-Centauri system, presents an intriguing anomaly. Despite a thin atmosphere, primarily composed of sulfur dioxide and carbon dioxide, with an average pressure of 11.3 kPa (0.1 atmospheres) and a frigid surface temperature averaging -128.1 degrees Celsius, the planet's geological composition is unexpectedly complex. The barren, volcanic rock surface, scarred by craters and fissures, reveals traces of rare earth elements like hafnium, ytterbium, and lutetium, alongside heavier transuranic elements such as americium and curium.

The planet's core, rich in radioactive isotopes, generates significant internal heat, yet ionizing radiation levels remain surprisingly low. This heat drives a rapid rotation of the core, completing a full cycle every 5.2 seconds. The resulting powerful magnetic field, with its irregularly flipping poles, induces strong eddy currents in the liquid metal mantle. These currents interact with a unique crystalline alloy, designated Alloy U1, found in the planet's fissures.

Alloy U1, a complex lattice of carbon and silicon interwoven with an unidentified metal, displays exceptional ferromagnetism and thermal conductivity. This alloy effectively channels and dissipates the intense heat generated by the planet's electromagnetic activity, preventing the surface from melting despite the immense energy levels. The molten lead observed on the surface and within fissures likely contributes to this heat dissipation process.

Exploration of the fissures has also revealed the presence of complex organic molecules, resembling a biofilm, though definitive signs of life remain elusive. The combination of unusual geological features, unique material properties, and potential biological precursors makes Eos a compelling target for further scientific investigation.


Iris

Class: C
Distance: 0.11 AU
Period: 9 days 2 hours and 58 minutes
Radius: 2666.9 km
Gravity: 0.37 G

Iris is a small, barren world with a surface scarred by craters and fissures. The planet lacks an atmosphere and experiences extremely cold temperatures, averaging -145.9 degrees Celsius. Its composition is primarily anthracite, basalt, and hydrocarbons, with an unexpected presence of an unidentified metallic element. The planet is denser than typical for its class and exhibits no geological activity, including a cold, solid core.

Recent long-range scans and probe data have revealed several anomalies originating from Iris. These include a complex, repeating signal with erratic modulation and multiple polarizations, as well as a massive energy spike indicative of exotic particle release. The signal's characteristics suggest a biological or biotechnological origin, possibly carrying multiple layers of information or multiple carriers. Additionally, a strong bio-electric signature concentrated deep beneath the surface points to the presence of organic lifeforms.

A faint, asymmetrical warp signature detected near the planet indicates a decentralized field generation system, unlike any known warp technology. These anomalies have led to the hypothesis of a technologically advanced subterranean civilization inhabiting Iris, potentially composed of a previously unknown species.

Inhabitants

The subterranean species inhabiting Iris is a non-humanoid life form with a unique, modular body structure. It is composed of individual cells that can separate and re-form, allowing for a high degree of flexibility and adaptability. The cells are interconnected through a complex network of chemical signals, electrical impulses, and possibly even telepathic communication, forming a collective consciousness with distributed intelligence and shared memory.

The species exhibits a remarkable ability to adapt to its environment, navigating through complex cave systems and surviving in the harsh conditions of Iris's subsurface. The energy spike detected during previous scans may be related to a biological process or the use of advanced technology. The complexity of the signal emanating from the planet suggests a sophisticated communication system and potentially advanced cognitive abilities.

The warp signature detected near Iris suggests that the subterranean species possesses advanced technology, including a unique form of warp drive that generates a decentralized field. This technology differs significantly from known Federation or Solas Tempus designs. The nature and extent of their technological capabilities remain unknown.