Posted by: SevenOfCarina
« on: April 18, 2020, 01:18:46 AM »Transphasic Materials
Retrieved : 01 January 2021
Transphasic materials are a type of naturally-occurring exotic matter, consisting of a core of weakly interacting massive particles (alternatively, dark matter or wimpy matter) trapped inside a baryonic crystal lattice by the weak nuclear force. First isolated on 13 December 2008 by an international team of researchers in Perth, Australia, the existence of transphasic matter had been theorised since the discovery of the Thornton-Nasser effect at the University of Western Australia by the research team of Emily Thornton and Omar Nasser in February 2008.
Dark matter in the free state is ubiquitous in the universe, but, owing to its unique lack of chemistry and the fact that it interacts with baryonic matter exclusively through the graviweak force, its exact nature was not conclusively identified till late 2009. While non-baryonic matter outmasses baryonic matter 3 :1, it has a tendency to clump around celestial bodies of sufficient mass forming long 'strands' that are arranged radially outward, typically beginning at some distance from the surface and extending outward several thousand or even millions of kilometre and kept in place by graviweak forces.
While the exact process of formation of tranphasic matter remains elusive, it is wildly theorised to be a result of strands of wimpy matter being perturbed into intersecting a mass of baryonic matter of specific composition and characteristics, resulting in dark matter particles forming transphasic crystal structures. The perturbation is generally gravitic and induced by large stellar masses - transphasic materials are theorised to be abundant in small solar system bodies in eccentric orbits and can be quantitatively and qualitatively estimated with the aid of highly sensitive gravimetric sensors using the Kumar-Tanaka-Mankowski technique.
Exposure to near vacuum results in transphasic materials undergoing rapid decay with the disassociation of wimpy matter and baryonic particles, requiring a complex series of processes to stabilise them. They tend to occur at depths exceeding ten kilometres due to the specificity of the formation process. Due to their exceedingly high densities, transphasic materials sink rapidly into the mantle and cores of large planetary bodies, rendering their extraction difficult and cumbersome. Nevertheless, their unique properties underpin modern technology and industry, with wide-ranging applications.
There are eleven distinct types of tranphasic materials that have been identified as of 1 January 2021, and these are classified as monowimpy, tetrawimpy and polywimpy based on the number of dark matter particles trapped in each crystal unit. They are listed below in order of discovery.
Duranium
Duraniums were the first type of transphasic materials to be isolated in December 2008 and are generally monowimpy complexes of iron and related transition metals. They are relatively easy to stabilise and manipulate, and enhance the strength and durability of an array of common alloys when used as an additive. Duraniums are widely used in industrial activities and are a principal construction material in spaceborne applications. Duraniums are the most abundant transphasic material, with twenty-three distinct types known.
Mercasssium
Mercassiums were first isolated in February 2009, and are monowimpy complexes of lanthanides displaying esoteric catalytic activities. They are used primarily in high-precision instruments and laboratory facilities, with seventeen mercassiums known.
Sorium
Soriums were first isolated in March 2009, and are monowimpy complexes of carbon-based volatiles. The Sage-Kampfer process is used to break down the large scale structure of soriums in refineries to produce starship fuel. They are the only known transphasic material that can survive in near vacuum condition; seven soriums are known.
Gallicite
Gallicites were first isolated in April 2009 and the first identified transphasic materials with more than one dark matter particle per crystal unit. They are tetrawimpy complexes of noble metals. Gallicites are used principally in distortion engines, with nine types known.
Corundium
Corundiums were first isolated in April 2010 and greatly enhanced the rate of extraction of transphasic materials. They are monowimpy complexes of rare earth elements with twelve known types. Corundiums are essential in the extraction of transphasic materials and play an important role in the stabilisation process.
Tritanium
Tritaniums were first isolated in May 2010 and are monowimpy complexes of alkalis, with only two known types. They are extremely unstable and can be induced to rupture explosively, generating focused streams of high energy particles.
Boronide
Boronides were first isolated in May 2010 and are polywimpy complexes of boron group elements. They have a highly complex structure and have the most massive crystal unit of all known transphasic materials. Boronides are used extensively as fusion catalysts, with three types known.
Vendarite
Vendarites were first isolated in May 2010 and are tetrawimpy complexes of tungsten and related heavy transition metals. They are lightweight for transphasic materials and extremely strong, with fifteen known types. Vendarites are used widely in aerospace applications and in high performance machinery.
Uridium
Uridiums were first isolated in June 2010 and are monowimpy complexes of carbon group elements, principally silicon. They are extensively used in computational architecture and in gravitimetric communication systems and sensors, with fourteen types known.
Corbomite
Corbomites were first isolated in July 2010 and are tetrawimpy complexes of rare earth elements, with seventeen known types. They are notable for the Corbomite Barrier Effect but have limited industrial use.
Neutronium
Neutroniums were first isolated in September 2010 and are monowimpy complexes of carbon with a diamondoid structure. They are extremely hard and hyperdense, and are used in industrial lathes. Five neutroniums are known.
Retrieved : 01 January 2021
Transphasic materials are a type of naturally-occurring exotic matter, consisting of a core of weakly interacting massive particles (alternatively, dark matter or wimpy matter) trapped inside a baryonic crystal lattice by the weak nuclear force. First isolated on 13 December 2008 by an international team of researchers in Perth, Australia, the existence of transphasic matter had been theorised since the discovery of the Thornton-Nasser effect at the University of Western Australia by the research team of Emily Thornton and Omar Nasser in February 2008.
Dark matter in the free state is ubiquitous in the universe, but, owing to its unique lack of chemistry and the fact that it interacts with baryonic matter exclusively through the graviweak force, its exact nature was not conclusively identified till late 2009. While non-baryonic matter outmasses baryonic matter 3 :1, it has a tendency to clump around celestial bodies of sufficient mass forming long 'strands' that are arranged radially outward, typically beginning at some distance from the surface and extending outward several thousand or even millions of kilometre and kept in place by graviweak forces.
While the exact process of formation of tranphasic matter remains elusive, it is wildly theorised to be a result of strands of wimpy matter being perturbed into intersecting a mass of baryonic matter of specific composition and characteristics, resulting in dark matter particles forming transphasic crystal structures. The perturbation is generally gravitic and induced by large stellar masses - transphasic materials are theorised to be abundant in small solar system bodies in eccentric orbits and can be quantitatively and qualitatively estimated with the aid of highly sensitive gravimetric sensors using the Kumar-Tanaka-Mankowski technique.
Exposure to near vacuum results in transphasic materials undergoing rapid decay with the disassociation of wimpy matter and baryonic particles, requiring a complex series of processes to stabilise them. They tend to occur at depths exceeding ten kilometres due to the specificity of the formation process. Due to their exceedingly high densities, transphasic materials sink rapidly into the mantle and cores of large planetary bodies, rendering their extraction difficult and cumbersome. Nevertheless, their unique properties underpin modern technology and industry, with wide-ranging applications.
There are eleven distinct types of tranphasic materials that have been identified as of 1 January 2021, and these are classified as monowimpy, tetrawimpy and polywimpy based on the number of dark matter particles trapped in each crystal unit. They are listed below in order of discovery.
Duranium
Duraniums were the first type of transphasic materials to be isolated in December 2008 and are generally monowimpy complexes of iron and related transition metals. They are relatively easy to stabilise and manipulate, and enhance the strength and durability of an array of common alloys when used as an additive. Duraniums are widely used in industrial activities and are a principal construction material in spaceborne applications. Duraniums are the most abundant transphasic material, with twenty-three distinct types known.
Mercasssium
Mercassiums were first isolated in February 2009, and are monowimpy complexes of lanthanides displaying esoteric catalytic activities. They are used primarily in high-precision instruments and laboratory facilities, with seventeen mercassiums known.
Sorium
Soriums were first isolated in March 2009, and are monowimpy complexes of carbon-based volatiles. The Sage-Kampfer process is used to break down the large scale structure of soriums in refineries to produce starship fuel. They are the only known transphasic material that can survive in near vacuum condition; seven soriums are known.
Gallicite
Gallicites were first isolated in April 2009 and the first identified transphasic materials with more than one dark matter particle per crystal unit. They are tetrawimpy complexes of noble metals. Gallicites are used principally in distortion engines, with nine types known.
Corundium
Corundiums were first isolated in April 2010 and greatly enhanced the rate of extraction of transphasic materials. They are monowimpy complexes of rare earth elements with twelve known types. Corundiums are essential in the extraction of transphasic materials and play an important role in the stabilisation process.
Tritanium
Tritaniums were first isolated in May 2010 and are monowimpy complexes of alkalis, with only two known types. They are extremely unstable and can be induced to rupture explosively, generating focused streams of high energy particles.
Boronide
Boronides were first isolated in May 2010 and are polywimpy complexes of boron group elements. They have a highly complex structure and have the most massive crystal unit of all known transphasic materials. Boronides are used extensively as fusion catalysts, with three types known.
Vendarite
Vendarites were first isolated in May 2010 and are tetrawimpy complexes of tungsten and related heavy transition metals. They are lightweight for transphasic materials and extremely strong, with fifteen known types. Vendarites are used widely in aerospace applications and in high performance machinery.
Uridium
Uridiums were first isolated in June 2010 and are monowimpy complexes of carbon group elements, principally silicon. They are extensively used in computational architecture and in gravitimetric communication systems and sensors, with fourteen types known.
Corbomite
Corbomites were first isolated in July 2010 and are tetrawimpy complexes of rare earth elements, with seventeen known types. They are notable for the Corbomite Barrier Effect but have limited industrial use.
Neutronium
Neutroniums were first isolated in September 2010 and are monowimpy complexes of carbon with a diamondoid structure. They are extremely hard and hyperdense, and are used in industrial lathes. Five neutroniums are known.