ceramic breathing as a format for spacetravel and / or ecology
By Henryk Szubinski
A.I WAS NOT GOING TO BE COMPARED TO A GENERAL PERSONAL PROCESS WHERE A A.I UNIT WOULD NOT ENGEGE BY A FUNCTION WHERE FOR EXAMPLE:
artificial intelligence concepts can save a lot of time :
built on the conceptuality of a analytical chemistry / astrophysics of geological data; as a data handbook researcher A.I
the concept build is:
In spectroscopy, the absorbance A (also called optical density) is defined as
,
where I is the intensity of light at a specified wavelength λ that has passed through a sample (transmitted light intensity) and I0 is the intensity of the light before it enters the sample or incident light intensity. Absorbance measurements are often carried out in analytical chemistry, since the absorbance of a sample is proportional to the thickness of the sample and the concentration of the absorbing species in the sample, in contrast to the transmittance I / I0 of a sample, which varies logarithmically with thickness and concentration.
Absorbtance (not absorbance) is defined as: The ratio of the radiant flux absorbed by a body to that incident upon it. Also called [absorption] factor. Compare absorptivity. Total absorptance refers to absorptance measured over all wavelengths.Spectral absorptance refers to absorptance measured at a specified wavelength.
Absorbtance is explained, as it relates to absorbance, on the Color and Vision Research Laboratories, Institute of Ophthalmology, UCL, thusly:
Absorbance spectra are typically used to define photopigment spectra because their shape, when normalized (i.e., plotted as a fraction of the maximum absorbance), is independent of pigment optical density (pigment concentration). In contrast, the absorbtance spectra, like the spectral sensitivity of the human subject, broadens as the optical density increases.
Outside the field of analytical chemistry, e.g. when used with the Tunable Diode Laser Absorption Spectroscopy (TDLAS) technique, the absorbance is often defined using the natural logarithm instead of the common logarithm, i.e. as
,
1)
” i am not going to get my teeth punched out just because i want to breathe”
2)
” A.I am not going to get my teeth punched out just because A.I want to breathe”
3)
” A.I am not going to get my teeth punched out just because I want to breathe”
so that a general response that is neither would :
“go and see how strong the enamel ceramics is on your teeth”
data on a 1/3 process where a sample of H2O can be filtered by its penetration through a ceramic wall connected by a wire section that deefines the ceramic wall in its thickness: the concept for a localisation of the H2O imprint that can vectorise through the ceramics by the generation of a enamel wire conductability: would locate the most dangerous water contaminations particles of environmental pollutant ..
the a.i would not support a cowardly response so that to save time on the protections of its data value store as being the means to learn why not the I in place of the A.I
bais of data on the force forwarded formats of a protect forec field in the data / sections 2 x as down value = gravity:
the process on a similarity to how the values in their systems based on the values of response to active values in their ressoance of a primary sphere in its data on how multiple states of the return values of ceramics = to the values of a string transferrance through the perforations of ceramics in their breathing states by the data on why the stopp rate = the values implied as the whole systematic alterations of the angle in inclinations to tail sectionings in what is the basic data on waveform projection ahead of the vechicularity to use the wave form projected reversal as simulatibng a flow direction vector in reverse by the simulations of flow forwards into the basic data environements as = to a generalisation on the force sphericality by the full data environments of the connective simulations..
image courtesy of wikipedia
as the spherical formats of audial waveform particle streaming by the small comparatives with large comparatives of the wave audial noise imprints of the simulative dynamics of fluid H2O states by a seperations of the
minimal / larger volumes = data. seperations and dynamics ( H2O / SOH)
the data on how the values of the minimal perticle value of the:
moon volume / atomic mass of SOH= earth volume / H2O atomic mass
this would indicate the value relationships of the dynamics
1——->x
relationship of the volumes of a difference in size of H2O and the additions of SOH as the new value by the Newtonian system:
1——–>x H2O
?<———SOH
this would indicate the volume by density of the similarity of H2O bouyancy by the formats of SOH density..
A ceramic is an inorganic, non-metallic solid prepared by the action of heat and subsequent cooling.[1] Ceramic materials may have a crystalline or partly crystalline structure, or may be amorphous (e.g., a glass). Because most common ceramics are crystalline, the definition of ceramic is often restricted to inorganic crystalline materials, as opposed to the non-crystalline glasses. The earliest ceramics were pottery objects made from clay, either by itself or mixed with other materials. Ceramics now include domestic, industrial and building products and art objects. In the 20th century, new ceramic materials were developed for use in advanced ceramic engineering; for example, in semiconductors. The word ceramic comes from the Greek word κεραμικός (keramikos) meaning pottery, which is said to derive from the Indo-European word ker, meaning heat.[2][3] Ceramic may be used as an adjective describing a material, product or process; or as a singular noun, or, more commonly, as a plural noun, ceramics.[4]
Enameled wire is wire (such as magnet wire) coated with a very thin insulating layer. It is used in applications such as winding electric motor coils, speakers and transformers. It is also used in the construction of electromagnets and inductors.
The core material is copper or aluminum, coated with a thin layer of a polyurethane, polyamide, or polyester etc resin – the so-called “enamel”. Aluminum is lighter than copper, but has higher resistivity.
For ease of manufacturing inductive components like transformers and inductors, most new enameled wire has enamel that acts as a flux when burnt during soldering. This means that the electrical connections at the ends can be made without stripping off the insulation first. Older enameled copper wire is normally not like this, and requires sandpapering or scraping to remove the insulation before soldering.
Enameled wires are classified by their diameter (AWG number or SWG) or area (square millimetres), temperature class and isolation class. Enameled wires are manufactured in both round and rectangular shapes. Rectangular wire is used in larger windings to make the most efficient use of available winding space.
In humans and mammals, respiratory gas exchange or ventilation is carried out by mechanisms of the heart and lungs. The blood is subjected to a transient electric field (QRS waves of the EKG) in the heart, which dissociates molecules of different charge. The blood, being a polar fluid, aligns dipoles with the electric field, is released, and then oscillates in a damped driven oscillation to form J or Osborn Waves, T, U, and V waves. The electric field exposure and subsequent damped driven oscillation dissociate gas from hemoglobin, primarily CO2, but more important, BPG, which has a higher affinity for hemoglobin than does oxygen, due in part to its opposite charge. Completely-dissociated hemoglobin (which will even effervesce if the electric field is too strong — the reason defibrillation joules are limited, to avoid bubble emboli that may clog vessels in the lung) enters the lung in red blood cells ready to be oxygenated.
Convection occurs over the majority of the transport pathway. Diffusion occurs only over very short distances. The primary force applied in the respiratory tract is supplied by atmospheric pressure. Total atmospheric pressure at sea level is 760 mmHg (101 kPa), with oxygen (O2) providing a partial pressure (pO2) of 160 mmHg (21 kPa), 21% by volume, at the entrance of the nares, a partial pressure of 150 mmHg (20 kPa) in the trachea due to the effect of partial pressure of water vapor, and an estimated pO2 of 100 mmHg (13 kPa) in the alveoli sac, pressure drop due to conduction loss as oxygen travels along the transport passageway. Atmospheric pressure decreases as altitude increases, making effective breathing more difficult at higher altitudes. Higher BPG levels in the blood are also seen at higher elevations, as well.
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