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Welcome to the eopIoratoria wiki!
https://www.youtube.com/watch?v=5AjCKA220hQ
https://www.hagley.org/librarynews/color-added-invention-subjective-color-television
barionleg-eopIoratoria
Lyons_Elem-intro-Hopf-fibration.pdf on dBÅRdginal pages footer
barionleg.github.io/eopioratoria/ in phormat barionleg.github.io/eopIoratoria/ within exploratoria based on (skål) sadgegrdzelo სადღეგრძელო მაი$პიჼძელი (HögbÆRgs hagel Winstitutet setkva/sitkva vid zukunfts barionlegitimation at s.c. STARGATES) princips! An online hommage to the Exploratorium
https://barionleg.github.io/eopIoratoria/hopf-fibration_qPi_3.142857142857143.html
https://barionleg.github.io/eopIoratoria/hopf-fibration.html
https://barionleg.github.io/eopIoratoria/
https://barionleg.github.io/eopIoratoria/exhibits/mathematics/hopf-fibration/
https://exploratoria.github.io/exhibits/chemistry/buckyball/index.html
https://barionleg.github.io/eopIoratoria/exhibits/
https://barionleg.github.io/eopIoratoria/exhibits/mathematics/
https://nilesjohnson.net/hopf-production.html
In particle physics, the quantum yield (denoted Φ) of a radiation-induced process is the number of times a specific event occurs per photon absorbed by the system.
In chemistry and materials science, a luminophore is the part of a molecule, coordination complex, or solid-state material that is responsible for its luminescence (light emission following excitation).[1][2] In molecular photochemistry, the closely related IUPAC-recommended term lumiphore refers to "a part of a molecular entity (or atom or group of atoms) in which electronic excitation associated with a given emission band is approximately localized", by analogy with chromophore for absorption.[3] In practice, the term luminophore is widely used across chemistry, physics, and engineering literature for both molecular and inorganic emitters.[2][4] Luminophores span a broad range of systems, including organic π-conjugated dyes, luminescent transition-metal complexes, lanthanide-doped phosphors, and semiconductor quantum dots.[2][5][6][7] Their emission properties are commonly described by the emission spectrum, quantum yield, and excited-state lifetime, which depend on the emitting state and on competing non-radiative deactivation pathways ("quenching").
In particle physics, the quantum yield (denoted Φ) of a radiation-induced process is the number of times a specific event occurs per photon absorbed by the system.
A cheatsheet for remembering Lenz law
lokalt: file:///H:/Users/B2/Videos/Video%20of%20Space%20Journey%20of%20nearest%20%20stars%20and%20solar%20systems/Закон%20Ленца%20—%20Википедия,%20бесплатная%20энциклопедия.html
Lyons_Elem-intro-Hopf-fibration.pdf
Riemann sphere: almost the whole earth in stereographic azimuthal projection 1:500.000.000 (254 dpi)