Issues »  Volume 47, Issue 7

‘Orbital Glass’ Effects. 6. Alloy Decomposition

O. I. Mitsek, V. M. Pushkar

G. V. Kurdyumov Institute for Metal Physics, N.A.S. of Ukraine, 36 Academician Vernadsky Blvd., UA-03142 Kyiv, Ukraine

Received: 01.01.2025; final version - 13.03.2025. Download: PDF

Decomposition of A1−cBc alloy picks out structures with different orbital glasses (OG). Quantity of elements in structure is NGG (Galois group—GG). That is segregation of orbital moments Lr of Co ions. Form and size of structure depend on Lr and their interaction Γρ(Lr, Lr+ρ). The separation of flat GG(x0y) is periodical. Decomposition period Δz depends on hardness and NGG(z) of flat phases and their thermostriction. That describes experimental data. Decomposition of FeCx (damask steel) gives ‘daggers’ stretched along 0z-axis in soft Fe. Daggers’ hardness increases with increase of [x, Cx] as (GG-3) of OG material. Overtones of damask-steel sound are determined by domain (GG-3) as OG phase. Calculation by many-electron operator spinors method gives finite quantity of hardness of phase (Cu1−xCox plane, ‘dagger’ FeCx and others) and their sound (ωn of overtones). Nuclear decay of U232 and U1−xPux is connected with decrease of neutron quality Nn < 146. Two versions are possible: going off n, breach of balance of Coulomb energy of Np protons and segregation (OG) of hadron orbital moments Lr; ousting (Nn ≤ 146 − x) by increase of Np ≥ (92 + x). These versions are possible under closing of semi-spheres of U1−xPux alloy to appearance of nuclear explosion.

Key words: orbital glass, lamellar decomposition, damask steel, nuclear decay of U–Pu.

URL: https://mfint.imp.kiev.ua/en/abstract/v47/i07/0667.html

DOI: https://doi.org/10.15407/mfint.47.07.0667

PACS: 64.60.De, 64.75.Op, 71.10.-w., 75.10.Dg, 75.10.Nr, 75.30.Et, 75.50.Lk

Citation: O. I. Mitsek and V. M. Pushkar, ‘Orbital Glass’ Effects. 6. Alloy Decomposition, Metallofiz. Noveishie Tekhnol., 47, No. 7: 667-673 (2025) (in Ukrainian)

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