| 1 | For inelastic scattering, the currently supported final states are (nA$\rightarrow$)
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| 2 | n$\gamma$s (discrete and continuum), np, nd, nt, n$^3$He, n$\alpha$, nd2$\alpha$,
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| 3 | nt2$\alpha$, n2p, n2$\alpha$, np$\alpha$, n3$\alpha$, 2n, 2np,
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| 4 | 2nd, 2n$\alpha$, 2n2$\alpha$, nX, 3n, 3np, 3n$\alpha$, 4n, p,
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| 5 | pd, p$\alpha$, 2p d, d$\alpha$, d2$\alpha$, dt, t, t2$\alpha$,
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| 6 | $^3$He, $\alpha$, 2$\alpha$, and 3$\alpha$.
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| 7 |
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| 8 | The photon distributions are again described as in the case of
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| 9 | radiative capture.
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| 10 |
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| 11 | The
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| 12 | possibility to describe the angular and energy distributions of the final
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| 13 | state particles as in the case of fission is maintained, except that normally
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| 14 | only the arbitrary tabulation of secondary energies is applicable.
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| 15 |
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| 16 | In addition, we support the possibility to describe the energy angular
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| 17 | correlations explicitly, in analogy with the ENDF/B-VI data formats.
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| 18 | In this case, the production cross-section for
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| 19 | reaction product n can be written as
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| 20 | $$\sigma_n(E, E', \cos(\theta))~=~\sigma(E)Y_n(E)p(E, E', \cos(\theta)).$$
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| 21 | Here $Y_n(E)$ is the product multiplicity, $\sigma(E)$ is the inelastic
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| 22 | cross-section, and $p(E, E', \cos(\theta))$ is the distribution probability.
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| 23 | Azimuthal symmetry is assumed.
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| 24 |
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| 25 | The representations for the distribution probability supported are iso\-tro\-pic
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| 26 | emission, discrete two-body kinematics, N-body phase-space distribution,
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| 27 | continuum energy-angle distributions, and continuum angle-energy distributions
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| 28 | in the laboratory system.
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| 29 |
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| 30 | The description of isotropic emission and discrete two-body kinematics is
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| 31 | possible without further information. In the case of N-body phase-space
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| 32 | distribution, tabulated values for the number of particles being treated by the
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| 33 | law, and the total mass of these particles are used.
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| 34 | For the continuum energy-angle distributions, several options for representing
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| 35 | the angular dependence are available. Apart from the already introduced methods
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| 36 | of expansion in terms of legendre polynomials, and tabulation (here in
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| 37 | both the incoming neutron energy, and the secondary energy), the Kalbach-Mann
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| 38 | systematic is available.
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| 39 | In the case of the continuum angle-energy distributions
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| 40 | in the laboratory system, only the tabulated form in incoming neutron energy,
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| 41 | product energy, and product angle is implemented.
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| 42 |
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| 43 | First comparisons for product yields, energy and angular distributions have
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| 44 | been performed for a set of incoming neutron energies, but full test coverage
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| 45 | is still to be achieved.
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| 46 | In all cases currently investigated, the agreement between evaluated data and
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| 47 | Monte Carlo is very good.
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