TENDL-2023 Nuclear data library

Deuteron sub-library for Si (Z=14) and A=30: Tabulated production and total cross sections

Production and total cross sections

Reaction #	Si(d,all)	Si(d,x)a	Si(d,x)d	Si(d,x)g	Si(d,x)he3	Si(d,non)	Si(d,x)n	Si(d,x)p	Si(d,reac)	Si(d,x)t

Reaction #

Partial cross sections

Reaction #	Si(d,g)	Si(d,a)	Si(d,2a)	Si(d,3a)

Reaction #	Si(d,He3)	Si(d,He3+a)	Si(d,He3+2a)	Si(d,t)

Reaction #	Si(d,t+a)	Si(d,t+2a)	Si(d,t+He3)	Si(d,t+He3+a)

Reaction #	Si(d,d)	Si(d,d+a)	Si(d,d+2a)	Si(d,d+He3)

Reaction #	Si(d,d+He3+a)	Si(d,d+t)	Si(d,d+t+a)	Si(d,d+t+He3)

Reaction #	Si(d,2d)	Si(d,2d+a)	Si(d,2d+He3)	Si(d,2d+t)

Reaction #	Si(d,p)	Si(d,p+a)	Si(d,p+2a)	Si(d,p+He3)

Reaction #	Si(d,p+He3+a)	Si(d,p+t)	Si(d,p+t+a)	Si(d,p+t+2a)

Reaction #	Si(d,p+t+He3)	Si(d,p+d)	Si(d,p+d+a)	Si(d,p+d+2a)

Reaction #	Si(d,p+d+He3)	Si(d,p+d+t)	Si(d,p+d+t+a)	Si(d,p+2d)

Reaction #	Si(d,p+2d+a)	Si(d,2p)	Si(d,2p+a)	Si(d,2p+2a)

Reaction #	Si(d,2p+He3)	Si(d,2p+t)	Si(d,2p+t+a)	Si(d,2p+d)

Reaction #	Si(d,2p+d+a)	Si(d,2p+d+t)	Si(d,2p+2d)	Si(d,3p)

Reaction #	Si(d,3p+a)	Si(d,3p+t)	Si(d,3p+d)	Si(d,4p)

Reaction #	Si(d,n)	Si(d,n+a)	Si(d,n+2a)	Si(d,n+3a)

Reaction #	Si(d,n+He3)	Si(d,n+He3+a)	Si(d,n+He3+2a)	Si(d,n+t)

Reaction #	Si(d,n+t+a)	Si(d,n+t+2a)	Si(d,n+t+He3)	Si(d,n+t+He3+a)

Reaction #	Si(d,n+d)	Si(d,n+d+a)	Si(d,n+d+2a)	Si(d,n+d+He3)

Reaction #	Si(d,n+d+He3+a)	Si(d,n+d+t)	Si(d,n+d+t+a)	Si(d,n+2d)

Reaction #	Si(d,n+2d+a)	Si(d,n+2d+t)	Si(d,n+p)	Si(d,n+p+a)

Reaction #	Si(d,n+p+2a)	Si(d,n+p+He3)	Si(d,n+p+He3+a)	Si(d,n+p+t)

Reaction #	Si(d,n+p+t+a)	Si(d,n+p+t+He3)	Si(d,n+p+d)	Si(d,n+p+d+a)

Reaction #	Si(d,n+p+d+2a)	Si(d,n+p+d+He3)	Si(d,n+p+d+t)	Si(d,n+p+2d)

Reaction #	Si(d,n+p+2d+a)	Si(d,n+2p)	Si(d,n+2p+a)	Si(d,n+2p+2a)

Reaction #	Si(d,n+2p+He3)	Si(d,n+2p+t)	Si(d,n+2p+t+a)	Si(d,n+2p+d)

Reaction #	Si(d,n+2p+d+a)	Si(d,n+3p)	Si(d,n+3p+a)	Si(d,n+3p+t)

Reaction #	Si(d,n+3p+d)	Si(d,n+4p)	Si(d,2n)	Si(d,2n+a)

Reaction #	Si(d,2n+2a)	Si(d,2n+3a)	Si(d,2n+He3)	Si(d,2n+He3+a)

Reaction #	Si(d,2n+t)	Si(d,2n+t+a)	Si(d,2n+t+He3)	Si(d,2n+d)

Reaction #	Si(d,2n+d+a)	Si(d,2n+d+2a)	Si(d,2n+d+He3)	Si(d,2n+d+t)

Reaction #	Si(d,2n+2d)	Si(d,2n+p)	Si(d,2n+p+a)	Si(d,2n+p+2a)

Reaction #	Si(d,2n+p+He3)	Si(d,2n+p+He3+a)	Si(d,2n+p+t)	Si(d,2n+p+t+a)

Reaction #	Si(d,2n+p+d)	Si(d,2n+p+d+a)	Si(d,2n+p+d+t)	Si(d,2n+p+2d)

Reaction #	Si(d,2n+2p)	Si(d,2n+2p+a)	Si(d,2n+2p+He3)	Si(d,2n+2p+t)

Reaction #	Si(d,2n+2p+d)	Si(d,2n+3p)	Si(d,2n+3p+a)	Si(d,3n)

Reaction #	Si(d,3n+a)	Si(d,3n+2a)	Si(d,3n+He3)	Si(d,3n+He3+a)

Reaction #	Si(d,3n+t)	Si(d,3n+d)	Si(d,3n+d+a)	Si(d,3n+d+He3)

Reaction #	Si(d,3n+p)	Si(d,3n+p+a)	Si(d,3n+p+2a)	Si(d,3n+p+He3)

Reaction #	Si(d,3n+p+t)	Si(d,3n+p+d)	Si(d,3n+2p)	Si(d,3n+2p+a)

Reaction #	Si(d,3n+2p+d)	Si(d,3n+3p)