function [Nelectron_Layer]= Electron_arrangement(x)
if x==1 % H
Nelectron_Layer(1,1) = 1;
end
if x==2 % He
Nelectron_Layer(1,1)=2;
end
if x==3 % Li
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=1;
end
if x==4 % Be
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=2;
end
if x==5 % B
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=3;
end
if x==6 % C
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=4;
end
if x==7 % N
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=5;
end
if x==8 % O
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=6;
end
if x==9 % F
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=7;
end
if x==10 % Ne
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
end
if x==11 % Na
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=1;
end
if x==12 % Mg
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=2;
end
if x==13 % Al
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=3;
end
if x==14 % Si
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=4;
end
if x==15 % P
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=5;
end
if x==16 % S
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=6;
end
if x==17 % Cl
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=7;
end
if x==18 % Ar
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=8;
end
if x==19 % K
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=8;
Nelectron_Layer(4,1)=1;
end
if x==20 % Ca
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=8;
Nelectron_Layer(4,1)=2;
end
if x==21 % Sc
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=9;
Nelectron_Layer(4,1)=2;
end
if x==22 % Ti
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=10;
Nelectron_Layer(4,1)=2;
end
if x==23 % V
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=11;
Nelectron_Layer(4,1)=2;
end
if x==24 % Cr
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=13;
Nelectron_Layer(4,1)=1;
end
if x==25 % Mn
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=13;
Nelectron_Layer(4,1)=2;
end
if x==26 % Fe
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=14;
Nelectron_Layer(4,1)=2;
end
if x==27 % Co
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=15;
Nelectron_Layer(4,1)=2;
end
if x==28 % Ni
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=16;
Nelectron_Layer(4,1)=2;
end
if x==29 % Cu
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=1;
end
if x==30 % Zn
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=2;
end
if x==31 % Ga
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=3;
end
if x==32 % Ge
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=4;
end
if x==33 % As
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=5;
end
if x==34 % Se
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=6;
end
if x==35 % Br
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=7;
end
if x==36 % Kr
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=8;
end
if x==37 % Rb
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=8;
Nelectron_Layer(5,1)=1;
end
if x==38 % Sr
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=8;
Nelectron_Layer(5,1)=2;
end
if x==39 % Y
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=9;
Nelectron_Layer(5,1)=2;
end
if x==40 % Zr
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=10;
Nelectron_Layer(5,1)=2;
end
if x==41 % Nb
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=12;
Nelectron_Layer(5,1)=1;
end
if x==42 % Mo
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=13;
Nelectron_Layer(5,1)=1;
end
if x==43 % Tc
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=13;
Nelectron_Layer(5,1)=2;
end
if x==44 % Ru
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=15;
Nelectron_Layer(5,1)=1;
end
if x==45 % Rh
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=16;
Nelectron_Layer(5,1)=1;
end
if x==46 % pd
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
end
if x==47 % Ag
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=1;
end
if x==48 % Cd
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=2;
end
if x==49 % In
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=3;
end
if x==50 % Sn
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=4;
end
if x==51 % Sb
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=5;
end
if x==52 % Te
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=6;
end
if x==53 % I
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=7;
end
if x==54 % Xe
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=8;
end
if x==55 % Cs
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=8;
Nelectron_Layer(6,1)=1;
end
if x==56 % Ba
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=8;
Nelectron_Layer(6,1)=2;
end
if x==57 % La
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=18;
Nelectron_Layer(5,1)=9;
Nelectron_Layer(6,1)=2;
end
if x==58 % Ce
Nelectron_Layer(1,1)=2;
Nelectron_Layer(2,1)=8;
Nelectron_Layer(3,1)=18;
Nelectron_Layer(4,1)=20;
Nelectron_Layer(5,1)=8;
Nelectron_Layer(6,1)=2;
end
if x==59 % Pr
Nelectron_Layer(1,1)=2;
Nelectron_Lay
同核分子优化(Homonuclear Molecules Optimization)算法附matlab代码.zip
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