$ \bar{H} \equiv\displaystyle\frac{2 J }{ g \gamma }\overline{\sum_{ k =1}^ n S_{kz} }$

H_m = 2* J @SUM( S_kz , k ,1 , n )/( g * gamma )

$ {\cal H}_j =- g \gamma ( H_0 + \bar{H} ) S_{jz} $

cH_j=- g * gamma *( H_0 + H_m )* S_jz

$ E_m =- g \mu_B ( H_0 + \bar{H} ) m $

E_m =- g * mu_B * ( H_0 + H_m ) * m

$ Z_W =\displaystyle\frac{\sinh( s +\displaystyle\frac{1}{2}) \eta }{\sinh\displaystyle\frac{1}{2} \eta }$

Z_W = sinh(( s +1/2)* eta ))/sinh( eta / 2)

$ \eta =\displaystyle\frac{ g \mu_B H }{ k_B T }$

eta = g * mu_B * H /( k_B * T )

$ \bar{S}_{jz} = g \mu_B S B_S(\eta) $

S_jz = g * mu_B * S * B_S

$ B_s(\eta) \equiv \displaystyle\frac{1}{ s }\left[( s +\displaystyle\frac{1}{2})\coth( s +\displaystyle\frac{1}{2}) \eta -\displaystyle\frac{1}{2}\coth\displaystyle\frac{1}{2} \eta \right]$

B_s = (( s +1/2)*coth(( s +1/2)* eta )-(1/2)*coth( eta /2))/ s

$2 J n s B_s(\eta)= k_B T \eta - g \mu_B H_0 $

2* J * n * s * B_s = k_B * T * eta - g * mu_B * H_0

$ T_c =\displaystyle\frac{2 n J s ( s +1)}{3 k_B }$

T_c = 2* n * J * s * ( s +1)/(3* k_B )

$ \eta =\displaystyle\frac{ g \mu_B H_0 }{ k_B ( T - T_c )}$

eta = g * mu_B * H_0 /( k_B * ( T - T_c ))

$ \chi = \displaystyle\frac{ N g ^2 \mu \mu_B ^2 s ( s +1)}{3 k_B ( T - T_c )}$

chi = N * g ^2* mu * mu_B ^2* s *( s +1)/(3* k_B *( T - T_c ))

$ \bar{M} = g \mu \mu_B s B_s(\eta) N $

M_m = g * mu * mu_B * s * B_s(eta) * N