function [ dm ] = emuslion2( t,n,n_s,n_M_0,V_p_0,V ) k_p = 715; % L/(mol*s) k_des = 1e-1; % 1/s k_e = 1e-6; % dm/s k_t = 9.8e6; % L/(mol*s) k_d = 5.55e-6; % 1/s N_A = 6.022*10^23; % 1/mol M_M = 0.1; % kg/mol p_M = 0.94; % kg/L p_P = 1.10; % kg/L w_I = 0.01; m_M_0 = n_M_0*M_M; % kg m_I = w_I*m_M_0; % kg M_I = 0.164; % kg/mol f = 0.5; c_I = m_I/(M_I*V); % mol/L c_R = sqrt(2*f*k_d*c_I/k_t); % mol/L %% n_M = n(1); % amount of total monomer available n_M_p = n(2); % amount of monomer in particles n_M_d = n_M-n_M_p; % amount of monomer in dispersed phase %% v_pol = V_p_0+(n_M_0-n_M)*M_M/(n_s*p_P); v_p = v_pol+(n_M_p/n_s)*(M_M/p_M); phi = (v_p-v_pol)/v_p; c_M = n_M_p/(n_s*v_p); diam = (6*v_p/pi)^(1/3); A_p = 4*pi*(diam/2)^2; rho = A_p*k_e*c_R*N_A; n_bar = (rho/(2*rho+k_des)); %% dn_M = - k_p*c_M*n_bar/N_A*n_s; dv_pol = - dn_M*M_M/(p_P*n_s); %% if n_M_d > 0 dn_M_P = n_s*c_M*1/(1-phi)*dv_pol; else dn_M_P = dn_M; end %% dm = [dn_M; dn_M_P]; end