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, Derivees.txt, p.4

, fprintf(fileID4,'%s \t

, fprintf(fileID4,'%s \n

, fprintf(fileID5,'%s \t

, fprintf(fileID5,'%s \n

, fprintf(fileID6,'%s \t', ' delta ')

, fprintf(fileID6,'%s \n

, %% Computation of intermediate fluxes % initialization of vectors delta=zeros(tf,1)

, Scanopy=zeros(tf, vol.1

, Lstem=zeros(tf, vol.1

, Nvessel=zeros(tf, vol.1

, L=zeros(tf, vol.1

, Imax=zeros(tf, vol.1

, UCO2max=zeros(tf,1)

, UH2Omax=zeros(tf,1)

, limit=zeros(tf, vol.1

, I=zeros(tf, vol.1

, UCO2=zeros(tf,1)

, UH2O=zeros(tf,1)

(. Vfree=zeros, , vol.1

, rho_leaf=zeros(tf, vol.1

, Delta_rho=zeros(tf, vol.1

, E_conv=zeros(tf, vol.1

, E_photons=zeros(tf, vol.1

, E_ray=zeros(tf, vol.1

, E_transpi=zeros(tf, vol.1

, Bilan=zeros(tf, vol.1

, JMc=zeros(tf, vol.1

, JMw=zeros(tf, vol.1

, JTleaf=zeros(tf, vol.1

, % Bulk Air nu=1, pp.8-13

, % Air kinematic viscosity (m2/s)

, % CO2 content in bulk air (ppm) Pb=85000

*. P0tb=100000 and . 10^, , vol.675, pp.4-1838

, Energy.txt, p.3

, fprintf(fileID3,'%s \t

, fprintf(fileID3,'%s \n

, Derivees.txt, p.4

, fprintf(fileID4,'%s \t

, fprintf(fileID4,'%s \n

, fprintf(fileID5,'%s \t

, fprintf(fileID5,'%s \n

, fprintf(fileID6,'%s \t', ' delta ')

, fprintf(fileID6,'%s \n

, %% Computation of intermediate fluxes % initialization of vectors delta=zeros(tf,1)

, Scanopy=zeros(tf, vol.1

, Lstem=zeros(tf, vol.1

, Nvessel=zeros(tf, vol.1

, L=zeros(tf, vol.1

, Imax=zeros(tf, vol.1

, UCO2max=zeros(tf,1)

, UH2Omax=zeros(tf,1)

, limit=zeros(tf, vol.1

, I=zeros(tf, vol.1

, UCO2=zeros(tf,1)

, UH2O=zeros(tf,1)

(. Vfree=zeros, , vol.1

, rho_leaf=zeros(tf, vol.1

, Delta_rho=zeros(tf, vol.1

, E_conv=zeros(tf, vol.1

, E_photons=zeros(tf, vol.1

, E_ray=zeros(tf, vol.1

, E_transpi=zeros(tf, vol.1

, Bilan=zeros(tf, vol.1

, JMc=zeros(tf, vol.1

, JMw=zeros(tf, vol.1

, JTleaf=zeros(tf, vol.1

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DOI : 10.1177/074171369604600404