Columnar and lamellar phases in attractive colloidal systems

Abstract: In colloidal suspensions, at low volume fraction and temperature, dynamical arrest occurs via the growth of elongated structures, that aggregate to form a connected network at gelation. Here we show that, in the region of parameter space where gelation occurs, the stable thermodynamical phase is a crystalline columnar one. Near and above the gelation threshold, the disordered spanning network slowly evolves and finally orders to form the crystalline structure. At higher volume fractions the stable phase is a l… Show more

“…Substituting Eq. (27) into (28) and making a Taylor expansion in the LDA hard-sphere part of the free energy, we obtain:…”

“…Structuring and pattern formation has also been seen in two dimensional systems [7,8], where the repulsion is likely to be due to dipole-dipole interactions between the particles at the surface. Together with these experimental studies, there has been significant theoretical interest in model colloidal systems exhibiting such competing interactions [9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31]. An overview of the results and conclusions drawn from this body of work is given in Ref.…”

“…We should expect the wave number for the modulations in Eq. (27) to be k = k c . However, for the present we will not make any assumptions concerning the precise value of k in Eq.…”

“…However, for the present we will not make any assumptions concerning the precise value of k in Eq. (27), other than to assume it is finite and non-zero. From our assumption that the density profile varies in only one Cartesian direction we may re-write the Helmholtz free energy (7) as follows: (28) where the limits on the integrals go from −L/2 to L/2 (we implicitly take the thermodynamic limit L → ∞), L 2 = dx dy is the system cross sectional area and…”

“…(ii) We assume the density modulations δρ(z) are of the form ρ(z) =ρ + δρ(z) =ρ + A sin(kz), (27) whereρ is the average fluid density and the amplitude A is the order parameter for the transition. We should expect the wave number for the modulations in Eq.…”

Theory for the phase behaviour of a colloidal fluid with competing interactions

“…Substituting Eq. (27) into (28) and making a Taylor expansion in the LDA hard-sphere part of the free energy, we obtain:…”

“…Structuring and pattern formation has also been seen in two dimensional systems [7,8], where the repulsion is likely to be due to dipole-dipole interactions between the particles at the surface. Together with these experimental studies, there has been significant theoretical interest in model colloidal systems exhibiting such competing interactions [9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31]. An overview of the results and conclusions drawn from this body of work is given in Ref.…”

“…We should expect the wave number for the modulations in Eq. (27) to be k = k c . However, for the present we will not make any assumptions concerning the precise value of k in Eq.…”

“…However, for the present we will not make any assumptions concerning the precise value of k in Eq. (27), other than to assume it is finite and non-zero. From our assumption that the density profile varies in only one Cartesian direction we may re-write the Helmholtz free energy (7) as follows: (28) where the limits on the integrals go from −L/2 to L/2 (we implicitly take the thermodynamic limit L → ∞), L 2 = dx dy is the system cross sectional area and…”

“…(ii) We assume the density modulations δρ(z) are of the form ρ(z) =ρ + δρ(z) =ρ + A sin(kz), (27) whereρ is the average fluid density and the amplitude A is the order parameter for the transition. We should expect the wave number for the modulations in Eq.…”

Theory for the phase behaviour of a colloidal fluid with competing interactions

Advances in the Molecular Simulation of Microphase Formers

Anisotropic self‐assembly and gelation in aqueous methylcellulose—theory and modeling