TY - JOUR
T1 - Packing in multimodal crystals and particle assemblies as models for dynamic packing during spontaneous and enforced particle movement
T2 - Settling, viscosity and elasticity
AU - Rosenholm, Jarl B.
N1 - Publisher Copyright:
© 2024 The Author
PY - 2024/9
Y1 - 2024/9
N2 - Colloid particles (CP, 10−8–10−6 m = 10–1000 nm) are used as models for atom scale processes, such as crystallization since the process is experimentally observable. Packing of atoms in crystals resemble mono-, bi-, and trimodal packing of noncharged hard spheres (particles). When the size of one particle exceeds the two others an excluded volume consisting of small particles is created around large particles. This is also the case when colloid particles are dispersed in water. The formation of an excluded volume does not require attraction forces, but it is enforced by the presence of dissolved primary (cations) and secondary (protons of surface hydroxyls) potential determining ions. The outcome is an interfacial solid-liquid charge. This excluded volume, denoted Stern layer is characterized by the surface potential and charge density. Charge neutrality is identified by point of zero charge (pHpzc and pcpzc). Outside Stern layer another excluded volume is formed of loosely bound counterions which interact with Stern layer. The extent of this diffuse layer is given by inverse Debye length and effective ζ-potential. The overall balance between attractive and repulsive energies is provided by Derjaguin-Landau-Veerwey-Overbeek (DLVO) model. Charge neutrality is identified at isoelectric point (pHiep and pciep). The dependence of viscosity and yield stress on shear rate may be modeled by von Smoluchowski's volumetric collision frequency multiplied by some total interaction energy given by DLVO model. Equilibrium and dynamic models for settling and enforced particle movement (viscosity) are presented. Both compressive yield stress (sedimentation) and cohesive energy (viscoelasticity) are characterized by power law exponents of volume fraction. The transition of disperse suspensions (sols) to spanning clusters (gels) is identified by oscillatory rheology. The slope of linear plots of logarithmic storage (G´) and loss (G") moduli against logarithm of frequency or logarithm of volume fraction provide power law exponents from the slopes. These exponents relate to percolation and fractal dimensions characterizing the particle network. Moreover, it identifies the structure formation process either as diffusion limited cluster-cluster (DLCCA) or as reaction limited cluster-cluster (RLCCA) aggregation.
AB - Colloid particles (CP, 10−8–10−6 m = 10–1000 nm) are used as models for atom scale processes, such as crystallization since the process is experimentally observable. Packing of atoms in crystals resemble mono-, bi-, and trimodal packing of noncharged hard spheres (particles). When the size of one particle exceeds the two others an excluded volume consisting of small particles is created around large particles. This is also the case when colloid particles are dispersed in water. The formation of an excluded volume does not require attraction forces, but it is enforced by the presence of dissolved primary (cations) and secondary (protons of surface hydroxyls) potential determining ions. The outcome is an interfacial solid-liquid charge. This excluded volume, denoted Stern layer is characterized by the surface potential and charge density. Charge neutrality is identified by point of zero charge (pHpzc and pcpzc). Outside Stern layer another excluded volume is formed of loosely bound counterions which interact with Stern layer. The extent of this diffuse layer is given by inverse Debye length and effective ζ-potential. The overall balance between attractive and repulsive energies is provided by Derjaguin-Landau-Veerwey-Overbeek (DLVO) model. Charge neutrality is identified at isoelectric point (pHiep and pciep). The dependence of viscosity and yield stress on shear rate may be modeled by von Smoluchowski's volumetric collision frequency multiplied by some total interaction energy given by DLVO model. Equilibrium and dynamic models for settling and enforced particle movement (viscosity) are presented. Both compressive yield stress (sedimentation) and cohesive energy (viscoelasticity) are characterized by power law exponents of volume fraction. The transition of disperse suspensions (sols) to spanning clusters (gels) is identified by oscillatory rheology. The slope of linear plots of logarithmic storage (G´) and loss (G") moduli against logarithm of frequency or logarithm of volume fraction provide power law exponents from the slopes. These exponents relate to percolation and fractal dimensions characterizing the particle network. Moreover, it identifies the structure formation process either as diffusion limited cluster-cluster (DLCCA) or as reaction limited cluster-cluster (RLCCA) aggregation.
KW - Characterization of elasticity and sol-gel transition
KW - Dependence of suspension stability on (effective) surface potential and charge density
KW - Ion distribution in stern and diffuse layers
KW - Packing in crystals and particle assemblies
KW - Relationship between settling and low-shear viscosimetry
KW - Viscoelasticity of loose flocculated and dense coagulated particle networks
KW - Packing in crystals and particle assemblies
KW - Ion distribution in stern and diffuse layers
KW - Dependence of suspension stability on (effective) surface potential and charge density
KW - Relationship between settling and low-shear viscosimetry
KW - Viscoelasticity of loose flocculated and dense coagulated particle networks
KW - Characterization of elasticity and sol-gel transition
UR - http://www.scopus.com/inward/record.url?scp=85197270126&partnerID=8YFLogxK
U2 - 10.1016/j.cis.2024.103165
DO - 10.1016/j.cis.2024.103165
M3 - Review Article or Literature Review
C2 - 38964197
AN - SCOPUS:85197270126
SN - 0001-8686
VL - 331
JO - Advances in Colloid and Interface Science
JF - Advances in Colloid and Interface Science
M1 - 103165
ER -