Oriented attachment kinetics for rod-like particles at a flat surface: Buffon’s needle at the nanoscale

The adsorption of large rod-like molecules or crystallites on a flat crystal face, similar to Buffon’s needle, requires the rods to “land,” with their binding sites in precise orientational alignment with matching sites on the surface. An example is provided by long, helical antifreeze proteins (AFP...

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Bibliographic Details
Published in:The Journal of chemical physics 2022-12, Vol.157 (21), p.214113-214113
Main Authors: Kamat, Kartik, Naullage, Pavithra M., Molinero, Valeria, Peters, Baron
Format: Article
Language:English
Subjects:
Adsorption
Alignment
Antifreeze Proteins - chemistry
Aspect ratio
Attachment
Binding sites
Boundary conditions
Crystal growth
Crystallites
Crystallization
Diffusion
Exact solutions
Flat surfaces
Ice
Kinetics
Physics
Surface chemistry
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Summary:The adsorption of large rod-like molecules or crystallites on a flat crystal face, similar to Buffon’s needle, requires the rods to “land,” with their binding sites in precise orientational alignment with matching sites on the surface. An example is provided by long, helical antifreeze proteins (AFPs), which bind at specific facets and orientations on the ice surface. The alignment constraint for adsorption, in combination with the loss in orientational freedom as the molecule diffuses toward the surface, results in an entropic barrier that hinders the adsorption. Prior kinetic models do not factor in the complete geometry of the molecule, nor explicitly enforce orientational constraints for adsorption. Here, we develop a diffusion-controlled adsorption theory for AFP molecules binding at specific orientations to flat ice surfaces. We formulate the diffusion equation with relevant boundary conditions and present analytical solutions to the attachment rate constant. The resulting rate constant is a function of the length and aspect ratio of the AFP, the distance threshold associated with binding, and solvent conditions such as temperature and viscosity. These results and methods of calculation may also be useful for predicting the kinetics of crystal growth through oriented attachment.
ISSN:0021-9606
1089-7690
DOI:10.1063/5.0124531