Your search keyword '"Jaffar Hasnain"' showing total 7 results

1. Ballistic Ejection of Microdroplets from Overpacked Interfacial Assemblies (Adv. Funct. Mater. 20/2023)

Author

Xuefei Wu, Gautam Bordia, Robert Streubel, Jaffar Hasnain, Cássio C.S. Pedroso, Bruce E. Cohen, Behzad Rad, Paul Ashby, Ahmad K. Omar, Phillip L. Geissler, Dong Wang, Han Xue, Jianjun Wang, and Thomas P. Russell

Subjects

Biomaterials, Electrochemistry, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Published

2023

2. Ballistic Ejection of Microdroplets from Overpacked Interfacial Assemblies

Author

Xuefei Wu, Gautam Bordia, Robert Streubel, Jaffar Hasnain, Cássio C.S. Pedroso, Bruce E. Cohen, Behzad Rad, Paul Ashby, Ahmad K. Omar, Phillip L. Geissler, Dong Wang, Han Xue, Jianjun Wang, and Thomas P. Russell

Subjects

FOS: Physical sciences, magnetic field, Condensed Matter - Soft Condensed Matter, explosive emulsification, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Biomaterials, Engineering, magnetic nanoparticle surfactants, overpacked interfacial assemblies, Physical Sciences, Chemical Sciences, Electrochemistry, Soft Condensed Matter (cond-mat.soft), Materials

Abstract

Spontaneous emulsification, resulting from the assembly and accumulation of surfactants at liquid-liquid interfaces, is an interfacial instability where microdroplets are generated and diffusively spread from the interface until complete emulsification. Here, we show that an external magnetic field can modulate the assembly of paramagnetic nanoparticle surfactants (NPSs) at liquid-liquid interfaces and trigger an oversaturation in the areal density of the NPSs at the interface, as evidenced by a marked reduction in the interfacial tension, {\gamma}, and corroborated with a magnetostatic continuum theory. Despite the significant reduction in {\gamma}, the presence of the magnetic field does not cause stable interfaces to become unstable. Upon rapid removal of the field, however, an explosive ejection of a plume of microdroplets from the surface occurs, a dynamical interfacial instability which is termed explosive emulsification. This explosive event rapidly reduces the areal density of the NPSs to its pre-field level, stabilizing the interface. The ability to externally suppress or trigger the explosive emulsification and controlled generation of tens of thousands of microdroplets, uncovers an efficient energy storage and release process, that has potential applications for controlled and directed delivery of chemicals and remotely controlled soft microrobots, taking advantage of the ferromagnetic nature of the microdroplets., Comment: Main text and supporting information. See https://berkeley.box.com/s/tmfzh0c1gj2r7aoz7klbsmvmbcakm269 for supporting videos

Published

2023

3. The Buckling Spectra of Nanoparticle Surfactant Assemblies

Author

Narayanan Menon, Anju Toor, Paul D. Ashby, Wenqian Feng, Brett A. Helms, Andres Mariano, Xubo Liu, Joe Forth, Phillip L. Geissler, Jaffar Hasnain, Yu Chai, Thomas P. Russell, and Yufeng Jiang

Subjects

Materials science, Flexural modulus, Mechanical Engineering, Soft robotics, Nanoparticle, Bioengineering, Nanotechnology, General Chemistry, Condensed Matter Physics, Power law, Surface-Active Agents, Membrane, Buckling, Anisotropy, Nanoparticles, General Materials Science, Self-assembly

Abstract

Fine control over the mechanical properties of thin sheets underpins transcytosis, cell shape, and morphogenesis. Applying these principles to artificial, liquid-based systems has led to reconfigurable materials for soft robotics, actuation, and chemical synthesis. However, progress is limited by a lack of synthetic two-dimensional membranes that exhibit tunable mechanical properties over a comparable range to that seen in nature. Here, we show that the bending modulus, B, of thin assemblies of nanoparticle surfactants (NPSs) at the oil-water interface can be varied continuously from sub-kBT to 106kBT, by varying the ligands and particles that comprise the NPS. We find extensive departure from continuum behavior, including enormous mechanical anisotropy and a power law relation between B and the buckling spectrum width. Our findings provide a platform for shape-changing liquid devices and motivate new theories for the description of thin-film wrinkling.

Published

2021

4. Direct observation of nanoparticle-surfactant assembly and jamming at the water-oil interface

Author

Siqi Li, Dong Li, Thomas P. Russell, Paul Kim, Phillip L. Geissler, Dangyuan Lei, Kushaan Bahl, Brett A. Helms, Yufeng Jiang, Yu Chai, Paul D. Ashby, Pei-Yang Gu, Jaffar Hasnain, and Matthew Wong

Subjects

In situ, Materials science, Interface (computing), education, Materials Science, Nanoparticle, Jamming, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Pulmonary surfactant, Area density, Diffusion (business), Research Articles, Multidisciplinary, fungi, SciAdv r-articles, Condensed Matter Physics, 021001 nanoscience & nanotechnology, Electrostatics, humanities, 0104 chemical sciences, cardiovascular system, 0210 nano-technology, Research Article

Abstract

Direct observation of nanoparticle adsorption to the water-oil interface captures early attachment and jamming., Electrostatic interactions between nanoparticles (NPs) and functionalized ligands lead to the formation of NP surfactants (NPSs) that assemble at the water-oil interface and form jammed structures. To understand the interfacial behavior of NPSs, it is necessary to understand the mechanism by which the NPSs attach to the interface and how this attachment depends on the areal coverage of the interface. Through direct observation with high spatial and temporal resolution, using laser scanning confocal microscopy and in situ atomic force microscopy (AFM), we observe that early-stage attachment of NPs to the interface is diffusion limited and with increasing areal density of the NPSs, further attachment requires cooperative displacement of the previously assembled NPSs both laterally and vertically. The unprecedented detail provided by in situ AFM reveals the complex mechanism of attachment and the deeply nonequilibrium nature of the assembly.

Published

2020

5. Dynamical phases of attractive particles sliding on a structured surface

Author

Swetlana Jungblut, Jaffar Hasnain, and Christoph Dellago

Subjects

Surface (mathematics), Lattice constant, Classical mechanics, Particle separation, Chemical physics, Chemistry, Monolayer, Yukawa potential, General Materials Science, Relative strength, Substrate (electronics), Quartz crystal microbalance, Condensed Matter Physics

Abstract

Inspired by experiments on quartz crystal microbalance setups, we study the mobility of a monolayer of Lennard-Jones particles driven over a hexagonal external potential. We pay special attention to the changes in the dynamical phases that arise when the lattice constant of the external substrate potential and the Lennard-Jones interaction are mismatched. We find that if the average particle separation is such that the particles repel each other, or interact harmonically, the qualitative behavior of the system is akin to that of a monolayer of purely repulsive Yukawa particles. On the other hand, if the particles typically attract each other, the ensuing dynamical states are determined entirely by the relative strength of the Lennard-Jones interaction with respect to that of the external potential.

Published

2015

6. Frictional dynamics of stiff monolayers: from nucleation dynamics to thermal sliding

Author

Jaffar Hasnain, Christoph Dellago, Swetlana Jungblut, and Andreas Tröster

Subjects

Nonlinear system, Classical mechanics, Chemistry, Differential equation, Dynamics (mechanics), Monolayer, Nucleation, Thermal fluctuations, General Materials Science, Statistical mechanics, Scaling

Abstract

The inherently nonlinear dynamics of two surfaces as they are driven past each other, a phenomenon known as dry friction, has yet to be fully understood on an atomistic level. New experiments on colloidal monolayers forced over laser-generated substrates now offer the opportunity to investigate friction with single-particle resolution. Here, we use analytical theory and computer simulations to study the effect of thermal fluctuations on the stick-slip mechanism characteristic for the frictional response of a stiff colloidal monolayer on a commensurate substrate. By performing a harmonic expansion of the energy and employing elementary statistical mechanics, we map the motion of the monolayer onto a simple differential equation. Analytical expressions derived from our approach predict a transition from nucleation dynamics, where the monolayer moves in a sequence of activated hops over energy barriers, to “thermal sliding”, in which the effective substrate barrier opposing the motion of the monolayer disappears due to thermal fluctuations, leading to continuous, uninterrupted sliding motion. Furthermore, we find that the average velocity of the monolayer for large driving forces obeys a simple scaling behavior that is consistent with the existence of a static friction. For small forces, however, nucleation provides a mode of motion that leads to a small but non-vanishing mobility of the monolayer. Data obtained from simulations confirm this picture and agree quantitatively with our analytical formulae. The theory developed here holds under general conditions for sufficiently strong inter-particle repulsions and it yields specific predictions that can be tested in experiments.

Published

2014

7. Dynamic phases of colloidal monolayers sliding on commensurate substrates

Author

Jaffar Hasnain, Swetlana Jungblut, and Christoph Dellago

Subjects

Work (thermodynamics), Chemistry, General Chemistry, Substrate (electronics), Condensed Matter Physics, Symmetry (physics), Condensed Matter::Soft Condensed Matter, Colloid, Crystallography, Chemical physics, Distortion, Monolayer, Diffusion (business), Langevin dynamics

Abstract

We report on numerical simulations of a monolayer of charge-stabilized colloids driven over a substrate potential by an external dc force acting along a symmetry axis of the monolayer. Using overdamped Langevin dynamics, we studied the sliding transition for various inter-particle interaction strengths as a function of the driving force. For weak interactions, the diffusion of individual defects is responsible for the motion of the monolayer. As the interaction strength is increased, sliding is induced by distinct density compression and decompression zones. For very strong interactions, a type of stick-slip mechanism emerges, in which the sliding of the monolayer is mediated by the propagation of collective distortion waves. Our predictions can be tested experimentally with two-dimensional arrangements of colloidal particles exposed to periodic light fields and our work shows that the inter-particle interaction strength tunes the degree of correlation in the sliding mechanism adopted by a monolayer driven over a commensurate substrate.

Published

2013