Your search keyword '"electroosmotic effects"' showing total 2 results

1. Modeling and Simulations of Buongiorno’s Model for Nanofluid in a Microchannel with Electro-Osmotic Effects and an Exothermal Chemical Reaction

Author

Ammarah Raees, Muhammad Raees-ul-Haq, and Muavia Mansoor

Subjects

electroosmotic effects, Arrhenius kinetics, nanofluids, Buongiorno’s model, slip boundary conditions, MHD, Chemistry, QD1-999

Abstract

The article presents a mathematical model for the magnetized nanofluid flow and heat transfer with an exothermic chemical reaction controlled by Arrhenius kinetics. Buongiorno’s model with passive boundary condition is employed to formulate the governing equation for nanoparticles concentration. The momentum equation with slip boundary conditions is modelled with the inclusion of electroosmotic effects which remain inattentive in the study of microchannel flows with electric double layer (EDL) effects. Conclusions are based on graphical and numerical results for the dimensionless numbers representing the features of heat transfer and fluid flow. Frank-Kamenetskii parameter resulting from the chemical reaction showed significant effects on the optimization of heat transfer, leading to increased heat exchangers’ effectiveness. The Hartmann number and slip parameter significantly affect skin friction, demonstrating the notable effects of electroosmotic flow and the exothermic chemical reaction on heat transfer in microchannels. This analysis contributes to prognosticating the convective heat transfer of nanofluids on a micro-scale for accomplishing successful thermal designs.

Published

2021

2. Self-Limited Formation of Bowl-Shaped Nanopores for Directional DNA Translocation

Author

Daniel Primetzhofer, Shi-Li Zhang, Shuangshuang Zeng, Ngan Hoang Pham, Shiyu Li, Tomas Nyberg, Chenyu Wen, Zhen Zhang, Tuan Thien Tran, and Yao Yao

Subjects

Silicon, Nanoteknik, Materials science, Fabrication, General Physics and Astronomy, chemistry.chemical_element, Tapering, Electrical Engineering, Electronic Engineering, Information Engineering, Article, Nanopores, Rectification, Electric field, silicon technology, electroosmotic effects, General Materials Science, Elektroteknik och elektronik, local oxidation of silicon (LOCOS), bowl shape, directional DNA translocation, business.industry, Silicon Compounds, self-limiting formation, General Engineering, DNA, Nanopore, Nanolithography, chemistry, Nano Technology, Optoelectronics, solid-state nanopores, Electroosmosis, business, Body orifice

Abstract

Solid-state nanopores of on-demand dimensions and shapes can facilitate desired sensor functions. However, reproducible fabrication of arrayed nanopores of predefined dimensions remains challenging despite numerous techniques explored. Here, bowl-shaped nanopores combining properties of ultrathin membrane and tapering geometry are manufactured using a self-limiting process developed on the basis of standard silicon technology. The upper opening of the bowl-nanopores is 60–120 nm in diameter, and the bottom orifice reaches sub-5 nm. Current-voltage characteristics of the fabricated bowl-nanopores display insignificant rectification indicating weak ionic selectivity, in accordance to numerical simulations showing minor differences in electric field and ionic velocity upon the reversal of bias voltages. Simulations reveal, concomitantly, high-momentum electroosmotic flow downward along the concave nanopore sidewall. Collisions between the left and right tributaries over the bottom orifice drive the electroosmotic flow both up into the nanopore and down out of the nanopore through the orifice. The resultant asymmetry in electrophoretic–electroosmotic force is considered the cause responsible for the experimentally observed strong directionality in λ-DNA translocation with larger amplitude, longer duration, and higher frequencies for the downward movements from the upper opening than the upward ones from the orifice. Thus, the resourceful silicon nanofabrication technology is shown to enable nanopore designs toward enriching sensor applications. Stiftelsen Olle Engkvist

Published

2021