We develop and apply an efficient multiscale method for simulating a large class of low-speed internal rarefied gas flows. The method is an extension of the hybrid atomistic-continuum approach proposed by Borg et al. (2013) [28] for the simulation of micro/nano flows of high-aspect ratio. The major new extensions are: (1) incorporation of fluid compressibility; (2) implementation using the direct simulation Monte Carlo (DSMC) method for dilute rarefied gas flows, and (3) application to a broader range of geometries, including periodic, non-periodic, pressure-driven, gravity-driven and shear-driven internal flows. The multiscale method is applied to micro-scale gas flows through a periodic converging-diverging channel (driven by an external ...
A hybrid multiscale method is developed for simulating micro- and nano-scale fluid flows. The contin...
We present a hybrid molecular-continuum simulation method for modelling nano- and micro-flows in net...
AbstractWe present a new hybrid method for dilute gas flows that couples a continuum-fluid descripti...
AbstractWe develop and apply an efficient multiscale method for simulating a large class of low-spee...
We develop and apply an efficient multiscale method for simulating a large class of low-speed intern...
AbstractThis paper describes the development and application of an efficient hybrid continuum-molecu...
This paper describes the development and application of an efficient hybrid continuum-molecular appr...
We present a hybrid molecular-continuum method for the simulation of general nano-fluidic networks, ...
International audienceThe present paper extends the hybrid atomistic-continuum multiscale method dev...
This paper extends the hybrid computational method proposed by Docherty et al. (2014) for simulating...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/77289/1/AIAA-2008-1184-250.pd
We present an internal-flow multiscale method ('unsteady-IMM') for compressible, time-varying/unstea...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/83650/1/AIAA-2010-820-828.pd
We present a new hybrid method for dilute gas flows that couples a continuum-fluid description to th...
International audienceA hybrid atomistic-continuum method devoted to the study of multi-scale proble...
A hybrid multiscale method is developed for simulating micro- and nano-scale fluid flows. The contin...
We present a hybrid molecular-continuum simulation method for modelling nano- and micro-flows in net...
AbstractWe present a new hybrid method for dilute gas flows that couples a continuum-fluid descripti...
AbstractWe develop and apply an efficient multiscale method for simulating a large class of low-spee...
We develop and apply an efficient multiscale method for simulating a large class of low-speed intern...
AbstractThis paper describes the development and application of an efficient hybrid continuum-molecu...
This paper describes the development and application of an efficient hybrid continuum-molecular appr...
We present a hybrid molecular-continuum method for the simulation of general nano-fluidic networks, ...
International audienceThe present paper extends the hybrid atomistic-continuum multiscale method dev...
This paper extends the hybrid computational method proposed by Docherty et al. (2014) for simulating...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/77289/1/AIAA-2008-1184-250.pd
We present an internal-flow multiscale method ('unsteady-IMM') for compressible, time-varying/unstea...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/83650/1/AIAA-2010-820-828.pd
We present a new hybrid method for dilute gas flows that couples a continuum-fluid description to th...
International audienceA hybrid atomistic-continuum method devoted to the study of multi-scale proble...
A hybrid multiscale method is developed for simulating micro- and nano-scale fluid flows. The contin...
We present a hybrid molecular-continuum simulation method for modelling nano- and micro-flows in net...
AbstractWe present a new hybrid method for dilute gas flows that couples a continuum-fluid descripti...