@article{JRC30887,
	address = {},
	year = {2005},
	author = {Drossinos I and Housiadas C},
	abstract = {Thermophoretic deposition in laminar and turbulent circularpipe
		flows is investigated. One-dimensional (1D) Eulerian and twodimensional
		(2D) Eulerian and Lagrangian models are developed.
		In 1D models the importance of correct reference scales is demonstrated.
		A 1D universal expression for the thermophoretic deposition
		efficiency in a long tube is derived that is valid for laminar
		and turbulent flows and that gives excellent agreement with previous
		empirical correlations and theoretical results.Two-dimensional
		models incorporating radial-profile effects are developed to assess
		the effectiveness of the 1D approach. The 2D modelling is based
		on a nonstochastic Lagrangian methodology that allows the calculation
		of thermophoretic deposition with computationally inexpensive
		means. The developed models are extensively validated by
		comparing their predictions to experimental results, previous numerical
		calculations, and theoretical results in laminar and turbulent
		flows. The models are also used to calculate thermophoretic
		deposition in large-scale experiments simulating fission-product
		behavior during a postulated severe accident at a nuclear power
		plant. It is found that in laminar flow a properly constructed 1D
		description provides accurate predictions. In turbulent flow1Dand
		2D predictions provide the same degree of accuracy, unless large
		bulk gas-to-wall temperature differences prevail where the more
		detailed 2D approach offers significant improvement.
		},
	title = {Thermophoretic Deposition in Tube Flow},
	type = {},
	url = {},
	volume = {},
	number = {39},
	journal = {AEROSOL SCIENCE AND TECHNOLOGY},
	pages = {304-318},
	issn = {},
	publisher = {TAYLOR & FRANCIS INC},
	doi = {}
}