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001			9781839628191
003			KnowledgeUnlatched
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008			210129p20202020xx o u00| u eng d
037			_5BiblioBoard
245	0	2	_aA Diffusion Hydrodynamic Model _cPrasada Rao, Theodore V. Hromadka, Chung-Cheng Yen.
020			_a9781839628191
024	8		_ahttps://doi.org/10.5772/intechopen.90224
029	1		_ahttps://library.biblioboard.com/ext/api/media/47d3a87f-4f61-400a-a2b8-c5633233c43b/assets/thumbnail.jpg
040			_aScCtBLL _cScCtBLL
100	1		_aRao, Prasada _eauthor.
506	0		_aAccess copy available to the general public. _fUnrestricted _2star
700	1		_aHromadka, Theodore V. _eauthor.
700	1		_aYen, Chung-Cheng _eauthor.
264		1	_bIntechOpen,
300			_a1 online resource (1 p.)
520			_aThe Diffusion Hydrodynamic Model (DHM), as presented in the 1987 USGS publication, was one of the first computational fluid dynamics computational programs based on the groundwater program MODFLOW, which evolved into the control volume modeling approach. Over the following decades, others developed similar computational programs that either used the methodology and approaches presented in the DHM directly or were its extensions that included additional components and capacities. Our goal is to demonstrate that the DHM, which was developed in an age preceding computer graphics/visualization tools, is as robust as any of the popular models that are currently used. We thank the USGS for their approval and permission to use the content from the earlier USGS report.
588	0		_aDescription based on print version record.
590			_aIntechOpen Engineering 2019 - 2021
650		7	_aScience / Mechanics / Hydrodynamics _2bisacsh
650		0	_aScience
655		0	_aElectronic books.
758			_iIs found in: _aKnowledge Unlatched _1https://openresearchlibrary.org/module/2774bc74-146a-484f-a7ba-ab1d6a09bbfb
856	4	0	_uhttps://openresearchlibrary.org/content/47d3a87f-4f61-400a-a2b8-c5633233c43b _zView this content on Open Research Library. _70
999			_c32536 _d32536