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Observing Behavior of Fluid Flow thr...
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Rochester Institute of Technology.
Observing Behavior of Fluid Flow through Carbon Nanotube Arrays.
紀錄類型:
書目-語言資料,手稿 : Monograph/item
正題名/作者:
Observing Behavior of Fluid Flow through Carbon Nanotube Arrays./
作者:
Jensen, Anna T.
面頁冊數:
1 online resource (100 pages)
附註:
Source: Masters Abstracts International, Volume: 56-03.
Contained By:
Masters Abstracts International56-03(E).
標題:
Nanotechnology. -
電子資源:
click for full text (PQDT)
ISBN:
9781369470505
Observing Behavior of Fluid Flow through Carbon Nanotube Arrays.
Jensen, Anna T.
Observing Behavior of Fluid Flow through Carbon Nanotube Arrays.
- 1 online resource (100 pages)
Source: Masters Abstracts International, Volume: 56-03.
Thesis (M.S.)
Includes bibliographical references
This work establishes a platform technique for visualizing fluid transport through Anoidisc Alumina Oxide (AAO) membranes, which can be applied to Carbon Nanotube (CNT) arrays, and allow for the testing of the effects of other parameters on flow. Arrays of CNTs have shown significant promise for delivering biomolecules into cells with high efficiency while maintaining cell viability. In these applications, biomolecules flow through CNT arrays manufactured in our lab using Template-Based Chemical Vapor Deposition. By culturing cells on the opposite side of the array, they can be used to transfect biomolecules into cells. In this research, it was discovered that the transfection rate was dependent on the type of biomolecule being delivered into the cells. It was also inferred that the number of CNTs the cells covered would affect the transfection rate. In order to characterize flow through the CNT arrays, an experiment was designed and conducted to test the effect of changing the number of active CNTs. Preliminary testing showed the occurrence of an unknown error in the CNT array manufacturing process which prevented material from flowing through the CNT arrays. As a result, the study was modified to characterize flow through AAO membranes, which serve as the template for the CNTs. To accomplish this, a flow device was developed which restricted flow to a predefined circular area. Three different diameters were tested 6 mm, 4 mm, and 2 mm. Flow data was taken using fluorescent dye, as it diffused through the AAO into a volume of water on the opposite side, fluorescent intensity would increase. This data was plotted against time and used to model flow for the three tested diameters. The results indicated that the total time for diffusion increased as the diameters decreased. However, the relationship between the number of exposed pores and the flow time were not directly related, meaning the amount of flow through one pore changes with the total number of exposed pores. Testing was also conducted regarding the development of a flow device designed with two distinct flow inlets to the CNT array. This was done to determine the future feasibility of administering two distinct solutions into groups of cells. It was concluded that these devices could successfully be used for that purpose.
Electronic reproduction.
Ann Arbor, Mich. :
ProQuest,
2018
Mode of access: World Wide Web
ISBN: 9781369470505Subjects--Topical Terms:
557660
Nanotechnology.
Index Terms--Genre/Form:
554714
Electronic books.
Observing Behavior of Fluid Flow through Carbon Nanotube Arrays.
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This work establishes a platform technique for visualizing fluid transport through Anoidisc Alumina Oxide (AAO) membranes, which can be applied to Carbon Nanotube (CNT) arrays, and allow for the testing of the effects of other parameters on flow. Arrays of CNTs have shown significant promise for delivering biomolecules into cells with high efficiency while maintaining cell viability. In these applications, biomolecules flow through CNT arrays manufactured in our lab using Template-Based Chemical Vapor Deposition. By culturing cells on the opposite side of the array, they can be used to transfect biomolecules into cells. In this research, it was discovered that the transfection rate was dependent on the type of biomolecule being delivered into the cells. It was also inferred that the number of CNTs the cells covered would affect the transfection rate. In order to characterize flow through the CNT arrays, an experiment was designed and conducted to test the effect of changing the number of active CNTs. Preliminary testing showed the occurrence of an unknown error in the CNT array manufacturing process which prevented material from flowing through the CNT arrays. As a result, the study was modified to characterize flow through AAO membranes, which serve as the template for the CNTs. To accomplish this, a flow device was developed which restricted flow to a predefined circular area. Three different diameters were tested 6 mm, 4 mm, and 2 mm. Flow data was taken using fluorescent dye, as it diffused through the AAO into a volume of water on the opposite side, fluorescent intensity would increase. This data was plotted against time and used to model flow for the three tested diameters. The results indicated that the total time for diffusion increased as the diameters decreased. However, the relationship between the number of exposed pores and the flow time were not directly related, meaning the amount of flow through one pore changes with the total number of exposed pores. Testing was also conducted regarding the development of a flow device designed with two distinct flow inlets to the CNT array. This was done to determine the future feasibility of administering two distinct solutions into groups of cells. It was concluded that these devices could successfully be used for that purpose.
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