File:STUDY OF MATERIAL AND PARAMETER IMPACTS ON THE PERFORMANCE OF A SIMPLE PARALLEL PLATE CAPACITOR WITH SUPER DIELECTRIC MATERIALS (IA studyofmateriala1094563498).pdf
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STUDY OF MATERIAL AND PARAMETER IMPACTS ON THE PERFORMANCE OF A SIMPLE PARALLEL PLATE CAPACITOR WITH SUPER DIELECTRIC MATERIALS
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| Author |
Roman, Alexander J. |
| Title |
STUDY OF MATERIAL AND PARAMETER IMPACTS ON THE PERFORMANCE OF A SIMPLE PARALLEL PLATE CAPACITOR WITH SUPER DIELECTRIC MATERIALS |
| Publisher |
Monterey, CA; Naval Postgraduate School |
| Description |
This study explored the impact of the materials employed, particularly electrode material, on the performance of Novel Paradigm Supercapacitors (NPS). The main experimental focus was on the impacts of changing the identity of the electrode materials in Novel Paradigm Supercapacitors employing Distilled Deionized water (DI) or DI with 3.5 wt % dissolved NaCl. In sum, it was determined that i) some metals too easily corrode in this application (e.g., silver and lead) to be functional for more than a few hours, ii) titanium is an excellent electrode material that corrodes very slowly and the corrosion layer has an impact on performance, and iii) conductive carbon of any type is superior to all other materials in terms of net energy storage capability. The study also served the purpose of testing the Super Dielectric Material Theory (SDM-Theory). The main thrust of the \"theory\" component was to test the general SDM model of dielectrics against the standard model using appropriately designed experiments, specifically, experiments designed to measure the impact of dielectric material “outside” the volume between the electrodes. Traditional theory indicates the material outside the capacitor has no possible impact, whereas SDM theory says it can have a very significant impact. Results were only consistent with SDM theory. Subjects: capacitor; dielectric; SDM; novel paradigm supercapacitors; supercapacitors |
| Language | English |
| Publication date | September 2019 |
| Current location |
IA Collections: navalpostgraduateschoollibrary; fedlink |
| Accession number |
studyofmateriala1094563498 |
| Source | |
| Permission (Reusing this file) |
This publication is a work of the U.S. Government as defined in Title 17, United States Code, Section 101. Copyright protection is not available for this work in the United States. |
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This work is in the public domain in the United States because it is a work prepared by an officer or employee of the United States Government as part of that person’s official duties under the terms of Title 17, Chapter 1, Section 105 of the US Code.
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| This file has been identified as being free of known restrictions under copyright law, including all related and neighboring rights. | ||
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| Date/Time | Thumbnail | Dimensions | User | Comment | |
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| current | 23:37, 24 July 2020 |  | 1,275 × 1,650, 122 pages (5.61 MB) | Fæ (talk | contribs) | FEDLINK - United States Federal Collection studyofmateriala1094563498 (User talk:Fæ/IA books#Fork8) (batch 1993-2020 #28497) |
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