Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications
Research shows that microorganisms play a major role in climate change, but there is a lack of adequate understanding of microbial involvement in climate change and further research is needed for greater understanding. Temperature monitoring lends an insight into the current climatic shifts in Arcti...
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Montana State University - Bozeman, College of Engineering
2020
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ftmontanastateu:oai:scholarworks.montana.edu:1/16744 2023-05-15T13:44:27+02:00 Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications Thomae, Madelyn Ruth Chairperson, Graduate Committee: Stephan Warnat Arctic regions Antarctica 2020 application/pdf https://scholarworks.montana.edu/xmlui/handle/1/16744 en eng Montana State University - Bozeman, College of Engineering https://scholarworks.montana.edu/xmlui/handle/1/16744 Copyright 2020 by Madelyn Ruth Thomae Microorganisms Climatic changes Low temperatures Microelectromechanical systems Thesis 2020 ftmontanastateu 2023-02-25T23:40:30Z Research shows that microorganisms play a major role in climate change, but there is a lack of adequate understanding of microbial involvement in climate change and further research is needed for greater understanding. Temperature monitoring lends an insight into the current climatic shifts in Arctic and Antarctic regions. Currently, satellite monitoring is used to track temperature changes in those regions. To further the understanding of the role microorganisms play in the rising temperatures in those regions, in-situ temperature monitoring is needed. Commercially available temperature probes are high in cost and not well-suited for the harsh environment of Arctic and Antarctic regions. Utilizing micro electromechanical systems technology provides a solution for robust low-cost, low-power sensors that can be designed specifically to operate in harsh environments. Gold resistance temperature devices were designed and fabricated using micro electromechanical systems technology with a high spatial resolution capable of detecting microorganisms in subzero applications. The fabricated temperature sensors were calibrated for subzero use and freezing experiments were done to detect any changes due to impurities in the sample. The gold resistance temperature devices were able to withstand prolonged exposure to the harsh experimental environment and provide an accurate spatial temperature gradient throughout the media. The gold resistance temperature devices had negligible effects due to the self-heating phenomenon common in resistance temperature devices. Additionally, the sensors were able to detect variations in the freezing curve of the media with the inclusion of the bacterial isolate Flavobacterium sp. ANT 11 (accession number GU592435) in DI water samples. Future research should focus on (1) furthering the understanding of the microbial interactions in the cooling curves of different medias and (2) integrating electrical impedance spectroscopy sensors to provide knowledge of what impurities are in the sample ... Thesis Antarc* Antarctic Antarctica Arctic Climate change Montana State University (MSU): ScholarWorks Antarctic Arctic |
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Open Polar |
| collection |
Montana State University (MSU): ScholarWorks |
| op_collection_id |
ftmontanastateu |
| language |
English |
| topic |
Microorganisms Climatic changes Low temperatures Microelectromechanical systems |
| spellingShingle |
Microorganisms Climatic changes Low temperatures Microelectromechanical systems Thomae, Madelyn Ruth Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| topic_facet |
Microorganisms Climatic changes Low temperatures Microelectromechanical systems |
| description |
Research shows that microorganisms play a major role in climate change, but there is a lack of adequate understanding of microbial involvement in climate change and further research is needed for greater understanding. Temperature monitoring lends an insight into the current climatic shifts in Arctic and Antarctic regions. Currently, satellite monitoring is used to track temperature changes in those regions. To further the understanding of the role microorganisms play in the rising temperatures in those regions, in-situ temperature monitoring is needed. Commercially available temperature probes are high in cost and not well-suited for the harsh environment of Arctic and Antarctic regions. Utilizing micro electromechanical systems technology provides a solution for robust low-cost, low-power sensors that can be designed specifically to operate in harsh environments. Gold resistance temperature devices were designed and fabricated using micro electromechanical systems technology with a high spatial resolution capable of detecting microorganisms in subzero applications. The fabricated temperature sensors were calibrated for subzero use and freezing experiments were done to detect any changes due to impurities in the sample. The gold resistance temperature devices were able to withstand prolonged exposure to the harsh experimental environment and provide an accurate spatial temperature gradient throughout the media. The gold resistance temperature devices had negligible effects due to the self-heating phenomenon common in resistance temperature devices. Additionally, the sensors were able to detect variations in the freezing curve of the media with the inclusion of the bacterial isolate Flavobacterium sp. ANT 11 (accession number GU592435) in DI water samples. Future research should focus on (1) furthering the understanding of the microbial interactions in the cooling curves of different medias and (2) integrating electrical impedance spectroscopy sensors to provide knowledge of what impurities are in the sample ... |
| author2 |
Chairperson, Graduate Committee: Stephan Warnat |
| format |
Thesis |
| author |
Thomae, Madelyn Ruth |
| author_facet |
Thomae, Madelyn Ruth |
| author_sort |
Thomae, Madelyn Ruth |
| title |
Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| title_short |
Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| title_full |
Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| title_fullStr |
Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| title_full_unstemmed |
Resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| title_sort |
resistance temperature devices fabricated using micro electromechanical systems technology designed and characterized for low-temperature applications |
| publisher |
Montana State University - Bozeman, College of Engineering |
| publishDate |
2020 |
| url |
https://scholarworks.montana.edu/xmlui/handle/1/16744 |
| op_coverage |
Arctic regions Antarctica |
| geographic |
Antarctic Arctic |
| geographic_facet |
Antarctic Arctic |
| genre |
Antarc* Antarctic Antarctica Arctic Climate change |
| genre_facet |
Antarc* Antarctic Antarctica Arctic Climate change |
| op_relation |
https://scholarworks.montana.edu/xmlui/handle/1/16744 |
| op_rights |
Copyright 2020 by Madelyn Ruth Thomae |
| _version_ |
1766201747527696384 |