Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications
As Lab-on-Chip platforms with micro-and nano-dimensions evolve biosensors using miniaturized and high-sensitivity cantilevers are becoming more attractive. Although these sensors function in non-isothermal situations, computational mathematics generally ignores the temperature. Conversely, biosenso...
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| Format: | Article |
| Language: | English |
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Elsevier
2023-06-01
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| Series: | Kuwait Journal of Science |
| Online Access: | https://journalskuwait.org/kjs/index.php/KJS/article/view/20495 |
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| author | Miranji Katta Sandanalakshmi R |
| author_facet | Miranji Katta Sandanalakshmi R |
| author_sort | Miranji Katta |
| collection | DOAJ |
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As Lab-on-Chip platforms with micro-and nano-dimensions evolve biosensors using miniaturized and high-sensitivity cantilevers are becoming more attractive. Although these sensors function in non-isothermal situations, computational mathematics generally ignores the temperature. Conversely, biosensors can’t be designed with a single-layered cantilever. Yet, in Nano-Electro-Mechanical-Systems, the influence of temperature is more likely to be dominant since the surface-to-volume ratio is higher. In the context of this conclusion, the mathematical modelling comprises temperature and the associated material attributes. This work presents a simple and direct analytical technique for analysing the control of bimetallic cantilevers with NEMS-based sensing and actuation mechanisms. Methodological techniques were used to develop and solve some well-known models of mathematical equations. Parametric analysis data is a major factor in the functioning of all of the other works studied. The findings of FEA comparisons and experiments reveal that the mathematical model's predictions are more than 20% correct.
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| format | Article |
| id | doaj-art-04ee3b68343d4721b0c1929cec010742 |
| institution | OA Journals |
| issn | 2307-4108 2307-4116 |
| language | English |
| publishDate | 2023-06-01 |
| publisher | Elsevier |
| record_format | Article |
| series | Kuwait Journal of Science |
| spelling | doaj-art-04ee3b68343d4721b0c1929cec0107422025-08-20T02:03:36ZengElsevierKuwait Journal of Science2307-41082307-41162023-06-01503B10.48129/kjs.20495Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applicationsMiranji Katta0Sandanalakshmi R1Dept. of Electronics and Communication Engineering, Sir C R Reddy College of Engineering, Eluru, Andhra Pradesh, India - 605014Dept. of Electronics and Communication Engineering, Puducherry Technological University, Pondicherry, India - 605014 As Lab-on-Chip platforms with micro-and nano-dimensions evolve biosensors using miniaturized and high-sensitivity cantilevers are becoming more attractive. Although these sensors function in non-isothermal situations, computational mathematics generally ignores the temperature. Conversely, biosensors can’t be designed with a single-layered cantilever. Yet, in Nano-Electro-Mechanical-Systems, the influence of temperature is more likely to be dominant since the surface-to-volume ratio is higher. In the context of this conclusion, the mathematical modelling comprises temperature and the associated material attributes. This work presents a simple and direct analytical technique for analysing the control of bimetallic cantilevers with NEMS-based sensing and actuation mechanisms. Methodological techniques were used to develop and solve some well-known models of mathematical equations. Parametric analysis data is a major factor in the functioning of all of the other works studied. The findings of FEA comparisons and experiments reveal that the mathematical model's predictions are more than 20% correct. https://journalskuwait.org/kjs/index.php/KJS/article/view/20495 |
| spellingShingle | Miranji Katta Sandanalakshmi R Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications Kuwait Journal of Science |
| title | Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications |
| title_full | Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications |
| title_fullStr | Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications |
| title_full_unstemmed | Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications |
| title_short | Mathematical modelling and analysis of temperature effects in MEMS based bi-metallic cantilever for molecular biosensing applications |
| title_sort | mathematical modelling and analysis of temperature effects in mems based bi metallic cantilever for molecular biosensing applications |
| url | https://journalskuwait.org/kjs/index.php/KJS/article/view/20495 |
| work_keys_str_mv | AT miranjikatta mathematicalmodellingandanalysisoftemperatureeffectsinmemsbasedbimetalliccantileverformolecularbiosensingapplications AT sandanalakshmir mathematicalmodellingandanalysisoftemperatureeffectsinmemsbasedbimetalliccantileverformolecularbiosensingapplications |