A study on the thermal aging characteristics of an electro-osmotic pump using a liquid crystal polymer as a packaging material

The generation of bubbles due to the poor barrier property of packaging materials with regard to gas or water permeability can be detrimental to the performance and stability of electro-osmotic (EO) pumps, as their lifetime decreases with the increase in the bubble volume. Water vapor transmission r...

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Published in	Macromolecular research Vol. 31; no. 12; pp. 1125 - 1134
Main Authors	Kim, Jae Hong, Hwang, Yu Hee, Lee, Mi Hyun, Chang, Young Wook, Song, Yong Chul, Lee, Do Kyung, Kim, Chang Jung
Format	Journal Article
Language	English
Published	Seoul The Polymer Society of Korea 01.12.2023 Springer Springer Nature B.V 한국고분자학회
Subjects	Accelerated aging tests Accelerated tests Activation energy Aging Bubbles Butyl rubber Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Complex Fluids and Microfluidics Crystallography Elastomers Emission analysis Field emission microscopy Liquid crystal polymers Liquid crystals Nanochemistry Nanotechnology Packaging Permeability Physical Chemistry Polycarbonate resins Polycarbonates Polymer industry Polymer liquid crystals Polymer Sciences Pumps Soft and Granular Matter Stability Thermal degradation Thermogravimetric analysis Water vapor X-ray spectroscopy 고분자공학 Electro-osmotic pump Accelerated thermal aging test Liquid crystal polymer Arrhenius model Water vapor transmission rate
Online Access	Get full text
ISSN	1598-5032 2092-7673
DOI	10.1007/s13233-023-00211-z

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Abstract	The generation of bubbles due to the poor barrier property of packaging materials with regard to gas or water permeability can be detrimental to the performance and stability of electro-osmotic (EO) pumps, as their lifetime decreases with the increase in the bubble volume. Water vapor transmission rate tests were conducted on three different polymers, butyl rubber, polycarbonate, and liquid crystal polymer (LCP), to develop a suitable packaging material for EO pumps. LCP showed the most pronounced barrier performance for water vapor permeability before and after an accelerated thermal aging test. Field emission scanning electron microscopy, energy-dispersive X-ray spectroscopy, thermogravimetric analysis, and X-ray diffraction measurement were performed, and it was found that LCP had no significant microstructural, compositional, and crystallographic changes, and thermal degradation after the accelerated thermal aging test. An EO pump was assembled using LCP cases, and it was then tested under various aging temperatures (50 °C, 60 °C, 70 °C, and 80 °C). Moreover, the pump’s thermal aging characteristics were analyzed using the Arrhenius model. Based on the obtained results, the reaction rate constant ( k ) rapidly increased with the increase in the aging temperature, and the calculated value of the activation energy ( E a ) was 69.2 kJ/mol. Graphical abstract In electro-osmotic (EO) pumps, the generation of bubbles due to the poor barrier property of packaging materials when it comes to gas or water permeability can be very detrimental with regard to the performance and stability of the pumps, whose lifetime usually decreases with the increase in the bubble volume. In this study, aiming at solving the above-mentioned problems, we performed water vapor transmission rate (WVTR) tests on three different polymers, butyl rubber (BR), polycarbonate (PC), and liquid crystal polymer (LCP), so as to develop a suitable packaging material for EO pumps. Based on the tests performed on the EO pump built with LCP cases, LCP is found to be a very reliable and promising packaging material for EO pumps. Moreover, the pump’s thermal aging characteristics were analyzed using Arrhenius model.
AbstractList	The generation of bubbles due to the poor barrier property of packaging materials with regard to gas or water permeability can be detrimental to the performance and stability of electro-osmotic (EO) pumps, as their lifetime decreases with the increase in the bubble volume. Water vapor transmission rate tests were conducted on three different polymers, butyl rubber, polycarbonate, and liquid crystal polymer (LCP), to develop a suitable packaging material for EO pumps. LCP showed the most pronounced barrier performance for water vapor permeability before and after an accelerated thermal aging test. Field emission scanning electron microscopy, energy-dispersive X-ray spectroscopy, thermogravimetric analysis, and X-ray diffraction measurement were performed, and it was found that LCP had no significant microstructural, compositional, and crystallographic changes, and thermal degradation after the accelerated thermal aging test. An EO pump was assembled using LCP cases, and it was then tested under various aging temperatures (50 °C, 60 °C, 70 °C, and 80 °C). Moreover, the pump’s thermal aging characteristics were analyzed using the Arrhenius model. Based on the obtained results, the reaction rate constant (k) rapidly increased with the increase in the aging temperature, and the calculated value of the activation energy (Ea) was 69.2 kJ/mol.In electro-osmotic (EO) pumps, the generation of bubbles due to the poor barrier property of packaging materials when it comes to gas or water permeability can be very detrimental with regard to the performance and stability of the pumps, whose lifetime usually decreases with the increase in the bubble volume. In this study, aiming at solving the above-mentioned problems, we performed water vapor transmission rate (WVTR) tests on three different polymers, butyl rubber (BR), polycarbonate (PC), and liquid crystal polymer (LCP), so as to develop a suitable packaging material for EO pumps. Based on the tests performed on the EO pump built with LCP cases, LCP is found to be a very reliable and promising packaging material for EO pumps. Moreover, the pump’s thermal aging characteristics were analyzed using Arrhenius model. The generation of bubbles due to the poor barrier property of packaging materials with regard to gas or water permeability can be detrimental to the performance and stability of electro-osmotic (EO) pumps, as their lifetime decreases with the increase in the bubble volume. Water vapor transmission rate tests were conducted on three different polymers, butyl rubber, polycarbonate, and liquid crystal polymer (LCP), to develop a suitable packaging material for EO pumps. LCP showed the most pronounced barrier performance for water vapor permeability before and after an accelerated thermal aging test. Field emission scanning electron microscopy, energy-dispersive X-ray spectroscopy, thermogravimetric analysis, and X-ray diffraction measurement were performed, and it was found that LCP had no significant microstructural, compositional, and crystallographic changes, and thermal degradation after the accelerated thermal aging test. An EO pump was assembled using LCP cases, and it was then tested under various aging temperatures (50 °C, 60 °C, 70 °C, and 80 °C). Moreover, the pump's thermal aging characteristics were analyzed using the Arrhenius model. Based on the obtained results, the reaction rate constant (k) rapidly increased with the increase in the aging temperature, and the calculated value of the activation energy (E.sub.a) was 69.2 kJ/mol. Graphical abstract In electro-osmotic (EO) pumps, the generation of bubbles due to the poor barrier property of packaging materials when it comes to gas or water permeability can be very detrimental with regard to the performance and stability of the pumps, whose lifetime usually decreases with the increase in the bubble volume. In this study, aiming at solving the above-mentioned problems, we performed water vapor transmission rate (WVTR) tests on three different polymers, butyl rubber (BR), polycarbonate (PC), and liquid crystal polymer (LCP), so as to develop a suitable packaging material for EO pumps. Based on the tests performed on the EO pump built with LCP cases, LCP is found to be a very reliable and promising packaging material for EO pumps. Moreover, the pump's thermal aging characteristics were analyzed using Arrhenius model. The generation of bubbles due to the poor barrier property of packaging materials with regard to gas or water permeability can be detrimental to the performance and stability of electro-osmotic (EO) pumps, as their lifetime decreases with the increase in the bubble volume. Water vapor transmission rate tests were conducted on three different polymers, butyl rubber, polycarbonate, and liquid crystal polymer (LCP), to develop a suitable packaging material for EO pumps. LCP showed the most pronounced barrier performance for water vapor permeability before and after an accelerated thermal aging test. Field emission scanning electron microscopy, energy-dispersive X-ray spectroscopy, thermogravimetric analysis, and X-ray diffraction measurement were performed, and it was found that LCP had no significant microstructural, compositional, and crystallographic changes, and thermal degradation after the accelerated thermal aging test. An EO pump was assembled using LCP cases, and it was then tested under various aging temperatures (50 °C, 60 °C, 70 °C, and 80 °C). Moreover, the pump’s thermal aging characteristics were analyzed using the Arrhenius model. Based on the obtained results, the reaction rate constant ( k ) rapidly increased with the increase in the aging temperature, and the calculated value of the activation energy ( E a ) was 69.2 kJ/mol. Graphical abstract In electro-osmotic (EO) pumps, the generation of bubbles due to the poor barrier property of packaging materials when it comes to gas or water permeability can be very detrimental with regard to the performance and stability of the pumps, whose lifetime usually decreases with the increase in the bubble volume. In this study, aiming at solving the above-mentioned problems, we performed water vapor transmission rate (WVTR) tests on three different polymers, butyl rubber (BR), polycarbonate (PC), and liquid crystal polymer (LCP), so as to develop a suitable packaging material for EO pumps. Based on the tests performed on the EO pump built with LCP cases, LCP is found to be a very reliable and promising packaging material for EO pumps. Moreover, the pump’s thermal aging characteristics were analyzed using Arrhenius model. The generation of bubbles due to the poor barrier property of packaging materials with regard to gas or water permeability can be detrimental to the performance and stability of electro-osmotic (EO) pumps, as their lifetime decreases with the increase in the bubble volume. Water vapor transmission rate tests were conducted on three different polymers, butyl rubber, polycarbonate, and liquid crystal polymer (LCP), to develop a suitable packaging material for EO pumps. LCP showed the most pronounced barrier performance for water vapor permeability before and after an accelerated thermal aging test. Field emission scanning electron microscopy, energy-dispersive X-ray spectroscopy, thermogravimetric analysis, and X-ray diffraction measurement were performed, and it was found that LCP had no significant microstructural, compositional, and crystallographic changes, and thermal degradation after the accelerated thermal aging test. An EO pump was assembled using LCP cases, and it was then tested under various aging temperatures (50 °C, 60 °C, 70 °C, and 80 °C). Moreover, the pump’s thermal aging characteristics were analyzed using the Arrhenius model. Based on the obtained results, the reaction rate constant (k) rapidly increased with the increase in the aging temperature, and the calculated value of the activation energy (Ea) was 69.2 kJ/mol. KCI Citation Count: 0
Audience	Academic
Author	Lee, Mi Hyun Hwang, Yu Hee Song, Yong Chul Kim, Chang Jung Lee, Do Kyung Kim, Jae Hong Chang, Young Wook
Author_xml	– sequence: 1 givenname: Jae Hong orcidid: 0000-0001-8700-7923 surname: Kim fullname: Kim, Jae Hong organization: Materials and Components Research Division, EOFLOW – sequence: 2 givenname: Yu Hee surname: Hwang fullname: Hwang, Yu Hee organization: Materials and Components Research Division, EOFLOW – sequence: 3 givenname: Mi Hyun surname: Lee fullname: Lee, Mi Hyun organization: Materials and Components Research Division, EOFLOW – sequence: 4 givenname: Young Wook surname: Chang fullname: Chang, Young Wook organization: Materials and Components Research Division, EOFLOW – sequence: 5 givenname: Yong Chul surname: Song fullname: Song, Yong Chul organization: Materials and Components Research Division, EOFLOW – sequence: 6 givenname: Do Kyung surname: Lee fullname: Lee, Do Kyung organization: Materials and Components Research Division, EOFLOW – sequence: 7 givenname: Chang Jung surname: Kim fullname: Kim, Chang Jung email: kcj@eoflow.com organization: Materials and Components Research Division, EOFLOW
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SubjectTerms	Accelerated aging tests Accelerated tests Activation energy Aging Bubbles Butyl rubber Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Complex Fluids and Microfluidics Crystallography Elastomers Emission analysis Field emission microscopy Liquid crystal polymers Liquid crystals Nanochemistry Nanotechnology Packaging Permeability Physical Chemistry Polycarbonate resins Polycarbonates Polymer industry Polymer liquid crystals Polymer Sciences Pumps Soft and Granular Matter Stability Thermal degradation Thermogravimetric analysis Water vapor X-ray spectroscopy 고분자공학
Title	A study on the thermal aging characteristics of an electro-osmotic pump using a liquid crystal polymer as a packaging material
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