Effects of electromagnetic radiation on the Q of quartz resonators
The quartz resonator Q with aluminum electrodes was studied with respect to its fundamental thickness shear mode frequency and its viscoelastic, viscopiezoelectric, and viscopiezoelectromagnetic behaviors. The governing equations for viscoelasticity, viscopiezoelectricity, and viscopiezoelectromagne...
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| Veröffentlicht in: | IEEE transactions on ultrasonics, ferroelectrics, and frequency control ferroelectrics, and frequency control, 2009-02, Vol.56 (2), p.353-360 |
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| description | The quartz resonator Q with aluminum electrodes was studied with respect to its fundamental thickness shear mode frequency and its viscoelastic, viscopiezoelectric, and viscopiezoelectromagnetic behaviors. The governing equations for viscoelasticity, viscopiezoelectricity, and viscopiezoelectromagnetism were implemented for an AT-cut quartz resonator. To simulate the radiation conditions at infinity for the viscopiezoelectromagnetic model, perfectly matched layers over a surface enclosing the resonator were implemented to absorb all incident electromagnetic radiation. The shape of the radiation spectrum of a 5.6 MHz AT-cut quartz resonator was found to compare relatively well the measured results by Campbell and Weber. The mesa-plate resonator was studied for a frequency range of 1.4 GHz to 3.4 GHz. The resonator Q was determined to be influenced predominantly by the quartz viscoelasticity; however at frequencies greater than 2.3 GHz, the quartz electromagnetic radiation had an increasingly significant effect on the resonator Q. At 3.4 GHz, the electromagnetic radiation accounted for about 14% of the loss in resonator Q. At frequencies less than 2 GHz, the calculated resonator Q compared well with the intrinsic Q x provided by the formula Q x = 16 times 10 6 /f where f was in MHz. At frequencies higher than 2.3 GHz, the aluminum electrodes had significant effects on the resonator Q. At 3.4 GHz, the electromagnetic radiation loss in the electrodes was an order of magnitude greater than their viscoelastic loss; hence, the vibrating aluminum electrodes became an efficient emitter of electromagnetic waves. The effects of electrical resistance in both the electrodes and quartz were determined to be negligible. |
| doi_str_mv | 10.1109/TUFFC.2009.1044 |
| format | Article |
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The governing equations for viscoelasticity, viscopiezoelectricity, and viscopiezoelectromagnetism were implemented for an AT-cut quartz resonator. To simulate the radiation conditions at infinity for the viscopiezoelectromagnetic model, perfectly matched layers over a surface enclosing the resonator were implemented to absorb all incident electromagnetic radiation. The shape of the radiation spectrum of a 5.6 MHz AT-cut quartz resonator was found to compare relatively well the measured results by Campbell and Weber. The mesa-plate resonator was studied for a frequency range of 1.4 GHz to 3.4 GHz. The resonator Q was determined to be influenced predominantly by the quartz viscoelasticity; however at frequencies greater than 2.3 GHz, the quartz electromagnetic radiation had an increasingly significant effect on the resonator Q. At 3.4 GHz, the electromagnetic radiation accounted for about 14% of the loss in resonator Q. At frequencies less than 2 GHz, the calculated resonator Q compared well with the intrinsic Q x provided by the formula Q x = 16 times 10 6 /f where f was in MHz. At frequencies higher than 2.3 GHz, the aluminum electrodes had significant effects on the resonator Q. At 3.4 GHz, the electromagnetic radiation loss in the electrodes was an order of magnitude greater than their viscoelastic loss; hence, the vibrating aluminum electrodes became an efficient emitter of electromagnetic waves. The effects of electrical resistance in both the electrodes and quartz were determined to be negligible.</description><identifier>ISSN: 0885-3010</identifier><identifier>EISSN: 1525-8955</identifier><identifier>DOI: 10.1109/TUFFC.2009.1044</identifier><identifier>PMID: 19251522</identifier><identifier>CODEN: ITUCER</identifier><language>eng</language><publisher>New York, NY: IEEE</publisher><subject>Acoustic wave devices, piezoelectric and piezoresistive devices ; Acoustics ; Aluminum ; Applied sciences ; Circuit properties ; Elasticity ; Electric, optical and optoelectronic circuits ; Electrodes ; Electromagnetic modeling ; Electromagnetic radiation ; Electromagnetism ; Electronics ; Equations ; Exact sciences and technology ; Frequency ; Fundamental areas of phenomenology (including applications) ; General equipment and techniques ; H infinity control ; Instruments, apparatus, components and techniques common to several branches of physics and astronomy ; Mathematical models ; Microwave circuits, microwave integrated circuits, microwave transmission lines, submillimeter wave circuits ; Physics ; Quartz ; Resonators ; Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices ; Shape measurement ; Shear ; Transducers ; Transduction; acoustical devices for the generation and reproduction of sound ; Viscoelasticity ; Viscosity</subject><ispartof>IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 2009-02, Vol.56 (2), p.353-360</ispartof><rights>2009 INIST-CNRS</rights><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. (IEEE) 2009</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c435t-217401fc848da982a56dbeca9a5c374d97ddbeca809c4439dc1edfc6662eba8d3</citedby><cites>FETCH-LOGICAL-c435t-217401fc848da982a56dbeca9a5c374d97ddbeca809c4439dc1edfc6662eba8d3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://ieeexplore.ieee.org/document/4787187$$EHTML$$P50$$Gieee$$H</linktohtml><link.rule.ids>314,776,780,792,27903,27904,54736</link.rule.ids><linktorsrc>$$Uhttps://ieeexplore.ieee.org/document/4787187$$EView_record_in_IEEE$$FView_record_in_$$GIEEE</linktorsrc><backlink>$$Uhttp://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=21338428$$DView record in Pascal Francis$$Hfree_for_read</backlink><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/19251522$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Yook-kong Yong</creatorcontrib><creatorcontrib>Patel, M.</creatorcontrib><creatorcontrib>Vig, J.</creatorcontrib><creatorcontrib>Ballato, A.</creatorcontrib><title>Effects of electromagnetic radiation on the Q of quartz resonators</title><title>IEEE transactions on ultrasonics, ferroelectrics, and frequency control</title><addtitle>T-UFFC</addtitle><addtitle>IEEE Trans Ultrason Ferroelectr Freq Control</addtitle><description>The quartz resonator Q with aluminum electrodes was studied with respect to its fundamental thickness shear mode frequency and its viscoelastic, viscopiezoelectric, and viscopiezoelectromagnetic behaviors. The governing equations for viscoelasticity, viscopiezoelectricity, and viscopiezoelectromagnetism were implemented for an AT-cut quartz resonator. To simulate the radiation conditions at infinity for the viscopiezoelectromagnetic model, perfectly matched layers over a surface enclosing the resonator were implemented to absorb all incident electromagnetic radiation. The shape of the radiation spectrum of a 5.6 MHz AT-cut quartz resonator was found to compare relatively well the measured results by Campbell and Weber. The mesa-plate resonator was studied for a frequency range of 1.4 GHz to 3.4 GHz. The resonator Q was determined to be influenced predominantly by the quartz viscoelasticity; however at frequencies greater than 2.3 GHz, the quartz electromagnetic radiation had an increasingly significant effect on the resonator Q. At 3.4 GHz, the electromagnetic radiation accounted for about 14% of the loss in resonator Q. At frequencies less than 2 GHz, the calculated resonator Q compared well with the intrinsic Q x provided by the formula Q x = 16 times 10 6 /f where f was in MHz. At frequencies higher than 2.3 GHz, the aluminum electrodes had significant effects on the resonator Q. At 3.4 GHz, the electromagnetic radiation loss in the electrodes was an order of magnitude greater than their viscoelastic loss; hence, the vibrating aluminum electrodes became an efficient emitter of electromagnetic waves. The effects of electrical resistance in both the electrodes and quartz were determined to be negligible.</description><subject>Acoustic wave devices, piezoelectric and piezoresistive devices</subject><subject>Acoustics</subject><subject>Aluminum</subject><subject>Applied sciences</subject><subject>Circuit properties</subject><subject>Elasticity</subject><subject>Electric, optical and optoelectronic circuits</subject><subject>Electrodes</subject><subject>Electromagnetic modeling</subject><subject>Electromagnetic radiation</subject><subject>Electromagnetism</subject><subject>Electronics</subject><subject>Equations</subject><subject>Exact sciences and technology</subject><subject>Frequency</subject><subject>Fundamental areas of phenomenology (including applications)</subject><subject>General equipment and techniques</subject><subject>H infinity control</subject><subject>Instruments, apparatus, components and techniques common to several branches of physics and astronomy</subject><subject>Mathematical models</subject><subject>Microwave circuits, microwave integrated circuits, microwave transmission lines, submillimeter wave circuits</subject><subject>Physics</subject><subject>Quartz</subject><subject>Resonators</subject><subject>Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices</subject><subject>Shape measurement</subject><subject>Shear</subject><subject>Transducers</subject><subject>Transduction; acoustical devices for the generation and reproduction of sound</subject><subject>Viscoelasticity</subject><subject>Viscosity</subject><issn>0885-3010</issn><issn>1525-8955</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2009</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNqF0c1LIzEYB-CwKGt197wHQQZBPU3N5yQ5aml1QVgW2nNIk3d0ZDrRZOagf73pBwoeFAJJyJOXN_kh9IfgMSFYX84Xs9lkTDHWY4I5_4FGRFBRKi3EHhphpUTJMMEH6DClR4wJ55r-RAdEU5EhHaHraV2D61MR6gLavIphZe876BtXROsb2zehK_LoH6D4v1bPg439axEhhc72IaZfaL-2bYLfu_kILWbT-eS2vPt383dydVc6zkRfUiI5JrVTXHmrFbWi8ktwVlvhmOReS7_ZK6wd50x7R8DXrqoqCkurPDtCF9u6TzE8D5B6s2qSg7a1HYQhGSVF_gKsdZbnX8qq0lIKVn0LGRdKcCwzPP0EH8MQu_xco4SShONNtcstcjGkFKE2T7FZ2fhiCDbruMwmLrOOy6zjyjdOdmWH5Qr8h9_lk8HZDtjkbFtH27kmvTtKGFOcquyOt64BgPdjLnNrSrI3uiSlHg</recordid><startdate>20090201</startdate><enddate>20090201</enddate><creator>Yook-kong Yong</creator><creator>Patel, M.</creator><creator>Vig, J.</creator><creator>Ballato, A.</creator><general>IEEE</general><general>Institute of Electrical and Electronics Engineers</general><general>The Institute of Electrical and Electronics Engineers, Inc. (IEEE)</general><scope>97E</scope><scope>RIA</scope><scope>RIE</scope><scope>IQODW</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SP</scope><scope>7U5</scope><scope>8FD</scope><scope>F28</scope><scope>FR3</scope><scope>L7M</scope><scope>7QF</scope><scope>JG9</scope><scope>7X8</scope></search><sort><creationdate>20090201</creationdate><title>Effects of electromagnetic radiation on the Q of quartz resonators</title><author>Yook-kong Yong ; Patel, M. ; Vig, J. ; Ballato, A.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c435t-217401fc848da982a56dbeca9a5c374d97ddbeca809c4439dc1edfc6662eba8d3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2009</creationdate><topic>Acoustic wave devices, piezoelectric and piezoresistive devices</topic><topic>Acoustics</topic><topic>Aluminum</topic><topic>Applied sciences</topic><topic>Circuit properties</topic><topic>Elasticity</topic><topic>Electric, optical and optoelectronic circuits</topic><topic>Electrodes</topic><topic>Electromagnetic modeling</topic><topic>Electromagnetic radiation</topic><topic>Electromagnetism</topic><topic>Electronics</topic><topic>Equations</topic><topic>Exact sciences and technology</topic><topic>Frequency</topic><topic>Fundamental areas of phenomenology (including applications)</topic><topic>General equipment and techniques</topic><topic>H infinity control</topic><topic>Instruments, apparatus, components and techniques common to several branches of physics and astronomy</topic><topic>Mathematical models</topic><topic>Microwave circuits, microwave integrated circuits, microwave transmission lines, submillimeter wave circuits</topic><topic>Physics</topic><topic>Quartz</topic><topic>Resonators</topic><topic>Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices</topic><topic>Shape measurement</topic><topic>Shear</topic><topic>Transducers</topic><topic>Transduction; acoustical devices for the generation and reproduction of sound</topic><topic>Viscoelasticity</topic><topic>Viscosity</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Yook-kong Yong</creatorcontrib><creatorcontrib>Patel, M.</creatorcontrib><creatorcontrib>Vig, J.</creatorcontrib><creatorcontrib>Ballato, A.</creatorcontrib><collection>IEEE All-Society Periodicals Package (ASPP) 2005-present</collection><collection>IEEE All-Society Periodicals Package (ASPP) 1998-Present</collection><collection>IEEE Electronic Library (IEL)</collection><collection>Pascal-Francis</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Electronics & Communications Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>Technology Research Database</collection><collection>ANTE: Abstracts in New Technology & Engineering</collection><collection>Engineering Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>Aluminium Industry Abstracts</collection><collection>Materials Research Database</collection><collection>MEDLINE - Academic</collection><jtitle>IEEE transactions on ultrasonics, ferroelectrics, and frequency control</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Yook-kong Yong</au><au>Patel, M.</au><au>Vig, J.</au><au>Ballato, A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Effects of electromagnetic radiation on the Q of quartz resonators</atitle><jtitle>IEEE transactions on ultrasonics, ferroelectrics, and frequency control</jtitle><stitle>T-UFFC</stitle><addtitle>IEEE Trans Ultrason Ferroelectr Freq Control</addtitle><date>2009-02-01</date><risdate>2009</risdate><volume>56</volume><issue>2</issue><spage>353</spage><epage>360</epage><pages>353-360</pages><issn>0885-3010</issn><eissn>1525-8955</eissn><coden>ITUCER</coden><abstract>The quartz resonator Q with aluminum electrodes was studied with respect to its fundamental thickness shear mode frequency and its viscoelastic, viscopiezoelectric, and viscopiezoelectromagnetic behaviors. The governing equations for viscoelasticity, viscopiezoelectricity, and viscopiezoelectromagnetism were implemented for an AT-cut quartz resonator. To simulate the radiation conditions at infinity for the viscopiezoelectromagnetic model, perfectly matched layers over a surface enclosing the resonator were implemented to absorb all incident electromagnetic radiation. The shape of the radiation spectrum of a 5.6 MHz AT-cut quartz resonator was found to compare relatively well the measured results by Campbell and Weber. The mesa-plate resonator was studied for a frequency range of 1.4 GHz to 3.4 GHz. The resonator Q was determined to be influenced predominantly by the quartz viscoelasticity; however at frequencies greater than 2.3 GHz, the quartz electromagnetic radiation had an increasingly significant effect on the resonator Q. At 3.4 GHz, the electromagnetic radiation accounted for about 14% of the loss in resonator Q. At frequencies less than 2 GHz, the calculated resonator Q compared well with the intrinsic Q x provided by the formula Q x = 16 times 10 6 /f where f was in MHz. At frequencies higher than 2.3 GHz, the aluminum electrodes had significant effects on the resonator Q. At 3.4 GHz, the electromagnetic radiation loss in the electrodes was an order of magnitude greater than their viscoelastic loss; hence, the vibrating aluminum electrodes became an efficient emitter of electromagnetic waves. The effects of electrical resistance in both the electrodes and quartz were determined to be negligible.</abstract><cop>New York, NY</cop><pub>IEEE</pub><pmid>19251522</pmid><doi>10.1109/TUFFC.2009.1044</doi><tpages>8</tpages></addata></record> |
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| ispartof | IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 2009-02, Vol.56 (2), p.353-360 |
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| subjects | Acoustic wave devices, piezoelectric and piezoresistive devices Acoustics Aluminum Applied sciences Circuit properties Elasticity Electric, optical and optoelectronic circuits Electrodes Electromagnetic modeling Electromagnetic radiation Electromagnetism Electronics Equations Exact sciences and technology Frequency Fundamental areas of phenomenology (including applications) General equipment and techniques H infinity control Instruments, apparatus, components and techniques common to several branches of physics and astronomy Mathematical models Microwave circuits, microwave integrated circuits, microwave transmission lines, submillimeter wave circuits Physics Quartz Resonators Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Shape measurement Shear Transducers Transduction acoustical devices for the generation and reproduction of sound Viscoelasticity Viscosity |
| title | Effects of electromagnetic radiation on the Q of quartz resonators |
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