Pt/PZT/Pt and Pt/barrier stack etches for MEMS devices in a dual frequency high density plasma reactor
Ion milling has been used in laboratory applications for patterning ferroelectric thin films and noble metal electrodes in Metal/Ferroelectric/Metal stacks. These MFM stacks are used to form several different families of MEMS devices: moving mirrors for optical signal switching applications, for exa...
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| creator | Werbaneth, P. Almerico, J. Jerde, L. Marks, S. Wachtmann, B. |
| description | Ion milling has been used in laboratory applications for patterning ferroelectric thin films and noble metal electrodes in Metal/Ferroelectric/Metal stacks. These MFM stacks are used to form several different families of MEMS devices: moving mirrors for optical signal switching applications, for example, utilize the piezoelectric properties of PZT; varactors, or other tunable circuit elements, depend on the dielectric nonlinearity of PZT and BST. The oxidizing environment encountered during the deposition of these ferroelectric films means that some material capable of resisting oxidation (platinum) or capable of forming an electrically conductive oxide (iridium or ruthenium) must be used as the metal electrode in any metal-ferroelectric-metal (MFM) stack. Its corrosion resistance, electromigration resistance and compatibility with standard IC fabs also make platinum attractive as an interconnect in many other MEMS applications. The physical action of energetic ions (usually argon) can remove surface atoms even when the vapor pressure of the material(s) to be removed is negligibly small. However, when ion milling is used to pattern platinum the removal rate is low (/spl sim/400 /spl Aring//min), the throughput is low, and the tendency is for the etched material to redeposit along the edge of the etch mask, creating veils, or fences, after the etch mask is removed. These residues, being electrically conductive, can lead to yield-limiting defects in finished devices. In this paper we report on MFM and interconnect stack etch results for MEMS applications from a dual frequency high density plasma etch reactor. Platinum and PZT etch rates greater than 100 /spl Aring//min are possible in this reactor at moderate (80/spl deg/C) wafer temperatures using photoresist masks. We can produce good etch profiles with no post-etch residue for MFM stacks like those used for a MEMS-based Atomic Force Microscopy application, for example, which employs a bottom platinum layer 1500 /spl Aring/ thick, 2800 /spl Aring/ of PZT, and a platinum top electrode of 1500 /spl Aring/. We also present production data from a process for etching a platinum/titanium-tungsten (10%/90%) stack for a micromachined mirror device. |
| doi_str_mv | 10.1109/ASMC.2002.1001599 |
| format | Conference Proceeding |
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These MFM stacks are used to form several different families of MEMS devices: moving mirrors for optical signal switching applications, for example, utilize the piezoelectric properties of PZT; varactors, or other tunable circuit elements, depend on the dielectric nonlinearity of PZT and BST. The oxidizing environment encountered during the deposition of these ferroelectric films means that some material capable of resisting oxidation (platinum) or capable of forming an electrically conductive oxide (iridium or ruthenium) must be used as the metal electrode in any metal-ferroelectric-metal (MFM) stack. Its corrosion resistance, electromigration resistance and compatibility with standard IC fabs also make platinum attractive as an interconnect in many other MEMS applications. The physical action of energetic ions (usually argon) can remove surface atoms even when the vapor pressure of the material(s) to be removed is negligibly small. However, when ion milling is used to pattern platinum the removal rate is low (/spl sim/400 /spl Aring//min), the throughput is low, and the tendency is for the etched material to redeposit along the edge of the etch mask, creating veils, or fences, after the etch mask is removed. These residues, being electrically conductive, can lead to yield-limiting defects in finished devices. In this paper we report on MFM and interconnect stack etch results for MEMS applications from a dual frequency high density plasma etch reactor. Platinum and PZT etch rates greater than 100 /spl Aring//min are possible in this reactor at moderate (80/spl deg/C) wafer temperatures using photoresist masks. We can produce good etch profiles with no post-etch residue for MFM stacks like those used for a MEMS-based Atomic Force Microscopy application, for example, which employs a bottom platinum layer 1500 /spl Aring/ thick, 2800 /spl Aring/ of PZT, and a platinum top electrode of 1500 /spl Aring/. We also present production data from a process for etching a platinum/titanium-tungsten (10%/90%) stack for a micromachined mirror device.</description><identifier>ISSN: 1078-8743</identifier><identifier>ISBN: 9780780371583</identifier><identifier>ISBN: 0780371585</identifier><identifier>EISSN: 2376-6697</identifier><identifier>DOI: 10.1109/ASMC.2002.1001599</identifier><language>eng</language><publisher>Piscataway NJ: IEEE</publisher><subject>Applied sciences ; Design. Technologies. Operation analysis. Testing ; Diodes ; Electronics ; Etching ; Exact sciences and technology ; Ferroelectric materials ; Frequency ; Inductors ; Integrated circuits ; Magnetic force microscopy ; Micro- and nanoelectromechanical devices (mems/nems) ; Microelectromechanical devices ; Microelectronic fabrication (materials and surfaces technology) ; Plasma applications ; Plasma density ; Plasma devices ; Platinum ; Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices</subject><ispartof>13th Annual IEEE/SEMI Advanced Semiconductor Manufacturing Conference. Advancing the Science and Technology of Semiconductor Manufacturing. ASMC 2002 (Cat. 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Advancing the Science and Technology of Semiconductor Manufacturing. ASMC 2002 (Cat. No.02CH37259)</title><addtitle>ASMC</addtitle><description>Ion milling has been used in laboratory applications for patterning ferroelectric thin films and noble metal electrodes in Metal/Ferroelectric/Metal stacks. These MFM stacks are used to form several different families of MEMS devices: moving mirrors for optical signal switching applications, for example, utilize the piezoelectric properties of PZT; varactors, or other tunable circuit elements, depend on the dielectric nonlinearity of PZT and BST. The oxidizing environment encountered during the deposition of these ferroelectric films means that some material capable of resisting oxidation (platinum) or capable of forming an electrically conductive oxide (iridium or ruthenium) must be used as the metal electrode in any metal-ferroelectric-metal (MFM) stack. Its corrosion resistance, electromigration resistance and compatibility with standard IC fabs also make platinum attractive as an interconnect in many other MEMS applications. The physical action of energetic ions (usually argon) can remove surface atoms even when the vapor pressure of the material(s) to be removed is negligibly small. However, when ion milling is used to pattern platinum the removal rate is low (/spl sim/400 /spl Aring//min), the throughput is low, and the tendency is for the etched material to redeposit along the edge of the etch mask, creating veils, or fences, after the etch mask is removed. These residues, being electrically conductive, can lead to yield-limiting defects in finished devices. In this paper we report on MFM and interconnect stack etch results for MEMS applications from a dual frequency high density plasma etch reactor. Platinum and PZT etch rates greater than 100 /spl Aring//min are possible in this reactor at moderate (80/spl deg/C) wafer temperatures using photoresist masks. We can produce good etch profiles with no post-etch residue for MFM stacks like those used for a MEMS-based Atomic Force Microscopy application, for example, which employs a bottom platinum layer 1500 /spl Aring/ thick, 2800 /spl Aring/ of PZT, and a platinum top electrode of 1500 /spl Aring/. We also present production data from a process for etching a platinum/titanium-tungsten (10%/90%) stack for a micromachined mirror device.</description><subject>Applied sciences</subject><subject>Design. Technologies. Operation analysis. Testing</subject><subject>Diodes</subject><subject>Electronics</subject><subject>Etching</subject><subject>Exact sciences and technology</subject><subject>Ferroelectric materials</subject><subject>Frequency</subject><subject>Inductors</subject><subject>Integrated circuits</subject><subject>Magnetic force microscopy</subject><subject>Micro- and nanoelectromechanical devices (mems/nems)</subject><subject>Microelectromechanical devices</subject><subject>Microelectronic fabrication (materials and surfaces technology)</subject><subject>Plasma applications</subject><subject>Plasma density</subject><subject>Plasma devices</subject><subject>Platinum</subject><subject>Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices</subject><issn>1078-8743</issn><issn>2376-6697</issn><isbn>9780780371583</isbn><isbn>0780371585</isbn><fulltext>true</fulltext><rsrctype>conference_proceeding</rsrctype><creationdate>2002</creationdate><recordtype>conference_proceeding</recordtype><sourceid>6IE</sourceid><sourceid>RIE</sourceid><recordid>eNpFkM1rAjEQxUM_oGL9A0ovufS4mo_dTXIUsbagVNBeepHZ7GxNu642iQX_-4Za6DDweDOPd_gRcsfZkHNmRuPVYjIUjIkhZ4wXxlyQnpCqzMrSqEsyMEqztFLxQssr0uPJZVrl8oYMQvhgafIiZ8z0SLOMo-XberSMFLqaJleB9w49DRHsJ8Votxhos_d0MV2saI3fzqaD6yjQ-ggtbTx-HbGzJ7p179sU6IKLJ3poIeyAegQb9_6WXDfQBhz8aZ-8Pk7Xk6ds_jJ7noznmeNcx6xhlinFTY2yVKIq0SpZg0xqhLLWYiVyq03OJRMAYKuy0rJGraFIFBSTffJw7j1AsNA2Hjrrwubg3Q78aZN4FEL95u7POYeI_-8zTfkDv79lpA</recordid><startdate>2002</startdate><enddate>2002</enddate><creator>Werbaneth, P.</creator><creator>Almerico, J.</creator><creator>Jerde, L.</creator><creator>Marks, S.</creator><creator>Wachtmann, B.</creator><general>IEEE</general><scope>6IE</scope><scope>6IH</scope><scope>CBEJK</scope><scope>RIE</scope><scope>RIO</scope><scope>IQODW</scope></search><sort><creationdate>2002</creationdate><title>Pt/PZT/Pt and Pt/barrier stack etches for MEMS devices in a dual frequency high density plasma reactor</title><author>Werbaneth, P. ; Almerico, J. ; Jerde, L. ; Marks, S. ; Wachtmann, B.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-i118t-f0c07719de3672b6ec73da36ec927ccceb24c8941302aaacb6b83de88a5599703</frbrgroupid><rsrctype>conference_proceedings</rsrctype><prefilter>conference_proceedings</prefilter><language>eng</language><creationdate>2002</creationdate><topic>Applied sciences</topic><topic>Design. Technologies. Operation analysis. Testing</topic><topic>Diodes</topic><topic>Electronics</topic><topic>Etching</topic><topic>Exact sciences and technology</topic><topic>Ferroelectric materials</topic><topic>Frequency</topic><topic>Inductors</topic><topic>Integrated circuits</topic><topic>Magnetic force microscopy</topic><topic>Micro- and nanoelectromechanical devices (mems/nems)</topic><topic>Microelectromechanical devices</topic><topic>Microelectronic fabrication (materials and surfaces technology)</topic><topic>Plasma applications</topic><topic>Plasma density</topic><topic>Plasma devices</topic><topic>Platinum</topic><topic>Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Werbaneth, P.</creatorcontrib><creatorcontrib>Almerico, J.</creatorcontrib><creatorcontrib>Jerde, L.</creatorcontrib><creatorcontrib>Marks, S.</creatorcontrib><creatorcontrib>Wachtmann, B.</creatorcontrib><collection>IEEE Electronic Library (IEL) Conference Proceedings</collection><collection>IEEE Proceedings Order Plan (POP) 1998-present by volume</collection><collection>IEEE Xplore All Conference Proceedings</collection><collection>IEEE Electronic Library (IEL)</collection><collection>IEEE Proceedings Order Plans (POP) 1998-present</collection><collection>Pascal-Francis</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Werbaneth, P.</au><au>Almerico, J.</au><au>Jerde, L.</au><au>Marks, S.</au><au>Wachtmann, B.</au><format>book</format><genre>proceeding</genre><ristype>CONF</ristype><atitle>Pt/PZT/Pt and Pt/barrier stack etches for MEMS devices in a dual frequency high density plasma reactor</atitle><btitle>13th Annual IEEE/SEMI Advanced Semiconductor Manufacturing Conference. Advancing the Science and Technology of Semiconductor Manufacturing. ASMC 2002 (Cat. No.02CH37259)</btitle><stitle>ASMC</stitle><date>2002</date><risdate>2002</risdate><spage>177</spage><epage>183</epage><pages>177-183</pages><issn>1078-8743</issn><eissn>2376-6697</eissn><isbn>9780780371583</isbn><isbn>0780371585</isbn><abstract>Ion milling has been used in laboratory applications for patterning ferroelectric thin films and noble metal electrodes in Metal/Ferroelectric/Metal stacks. These MFM stacks are used to form several different families of MEMS devices: moving mirrors for optical signal switching applications, for example, utilize the piezoelectric properties of PZT; varactors, or other tunable circuit elements, depend on the dielectric nonlinearity of PZT and BST. The oxidizing environment encountered during the deposition of these ferroelectric films means that some material capable of resisting oxidation (platinum) or capable of forming an electrically conductive oxide (iridium or ruthenium) must be used as the metal electrode in any metal-ferroelectric-metal (MFM) stack. Its corrosion resistance, electromigration resistance and compatibility with standard IC fabs also make platinum attractive as an interconnect in many other MEMS applications. The physical action of energetic ions (usually argon) can remove surface atoms even when the vapor pressure of the material(s) to be removed is negligibly small. However, when ion milling is used to pattern platinum the removal rate is low (/spl sim/400 /spl Aring//min), the throughput is low, and the tendency is for the etched material to redeposit along the edge of the etch mask, creating veils, or fences, after the etch mask is removed. These residues, being electrically conductive, can lead to yield-limiting defects in finished devices. In this paper we report on MFM and interconnect stack etch results for MEMS applications from a dual frequency high density plasma etch reactor. Platinum and PZT etch rates greater than 100 /spl Aring//min are possible in this reactor at moderate (80/spl deg/C) wafer temperatures using photoresist masks. We can produce good etch profiles with no post-etch residue for MFM stacks like those used for a MEMS-based Atomic Force Microscopy application, for example, which employs a bottom platinum layer 1500 /spl Aring/ thick, 2800 /spl Aring/ of PZT, and a platinum top electrode of 1500 /spl Aring/. We also present production data from a process for etching a platinum/titanium-tungsten (10%/90%) stack for a micromachined mirror device.</abstract><cop>Piscataway NJ</cop><pub>IEEE</pub><doi>10.1109/ASMC.2002.1001599</doi><tpages>7</tpages></addata></record> |
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| identifier | ISSN: 1078-8743 |
| ispartof | 13th Annual IEEE/SEMI Advanced Semiconductor Manufacturing Conference. Advancing the Science and Technology of Semiconductor Manufacturing. ASMC 2002 (Cat. No.02CH37259), 2002, p.177-183 |
| issn | 1078-8743 2376-6697 |
| language | eng |
| recordid | cdi_pascalfrancis_primary_15852770 |
| source | IEEE Electronic Library (IEL) Conference Proceedings |
| subjects | Applied sciences Design. Technologies. Operation analysis. Testing Diodes Electronics Etching Exact sciences and technology Ferroelectric materials Frequency Inductors Integrated circuits Magnetic force microscopy Micro- and nanoelectromechanical devices (mems/nems) Microelectromechanical devices Microelectronic fabrication (materials and surfaces technology) Plasma applications Plasma density Plasma devices Platinum Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices |
| title | Pt/PZT/Pt and Pt/barrier stack etches for MEMS devices in a dual frequency high density plasma reactor |
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