Stochastic Modeling and Local CD Uniformity Comparison between Negative Metal-Based, Negative- and Positive-Tone Development EUV Resists

This paper presents a simulation study on the printing behavior of three different EUV resist systems. Stochastic models for negative metal-based resist and conventional chemically amplified resist (CAR) were calibrated and then validated. As for negative-tone development (NTD) CAR, we commenced fro...

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Veröffentlicht in:	IEICE Transactions on Electronics 2022/01/01, Vol.E105.C(1), pp.35-46
Hauptverfasser:	KAMOHARA, Itaru, WELLING, Ulrich, KLOSTERMANN, Ulrich, DEMMERLE, Wolfgang
Format:	Artikel
Sprache:	eng
Schlagworte:	Contact holes EUV Inhibitors LCDU mask tone metal-oxide-resist NTD Pitch polymer resist Resists stochastic model calibration Stochastic models Stochastic processes
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creator	KAMOHARA, Itaru WELLING, Ulrich KLOSTERMANN, Ulrich DEMMERLE, Wolfgang
description	This paper presents a simulation study on the printing behavior of three different EUV resist systems. Stochastic models for negative metal-based resist and conventional chemically amplified resist (CAR) were calibrated and then validated. As for negative-tone development (NTD) CAR, we commenced from a positive-tone development (PTD) CAR calibrated (material) and NTD development models, since state-of-the-art measurements are not available. A conceptual study between PTD CAR and NTD CAR shows that the stochastic inhibitor fluctuation differs for PTD CAR: the inhibitor level exhibits small fluctuation (Mack development). For NTD CAR, the inhibitor fluctuation depends on the NTD type, which is defined by categorizing the difference between the NTD and PTD development thresholds. Respective NTD types have different inhibitor concentration level. Moreover, contact hole printing between negative metal-based and NTD CAR was compared to clarify the stochastic process window (PW) for tone reversed mask. For latter comparison, the aerial image (AI) and secondary electron effect are comparable. Finally, the local CD uniformity (LCDU) for the same 20 nm size, 40 nm pitch contact hole was compared among the three different resists. Dose-dependent behavior of LCDU and stochastic PW for NTD were different for the PTD CAR and metal-based resist. For NTD CAR, small inhibitor level and large inhibitor fluctuation around the development threshold were observed, causing LCDU increase, which is specific to the inverse Mack development resist.
doi_str_mv	10.1587/transele.2021ECP5010
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Stochastic models for negative metal-based resist and conventional chemically amplified resist (CAR) were calibrated and then validated. As for negative-tone development (NTD) CAR, we commenced from a positive-tone development (PTD) CAR calibrated (material) and NTD development models, since state-of-the-art measurements are not available. A conceptual study between PTD CAR and NTD CAR shows that the stochastic inhibitor fluctuation differs for PTD CAR: the inhibitor level exhibits small fluctuation (Mack development). For NTD CAR, the inhibitor fluctuation depends on the NTD type, which is defined by categorizing the difference between the NTD and PTD development thresholds. Respective NTD types have different inhibitor concentration level. Moreover, contact hole printing between negative metal-based and NTD CAR was compared to clarify the stochastic process window (PW) for tone reversed mask. For latter comparison, the aerial image (AI) and secondary electron effect are comparable. Finally, the local CD uniformity (LCDU) for the same 20 nm size, 40 nm pitch contact hole was compared among the three different resists. Dose-dependent behavior of LCDU and stochastic PW for NTD were different for the PTD CAR and metal-based resist. 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Electron.</addtitle><description>This paper presents a simulation study on the printing behavior of three different EUV resist systems. Stochastic models for negative metal-based resist and conventional chemically amplified resist (CAR) were calibrated and then validated. As for negative-tone development (NTD) CAR, we commenced from a positive-tone development (PTD) CAR calibrated (material) and NTD development models, since state-of-the-art measurements are not available. A conceptual study between PTD CAR and NTD CAR shows that the stochastic inhibitor fluctuation differs for PTD CAR: the inhibitor level exhibits small fluctuation (Mack development). For NTD CAR, the inhibitor fluctuation depends on the NTD type, which is defined by categorizing the difference between the NTD and PTD development thresholds. Respective NTD types have different inhibitor concentration level. Moreover, contact hole printing between negative metal-based and NTD CAR was compared to clarify the stochastic process window (PW) for tone reversed mask. For latter comparison, the aerial image (AI) and secondary electron effect are comparable. Finally, the local CD uniformity (LCDU) for the same 20 nm size, 40 nm pitch contact hole was compared among the three different resists. Dose-dependent behavior of LCDU and stochastic PW for NTD were different for the PTD CAR and metal-based resist. For NTD CAR, small inhibitor level and large inhibitor fluctuation around the development threshold were observed, causing LCDU increase, which is specific to the inverse Mack development resist.</description><subject>Contact holes</subject><subject>EUV</subject><subject>Inhibitors</subject><subject>LCDU</subject><subject>mask tone</subject><subject>metal-oxide-resist</subject><subject>NTD</subject><subject>Pitch</subject><subject>polymer</subject><subject>resist</subject><subject>Resists</subject><subject>stochastic model calibration</subject><subject>Stochastic models</subject><subject>Stochastic processes</subject><issn>0916-8524</issn><issn>1745-1353</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><recordid>eNpNkctOwzAQRS0EEqXwBywssSVgO3biLiGUh1QeAsrWcp1JcZXaxXZB_AGfTaC0YjUPnXtHuoPQISUnVMjyNAXtIrRwwgijw-pBEEq2UI-WXGQ0F_k26pEBLTIpGN9FezHOCKGS0byHvp6SN686Jmvwra-htW6KtavxyBvd4uoCj51tfJjb9IkrP1_oYKN3eALpA8DhO5jqZN8B30LSbXauI9THm232a_Xgo_2dnr0DfAHv0PrFHFzCw_ELfoRoY4r7aKfRbYSDv9pH48vhc3Wdje6vbqqzUWZ4SVJWsAFrNNTlZMJFI_lEUi3zpjQFANElqQmR0BTCMDoQDDgfsKIB4NLkJTNQ5310tPJdBP-2hJjUzC-D604qVlBRCkG57Ci-okzwMQZo1CLYuQ6fihL1k7laZ67-Zd7JHleyWUx6ChuRDl2-HbsRDSkRqlJ03fwz2cDdW4ICl38DtdWVqg</recordid><startdate>20220101</startdate><enddate>20220101</enddate><creator>KAMOHARA, Itaru</creator><creator>WELLING, Ulrich</creator><creator>KLOSTERMANN, Ulrich</creator><creator>DEMMERLE, Wolfgang</creator><general>The Institute of Electronics, Information and Communication Engineers</general><general>Japan Science and Technology Agency</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SP</scope><scope>8FD</scope><scope>L7M</scope></search><sort><creationdate>20220101</creationdate><title>Stochastic Modeling and Local CD Uniformity Comparison between Negative Metal-Based, Negative- and Positive-Tone Development EUV Resists</title><author>KAMOHARA, Itaru ; WELLING, Ulrich ; KLOSTERMANN, Ulrich ; DEMMERLE, Wolfgang</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c470t-6292faed7bb45f84b81a83f7c6ee0a70d008ef65c21952e44926fee48c372ced3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2022</creationdate><topic>Contact holes</topic><topic>EUV</topic><topic>Inhibitors</topic><topic>LCDU</topic><topic>mask tone</topic><topic>metal-oxide-resist</topic><topic>NTD</topic><topic>Pitch</topic><topic>polymer</topic><topic>resist</topic><topic>Resists</topic><topic>stochastic model calibration</topic><topic>Stochastic models</topic><topic>Stochastic processes</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>KAMOHARA, Itaru</creatorcontrib><creatorcontrib>WELLING, Ulrich</creatorcontrib><creatorcontrib>KLOSTERMANN, Ulrich</creatorcontrib><creatorcontrib>DEMMERLE, Wolfgang</creatorcontrib><collection>CrossRef</collection><collection>Electronics & Communications Abstracts</collection><collection>Technology Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>IEICE Transactions on Electronics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>KAMOHARA, Itaru</au><au>WELLING, Ulrich</au><au>KLOSTERMANN, Ulrich</au><au>DEMMERLE, Wolfgang</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Stochastic Modeling and Local CD Uniformity Comparison between Negative Metal-Based, Negative- and Positive-Tone Development EUV Resists</atitle><jtitle>IEICE Transactions on Electronics</jtitle><addtitle>IEICE Trans. Electron.</addtitle><date>2022-01-01</date><risdate>2022</risdate><volume>E105.C</volume><issue>1</issue><spage>35</spage><epage>46</epage><pages>35-46</pages><artnum>2021ECP5010</artnum><issn>0916-8524</issn><eissn>1745-1353</eissn><abstract>This paper presents a simulation study on the printing behavior of three different EUV resist systems. Stochastic models for negative metal-based resist and conventional chemically amplified resist (CAR) were calibrated and then validated. As for negative-tone development (NTD) CAR, we commenced from a positive-tone development (PTD) CAR calibrated (material) and NTD development models, since state-of-the-art measurements are not available. A conceptual study between PTD CAR and NTD CAR shows that the stochastic inhibitor fluctuation differs for PTD CAR: the inhibitor level exhibits small fluctuation (Mack development). For NTD CAR, the inhibitor fluctuation depends on the NTD type, which is defined by categorizing the difference between the NTD and PTD development thresholds. Respective NTD types have different inhibitor concentration level. Moreover, contact hole printing between negative metal-based and NTD CAR was compared to clarify the stochastic process window (PW) for tone reversed mask. For latter comparison, the aerial image (AI) and secondary electron effect are comparable. Finally, the local CD uniformity (LCDU) for the same 20 nm size, 40 nm pitch contact hole was compared among the three different resists. Dose-dependent behavior of LCDU and stochastic PW for NTD were different for the PTD CAR and metal-based resist. For NTD CAR, small inhibitor level and large inhibitor fluctuation around the development threshold were observed, causing LCDU increase, which is specific to the inverse Mack development resist.</abstract><cop>Tokyo</cop><pub>The Institute of Electronics, Information and Communication Engineers</pub><doi>10.1587/transele.2021ECP5010</doi><tpages>12</tpages></addata></record>
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source	J-STAGE (Japan Science & Technology Information Aggregator, Electronic) Freely Available Titles - Japanese
subjects	Contact holes EUV Inhibitors LCDU mask tone metal-oxide-resist NTD Pitch polymer resist Resists stochastic model calibration Stochastic models Stochastic processes
title	Stochastic Modeling and Local CD Uniformity Comparison between Negative Metal-Based, Negative- and Positive-Tone Development EUV Resists
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