Katja Steidel scite author profile

Electron beam direct write lithography (EBDW) potentially offers advantages for low-volume semiconductor manufacturing, rapid prototyping or design verification due to its high flexibility without the need of costly masks. However, the integration of this advanced patterning technology into complex CMOS manufacturing processes remains challenging. The low throughput of today’s single e-Beam tools limits high volume manufacturing applications and maturity of parallel (multi) beam systems is still insufficient [1,2]. Additional concerns like transistor or material damage of underlying layers during exposure at high electron density or acceleration voltage have to be addressed for advanced technology nodes. In the past we successfully proved that potential degradation effects of high-k materials or ULK shrink can be neglected and were excluded by demonstrating integrated electrical results of 28nm node transistor and BEOL performance following 50kV electron beam dry exposure [3]. Here we will give an update on the integration of EBDW in the 300mm CMOS manufacturing processes of advanced integrated circuits at the 28nm SRAM node of GLOBALFOUNDRIES Dresden. The work is an update to what has been previously published [4]. E-beam patterning results of BEOL full chip metal and via layers with a dual damascene integration scheme using a 50kV VISTEC SB3050DW variable shaped electron beam direct writer at Fraunhofer IPMSCNT are demonstrated. For the patterning of the Metal layer a Mix & Match concept based on the sequence litho - etch -litho -etch (LELE) was developed and evaluated wherein several exposure fields were blanked out during the optical exposure. Etch results are shown and compared to the POR. Results are also shown on overlay performance and optimized e-Beam exposure time using most advanced data prep solutions and resist processes. The patterning results have been verified using fully integrated electrical measurement of metal lines and vias on wafer level. In summary we demonstrate the integration capability of EBDW into a productive CMOS process flow at the example of the 28nm SRAM technology node

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Integration of e-beam direct write in BEOL processes of 28nm SRAM technology node using mix and match

Gutsch

Choi

Hanisch

et al. 2014

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Many efforts were spent in the development of EUV technologies, but from a customer point of view EUV is still behind expectations. In parallel since years maskless lithography is included in the ITRS roadmap wherein multi electron beam direct patterning is considered as an alternative or complementary approach for patterning of advanced technology nodes. The process of multi beam exposures can be emulated by single beam technologies available in the field. While variable shape-beam direct writers are already used for niche applications, the integration capability of e-beam direct write at advanced nodes has not been proven, yet. In this study the e-beam lithography was implemented in the BEoL processes of the 28nm SRAM technology. Integrated 300mm wafers with a 28nm back-end of line (BEoL) stack from GLOBALFOUNDRIES, Dresden, were used for the experiments. For the patterning of the Metal layer a Mix and Match concept based on the sequence litho - etch - litho – etch (LELE) was developed and evaluated wherein several exposure fields were blanked out during the optical exposure. E-beam patterning results of BEoL Metal and Via layers are presented using a 50kV VISTEC SB3050DW variable shaped electron beam direct writer at Fraunhofer IPMS-CNT. Etch results are shown and compared to the POR. In summary we demonstrate the integration capability of EBDW into a productive CMOS process flow at the example of the 28nm SRAM technology node

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15days electron beam exposure for manufacturing of large area silicon based NIL master

Thrun

Choi

Freitag

et al. 2013

Microelectronic Engineering

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Scaling and optimization of high-density integrated Si-capacitors

Weinreich

Seidel

Rudolph

et al. 2013

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This paper focuses on the scaling and optimization of metal-isolator-metal capacitors integrated in 3D Si structures. Scaling to high capacitance density is aimed by the use of high-k dielectrics and a significant area enhancement realized through silicon pattering with increasing aspect ratios. By material and process optimization the capacitors show excellent IV and CV characteristics with high temperature and reliability performance independently of the 3D structure. A fully functional capacitor of 4mm2 consisting of 80 Mil trenches with an overall capacitance of 850nF can be demonstrated

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Katja Steidel

Patterning and imaging with electrons: assessing multi-beam SEM for e-beam structured CMOS samples

Verification of E-Beam direct write integration into 28nm BEOL SRAM technology

Integration of e-beam direct write in BEOL processes of 28nm SRAM technology node using mix and match

15days electron beam exposure for manufacturing of large area silicon based NIL master

Scaling and optimization of high-density integrated Si-capacitors

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