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Main Authors: Iyer, Vasant, Shah, Nishal, Johnson, A. T. Charlie, Issadore, David A., Aflatouni, Firooz
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.06498
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author Iyer, Vasant
Shah, Nishal
Johnson, A. T. Charlie
Issadore, David A.
Aflatouni, Firooz
author_facet Iyer, Vasant
Shah, Nishal
Johnson, A. T. Charlie
Issadore, David A.
Aflatouni, Firooz
contents Electronic devices made from two-dimensional materials (2DMs) significantly outperform their silicon counterparts; however, silicon CMOS technology remains commercially predominant as it offers the capability to operate dense arrays of devices in a scalable fashion. In particular, graphene Hall sensors (GHSs) offer great improvements in magnetic field sensitivity and resolution compared to silicon Hall-effect sensors, making them extremely appealing for magnetic field imaging and biosensing. At present, GHS arrays have limited scalability compared to silicon CMOS since they require planar routing for biasing and multiplexing. In this work, we explore strategies to realize high-density graphene Hall sensor arrays by vertically connecting GHSs with silicon CMOS biasing and multiplexing circuitry, allowing the routing and circuitry to scale with the array. We investigate the importance of design choices in the chip layout and post-fabrication process in maximizing the reliability of graphene transfer onto mm-scale CMOS dies. Our experimental results validate the success of the integration process by showing for the first time that GHSs can be monolithically integrated with CMOS with high yield to form sensor arrays. We expect that these results will lead to further improvements in magnetic sensing technology and broader advancements in large-scale heterogeneous 2DM-CMOS systems.
format Preprint
id arxiv_https___arxiv_org_abs_2508_06498
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-density and scalable graphene Hall sensor arrays through monolithic CMOS integration
Iyer, Vasant
Shah, Nishal
Johnson, A. T. Charlie
Issadore, David A.
Aflatouni, Firooz
Instrumentation and Detectors
Materials Science
Electronic devices made from two-dimensional materials (2DMs) significantly outperform their silicon counterparts; however, silicon CMOS technology remains commercially predominant as it offers the capability to operate dense arrays of devices in a scalable fashion. In particular, graphene Hall sensors (GHSs) offer great improvements in magnetic field sensitivity and resolution compared to silicon Hall-effect sensors, making them extremely appealing for magnetic field imaging and biosensing. At present, GHS arrays have limited scalability compared to silicon CMOS since they require planar routing for biasing and multiplexing. In this work, we explore strategies to realize high-density graphene Hall sensor arrays by vertically connecting GHSs with silicon CMOS biasing and multiplexing circuitry, allowing the routing and circuitry to scale with the array. We investigate the importance of design choices in the chip layout and post-fabrication process in maximizing the reliability of graphene transfer onto mm-scale CMOS dies. Our experimental results validate the success of the integration process by showing for the first time that GHSs can be monolithically integrated with CMOS with high yield to form sensor arrays. We expect that these results will lead to further improvements in magnetic sensing technology and broader advancements in large-scale heterogeneous 2DM-CMOS systems.
title High-density and scalable graphene Hall sensor arrays through monolithic CMOS integration
topic Instrumentation and Detectors
Materials Science
url https://arxiv.org/abs/2508.06498