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MAGALIGN: Magnetic alignment for high precision 3D assembly


​Bernard Dieny at IRIG, receives an ERC-Proof of Concept for his MAGALIGN project. This project, co-supported with his colleague Ricardo Sousa, is the result of an ERC Advanced Grant for the development of multifunctional spintronic chips. MAGALIGN aims at a particular valorisation resulting from the ERC Advanced Grant. The aim is to improve alignment accuracy by one to two orders of magnitude during molecular bonding operations. This project will benefit from 18 months of financial support.

Published on 14 September 2020
In microelectronics, molecular bonding has opened up a very efficient 3D integration path, allowing several levels of microelectronic components, initially produced on different substrates, to be stacked on top of each other. During these bonding steps, an extremely precise relative alignment of the substrates must be achieved. Up to now, this alignment has been achieved optically. The project proposes to prove the concept of a new, much more precise approach, based on a magnetic alignment combining nanomagnets and spintronic magnetic field sensors.

The launching of a new generation of spintronic memory (STT-MRAM) in volume production in 2019 by all major microelectronics companies marks the adoption of spintronics by microelectronics industry. This constitutes a major milestone in the field. Our institute largely contributed to these developments and hold key patents on MRAM technology. Part of these developments were performed thanks to two ERC Adv grants. These two grants dealt with various MRAM optimizations and their potential for low power and multifunctional spintronic circuits. In the frame of the second ERC project (MAGICAL: “CMOS/Magnetoelectronic Integrated Circuits with Multifunctional Capabilities”), an ERC-Proof of Concept grant just got funded (MAGALIGN: “Magnetic alignment for high precision 3D assembly”). The goal of this project is the following:
In microelectronics, 3D integration and assembly definitely appears as a very efficient option to achieve highly integrated chips. It offers major benefits such as combining heterogeneous technologies, combining high-performance and low-power chips, increasing data transfer bandwidth in memory above logic circuits, etc. 3D assembly is realized by bonding two wafers or chips face to face on a wafer. In this bonding process, the number of interchips interconnects is limited by the accuracy of the alignment process. Presently, alignment methods rely on optical alignment techniques which offer ±0.2 µm resolution for wafer-to-wafer bonding or only ±1 µm resolution for die-to-wafer bonding. This is relatively poor and limits the density of interconnects and therefore the bandwidth of interchip communication. In this ERC PoC project, it is intended to establish the viability of a novel magnetic alignment approach based on nanomagnetism and spinelectronics which could yield unprecedented accuracy in alignment during wafer bonding.
The goals of MAGALIGN are i) to make a proof of concept of this novel alignment method, ii) optimize it and develop the design tools to exploit it, iii) develop industrialization strategy.


Legend: Electrical testing of spintronic components.

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