Abstract
Tunneling magnetoresistance (TMR) devices are crucial for high-density low-power magnetic sensing owing to the increase in data-intensive applications. This study presents a three-dimensional heterogeneous integration bonding technique for TMR sensors. The number of serially connected magnetic tunnel junctions is doubled without enlarging the chip area by vertically bonding two TMR film stacks, and the low-frequency 1/f noise is effectively suppressed. The sputtering parameters of the Cr/Au bonding layer, argon-ion activation conditions, and bonding pressure are optimized to achieve a void ratio of only 0.73%. Double-layer TMR devices are fabricated via backside silicon removal, photolithography, and ion-beam etching. A 45° etching angle mitigates sidewall redeposition, increases the magnetoresistance ratio from 149% to 172%, and decreases the magnetic noise to 0.97 nT·Hz(-1/2) at 1 Hz. The proposed approach enables high integration and low noise without altering the device dimensions and has strong potential for applications in high-density magnetic-sensing arrays. The three-dimensional heterogeneous bonding strategy proposed in this study vertically integrates double-layer TMR films, doubles the number of tunnel junctions without enlarging the device footprint, and significantly suppresses the 1/f noise through an optimized bonding process. This approach enables high-density, low-noise, low parasitic resistance magnetic sensing for next-generation spintronic devices.