Abstract
Silicon nitride (SiNx) is an important and widely used material in many applications due to its intermediate (7 ~ 10) dielectric constant, ultrawide band gap, high strength, and other properties [1]. Patterning thin films of SiNx typically involves the use of plasma etching with fluorocarbons such as CF4, CHF3, and others [2]. While these gases are highly effective for silicon nitride (and many other) etches, they have an unfortunately high global warming potential. As a result, Skyworks Solutions has taken the initiative to substantially reduce the use of fluorocarbons and other greenhouse gases [3, 4]. In the current study, a legacy fluorocarbon-based SiNx etch for the resistor layer is investigated. This plasma etch is somewhat unique in that undercutting the dielectric beneath the photoresist mask is the desired result, and therefore little to no sidewall passivation should be required. Suitable undercut facilitates a successful liftoff of the reactively-sputtered tantalum nitride thin film. The results show that well-targeted critical dimensions and device performance can be achieved for a resistor layer etch without the use of a polymerizing gas (i.e. CHF3). Moreover, by eliminating CHF3, a higher etch rate is achieved and the process time can be halved without negatively impacting the device. This study demonstrates that manufacturing processes can be designed to meet or exceed both sustainability and productivity goals simultaneously.
