Tejaswi K. Indukuri

Demonstration of an electrically functional 34 nm metal pitch interconnect in ultralow-k ILD using spacer-based pitch quartering

The patterning of a 34 nm metal pitch interconnect was realized using a spacer-based pitch quartering scheme. The pattern is transferred into an ultralow-k ILD using a process that avoids ILD buckling and structure collapse. Resulting features were metallized with copper, and electrically characterized. Measurement results show expected trends with drawn dimensions.

Demonstration of a 12 nm-half-pitch copper ultralow-k interconnect process

A process to achieve 12 nm half-pitch interconnect structures in ultralow-k interlayer dielectric (ILD) is realized using standard 193 nm lithography. An optimized pattern transfer that minimizes unwanted distortion of ILD features is followed by copper fill. Electrical measurements that validate functionality of the drawn structures are presented.

Patterning challenges in the fabrication of 12 nm half-pitch dual damascene copper ultra low-k interconnects

Earlier [1, 2] work highlighted an integrated process for electrically functional 12 nm half-pitch copper interconnects in an ultralow-k interlayer dielectric (ILD). In this paper, we focus on understanding and reducing undesired effects such as pattern asymmetry/distortion, and line undulation/ collapse. Key defect modes and possible solution paths are discussed. Line undulation can occur when the ILD feature changes shape under the stress of the sacrificial hard mask(s) (HM) during patterning, resulting in “wavy” instead of straight features. The amount of undulation is directly related to mechanical properties such as elastic modulus, residual stresses of patterned HMs and the ILD, as well as the dimensions and aspect ratio of the features. Line collapse is observed post wet-clean processing when one or more of the following is true - Insufficient ILD mechanical strength, excessive pattern aspect ratio, or non-uniform drying. Pattern asymmetry, or unequal critical dimensions (CD) of trenches defined by the same backbone, is a typical problem encountered during spacer-based pitch division. In pitch quartering (P/4), three different trench widths result from small variations in backbone lithography, spacer CD and etch bias. Symmetric patterning can be achieved through rigorous control of patterning processes like backbone definition, spacer deposition and downstream etches. Plasma-based ash and energetic metal deposition were also observed to degrade patterning fidelity of ultra low-k film, and also need to be closely managed.

Direct seed electroplating of copper on ruthenium liners

The ruthenium (Ru) liner based metallization scheme depends on the ability to electrodeposit Cu onto thin, resistive Ru substrates with substantially high Cu nuclei density. In the present paper, a novel electrochemical bath that utilizes Cu-complexing agents to improve the nucleation of plated Cu films on Ru is presented. Such chemistries can generate Cu nucleation density on Ru greater than 1012 nuclei/cm2, thereby enabling robust gap-fill in aggressive (CD∼30nm) dual damascene structures. Complexed-Cu plating chemistries thus provide great potential for extending Cu metallization to future technology nodes.

Demonstration of a sidewall capacitor to evaluate dielectrics and metal barrier thin films

A sidewall planar capacitor (SW CAP) vehicle is developed to closely simulate processing conditions for metal barrier and dielectric in an integrated structure. For a known tantalum barrier for copper on a low-K dielectric, SW CAP TDDB is similar to those measured on an integrated vehicle. SW CAP results are useful for comparing electrical reliability of different dielectric systems, and effective in determining physical continuity of copper metal barriers.

Demonstration of new planar capacitor (PCAP) vehicles to evaluate dielectrics and metal barrier thin films

Planar capacitors can quickly test material properties of metals and dielectrics for interconnects. A sidewall capacitor device is used to evaluate metal thin-film barriers. Etch stop planar capacitors in turn can test multi-layer etch stops, exposing differences between leaky and good etch stop films. Fillable planar capacitors are also fabricated and results presented for that class of fill materials.