Carbon nanotube based via interconnects: Performance estimation based on the resistance of individual carbon nanotubes

“…Carbon nanotubes (CNTs) offer a large variety of properties [Cha07,Cre08,Sca12], which can be very useful for future electronic devices. One of them is the very high conductance in the ballistic regime [Whi98] that makes CNTs attractive for metallic interconnect systems [Kre02,Van14,Fie14,Fie13]. Although research on CNTs has continued for many years since their discovery in 1991 and clean CNTs approaching the theoretical conductance limit can be produced under well-defined laboratory conditions [Kon01], current CNT-based devices at the wafer level which means a fast and reproducible fabrication are still not reaching that limit.…”

Electronic transport in metallic carbon nanotubes with mixed defects within the strong localization regime

“…Carbon nanotubes (CNTs) offer a large variety of properties [Cha07,Cre08,Sca12], which can be very useful for future electronic devices. One of them is the very high conductance in the ballistic regime [Whi98] that makes CNTs attractive for metallic interconnect systems [Kre02,Van14,Fie14,Fie13]. Although research on CNTs has continued for many years since their discovery in 1991 and clean CNTs approaching the theoretical conductance limit can be produced under well-defined laboratory conditions [Kon01], current CNT-based devices at the wafer level which means a fast and reproducible fabrication are still not reaching that limit.…”

Electronic transport in metallic carbon nanotubes with mixed defects within the strong localization regime

“…Afterwards a 2.3 nm Ni catalyst layer is deposited by electron-beam evaporation and multi-walled CNTs (MWCNTs) are grown within the vias by thermal chemical vapor deposition (CVD) at a temperature of 600 °C using ethylene as carbon precursor. Details regarding the CNT growth recipe can be found elsewhere [10]. The CNTs then were embedded into SiO 2 using a tetraethylorthosilicate (TEOS) and ozone sub-atmospheric pressure CVD process, planarized by chemical mechanical planarization (CMP), and subjected to a HF treatment which involves exposing the CNT tips for 20 s to HF vapor and annealing the sample for 1 min on a hotplate at 150 °C.…”

“…One potential candidate to replace Cu are carbon nanotubes (CNTs) due to their extraordinary properties, such as high resistance towards electromigration [2], high thermal conductance [3] and a large electron mean free path [4]. However, major challenges for the integration of CNTs into interconnects are a sufficient CNT density [5], a low metal-CNT contact resistance [6] and a high CNT quality [7]. For multi-walled CNTs (MWCNTs) a linear increase of the resistance with the CNT length is generally assumed [8], but for single walled CNTs Anderson localization has also been observed [7].…”

Localization length of integrated multi-walled carbon nanotubes

“…CNT vias connecting different metal levels of an integrated circuit are potential candidates to replace copper ones. With tip radii of the order of 20 nm, the size ranges of the probe (metallized AFM tip) and sample (individual MWCNT) are comparable, the wafer‐level fabrication process yields an appropriate mechanical stability and contaminations directly relate to the variation of the local conductivity properties (see below), therefore CNT vias appeared as ideal sample to verify the opportunities of CS‐AFM as an advanced nanoscale characterization technique. The analysis of CNT via samples with CS‐AFM reveals that different CNT vias yield a map of locally different conductivity as shown in Figure (left) .…”

Advanced Characterization Methods for Electrical and Sensoric Components and Devices at the Micro and Nano Scales