Understanding How Small Variations In Photoresist Shape Significantly Impact Multi-Patterning Yield


Multi-patterning schemes such as Self-Aligned Double Patterning (SADP) and Self-Aligned Quadruple Patterning (SAQP) have been used to successfully increase semiconductor device density, circumventing prior physical limits in pattern density. However, the number of processing steps needed in these patterning schemes can make it difficult to directly translate a lithographic mask pattern to a fin... » read more

Inside Next-Gen Transistors


David Fried, chief technology officer at [getentity id="22210" e_name="Coventor"], sat down with Semiconductor Engineering to discuss the IC industry, China, scaling, transistors and process technology. What follows are excerpts of that conversation. SE: In a recent roundtable discussion you talked about some of the big challenges facing the IC industry. One of your big concerns involves th... » read more

Battling Fab Cycle Times


The shift from planar devices to finFETs enables chipmakers to scale their processes and devices from 16nm/14nm and beyond, but the industry faces several challenges at each node. Cost and technical issues are the obvious challenges. In addition, cycle time—a key but less publicized part of the chip-scaling equation—also is increasing at every turn, creating more angst for chipmakers and... » read more

BEOL Issues At 10nm And 7nm (part 2)


Semiconductor Engineering sat down to discuss problems with the back end of line at leading-edge nodes with Craig Child, senior manager and deputy director for [getentity id="22819" e_name="GlobalFoundries'"] advanced technology development integration unit; Paul Besser, senior technology director at [getentity id="22820" comment="Lam Research"]; David Fried, CTO at [getentity id="22210" e_name... » read more

BEOL Barricades Ahead


Coventor recently assembled an expert panel at IEDM 2016, to discuss changes to BEOL process technology that would be needed to continue dimensional scaling to 7 nm and lower. Among the questions posed to panelists: What is BEOL? Where does it begin and end? Are there fundamental limits to interconnect processes? How much longer can we continue to use current interconnect processes and ... » read more

Multi-Patterning Issues At 7nm, 5nm


Continuing to rely on 193nm immersion lithography with multiple patterning is becoming much more difficult at 7nm and 5nm. With the help of various resolution enhancement techniques, optical lithography using a deep ultraviolet excimer laser has been the workhorse patterning technology in the fab since the early 1980s. It is so closely tied with the continuation of [getkc id="74" comment="Mo... » read more

How Many Nanometers?


What’s the difference between a 10nm and a 7nm chip? That should be a straightforward question. Math, after all, is the only pure science. But as it turns out, the answer is hardly science—even if it is all about numbers. Put in perspective, at 65nm, companies defined the process node by the half pitch of the first metal layer. At 40/45nm, with the cost and difficulty of developing n... » read more

Back-End-of-Line (BEOL) Virtual Patterning With SEMulator3D


Interconnect requirements for the 22nm technology node and beyond, driven by shrinking FEOL geometry, push the limits of unit process tools for BEOL as well as FEOL. Lengthy and costly in-fab experiments are required to ensure that the integrated BEOL process meets local performance and cross-wafer uniformity requirements. Virtual fabrication experiments conducted with SEMulator3D can reduce th... » read more

Interconnect Challenges Rising


Chipmakers are ramping up their 14nm finFET processes, with 10nm and 7nm slated to ship possibly later this year or next. At 10nm and beyond, IC vendors are determined to scale the two main parts of the [getkc id="185" kc_name="finFET"] structure—the transistor and interconnects. Generally, transistor scaling will remain challenging at advanced nodes. And on top of that, the interconnects ... » read more

Back-End-of-Line (BEOL) Metallization


Physical Vapor Deposition (PVD) for Back-End-of-Line (BEOL) metallization is being pushed to the limits at the 16-nanometer (nm) technology node and beyond. Extending PVD for metal liner and barrier seed deposition is forcing the process into a narrow window that must be characterized prior to manufacturing introduction. Furthermore, understanding the liner dependency on the trench and via etch... » read more

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