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Posts Tagged ‘alignment’

Silicon Photonics Technology Developments

Thursday, April 6th, 2017

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By Ed Korczynski, Sr. Technical Editor

With rapidly increasing use of “Cloud” client:server computing there is motivation to find cost-savings in the Cloud hardware, which leads to R&D of improved photonics chips. Silicon photonics chips could reduce hardware costs compared to existing solutions based on indium-phosphide (InP) compound semiconductors, but only with improved devices and integration schemes. Now MIT researchers working within the US AIM Photonics program have shown important new silicon photonics properties. Meanwhile, GlobalFoundries has found a way to allow for automated passive alignment of optical fibers to silicon chips, and makes chips on 300mm silicon wafers for improved performance at lower cost.

In a recent issue of Nature Photonics, MIT researchers present “Electric field-induced second-order nonlinear optical effects in silicon waveguides.” They also report prototypes of two different silicon devices that exploit those nonlinearities: a modulator, which encodes data onto an optical beam, and a frequency doubler, a component vital to the development of lasers that can be precisely tuned to a range of different frequencies.

This work happened within the American Institute for Manufacturing Integrated Photonics (AIM Photonics) program, which brought government, industry, and academia together in R&D of photonics to better position the U.S. relative to global competition. Federal funding of $110 million was combined with some $500 million from AIM Photonics’ consortium of state and local governments, manufacturing firms, universities, community colleges, and nonprofit organizations across the country. Michael Watts, an associate professor of electrical engineering and computer science at MIT, has led the technological innovation in silicon photonics.

“Now you can build a phase modulator that is not dependent on the free-carrier effect in silicon,” says Michael Watts in an online interview. “The benefit there is that the free-carrier effect in silicon always has a phase and amplitude coupling. So whenever you change the carrier concentration, you’re changing both the phase and the amplitude of the wave that’s passing through it. With second-order nonlinearity, you break that coupling, so you can have a pure phase modulator. That’s important for a lot of applications.”

The first author on the new paper is Erman Timurdogan, who completed his PhD at MIT last year and is now at the silicon-photonics company Analog Photonics. The frequency doubler uses regions of p- and n-doped silicon arranged in regularly spaced bands perpendicular to an undoped silicon waveguide. The space between bands is tuned to a specific wavelength of light, such that a voltage across them doubles the frequency of the optical signal passing. Frequency doublers can be used as precise on-chip optical clocks and amplifiers, and as terahertz radiation sources for security applications.

GlobalFoundries’ Packaging Prowess

At the start of the AIM Photonics program in 2015, MIT researchers had demonstrated light detectors built from efficient ring resonators that they could reduce the energy cost of transmitting a bit of information down to about a picojoule, or one-tenth of what all-electronic chips require. Jagdeep Shah, a researcher at the U.S. Department of Defense’s Institute for Defense Analyses who initiated the program that sponsored the work said, “I think that the GlobalFoundries process was an industry-standard 45-nanometer design-rule process.”

The Figure shows that researchers at IBM developed an automated method to assemble twelve optical fibers to a
silicon chip while the fibers are dark, and GlobalFoundries chips can now be paired with this assembly technology. Because the micron-scale fibers must be aligned with nanometer precision, default industry standard has been to expensively align actively lit fibers. Leveraging the company’s work for Micro-Electro-Mechanical Sensors (MEMS) customers, GlobalFoundries uses an automated pick-and-place tool to push ribbons of multiple fibers into MEMS groves for the alignment. Ted Letavic, Global Foundries’ senior fellow, said the edge coupling process was in production for a telecommunications application. Silicon photonics may find first applications for very high bandwidth, mid- to long-distance transmission (30 meters to 80 kilometers), where spectral efficiency is the key driver according to Letavic.

FIGURE: GlobalFoundries chips can be combined with IBM’s automated method to assemble 12 optical fibers to a silicon photonics chip. (Source: IBM, Tymon Barwicz et al.)

GobalFoundries has now transferred its monolithic process from 200mm to 300mm-diameter silicon wafers, to achieve both cost-reduction and improved device performance. The 300mm fab lines feature higher-N.A. immersion lithography tools which provide better overlay and line width roughness (LWR). Because the of the extreme sensitivity of optical coupling to the physical geometry of light-guides, improving the patterning fidelity by nanometers can reduce transmission losses by 3X.

—E.K.

New Applied PVD system targets TiN hardmasks for 10nm, 7nm chips

Tuesday, May 19th, 2015

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By Jeff Dorsch, Contributing Editor

Applied Materials today introduces the Applied Endura Cirrus HTX PVD, a physical vapor deposition system for creating titanium nitride hardmask films that could be used in fabricating 10-nanometer and 7nm chips.

“Titanium nitride is the metal hardmask of choice,” harder than copper and nearly as hard as diamond, says Sree Kesapragada, Applied’s global product manager for Metal Deposition Products.

“Patterning plays key role in defining the interconnect,” Kesapragada says. “Perfect via alignment is critical for device yield. Hardmask ensures the perfect via alignment critical for yield.”

The hardmasks created with the Endura Cirrus HTX TiN system strike the required balance between neutral stress and film density hardness, he asserts. The TiN hardmask, meant to resist the erosion of etching, helps ensure that via etches land where they are supposed to, and not too close to neighboring vias, which can creates shorts.

Metal hardmask layer manages alignment errors.

Applied has worked with customers at multiple sites in developing the new PVD system over the past two to three years, according to Kesapragada. He emphasizes that the Cirrus HTX TiN system offers “precision control over TiN crystal growth,” as the process chamber is “designed for tensile high-density TiN films.” The new PVD system enables high density, tensile films thanks to a high level of ionization during deposition made possible by a high frequency source.

High film desnity is needed to prevent erosion, and a neutral-to-tensile stress is needed for pattern fidelity. CVD/ALD films have tensile stress, but are low density. Traditionally deposited TiN films have good density, but compressive stress.

The formation of “islands” of TiN crystals is almost like chemical vapor deposition, “layer by layer,” Kesapragada says, “in a PVD chamber.”

In the process chamber, the first of its kind, titanium atoms are reactively sputtered in a nitrogen-based plasma, allowing for tunable composition, according to Applied. This chamber can be used for high-volume manufacturing of semiconductors with 7nm features, covering two process-node generations, Kesapragada says.

There is also “very established integration” with chemical mechanical planarization equipment, he adds.

Applied is the market leader in TiN PVD systems, with more than 200 systems shipped, according to Kesapragada. Those PVD systems have more than 700 process chambers, he adds.

The Endura Cirrus HTX TiN PVD system is being formally introduced this week at the IEEE’s 2015 International Interconnect Technology Conference in Grenoble, France.