Yearly Archives: 2016

Busch LLC has launched a new program where, at key sites around the world, they have the ability to re-manufacture any major brand of vacuum pump, including high vacuum turbos and cryos.

“In the last year, we’ve made a lot of investments in re-manufacturing,” said Derek Shields, Director Strategic Alliances, Busch. The company is calling it re-manufacturing rather than servicing because of the application of manufacturing principles, including lean practices, to the service operation. Re-manufacturing services extend to major brands of gas abatement systems, although those are typically done on-site.

Shields said that rather than performing service at what he calls “supercenters,” as other suppliers are doing, Busch is striving to offer local support. “We’re actually investing in areas where there are semiconductor clusters so that we’ve got support locally,” Shields said.

“We’re keeping those pumps alive, because there’s really nothing wrong with the pumps. We can actually improve upon the older technology vacuum pumps,” Shields said. Typical turnaround time for a pump re-manufacture is about 4 weeks, but that can be expedited upon request.

The main advantage of the re-manufacturing capability is risk mitigation. “The risk of the pump failing in its service window is negated,” he said.

The latest addition to the Busch lineup is a new facility in Austin, TX. This 44,000ft2 facility will offer singe piece flow re-manufacturing with four flow line capabilities, processing 16 modules per day from disassembly to testing. It also has the potential to serve as a distribution hub for pumps and parts.

Some upgraded features of the building include additional space, a training center, a fully exhausted disassembly area and visual production planning by way of large screens in each area tracking actual movements in flow lines. A visitor walkway will allow visitors to view the production area without entering it, and customers will be able to track their repairs via the web in real time. “Our customers can go into the tracker and see where their pumps is in the service process. It will also give them push notifications of where their pump is and when it’s ready,” Shields said.

9:30 am –10:15 am
CLOSING KEYNOTE: Internet of Things in Smart Manufacturing
Atul Mahamuni, Vice President, Internet of Things, Oracle
Keynote Stage

10:00 pm – 3:00pm
University Day: Future U
Exploring Careers in Microelectronics
Rm 304, Esplanade

10:30 am – 4:00 pm
Smart Manufacturing
Keynote Stage

10:30 am – 12:30 pm
Sensing the Future: Enabling Applications for a Smarter World
TechXPOT North

10:30 am –12:50 pm
3D Printing: A New Dimension in Manufacturing
TechXPOT South

1:45 pm – 4:00 pm
IoT Startups and Hackathon Showcase

2:00 pm – 3:00 pm
Best of West Showcase
Innovation & IoT Theater

By Pete Singer, Editor-in-Chief

On Wednesday, Solid State Technology and SEMI announced the recipient of the 2016 “Best of West” Award — Coventor — for its SEMulator3D. The award recognizes important product and technology developments in the electronics manufacturing supply chain. The Best of West finalists were selected based on their financial impact on the industry, engineering or scientific achievement, and/or societal impact.

Coventor won the “Best-of-West” award for its SEMulator 3D modeling software. Left to right, SEMI’s Karen Savala, Dinesh Bettadapur, vice president, business development at Coventor, who received the award, and Pete Singer, Editor-in-Chief of Solid State Technology.

Coventor won the “Best-of-West” award for its SEMulator 3D modeling software. Left to right, SEMI’s Karen Savala, Dinesh Bettadapur, vice president, business development at Coventor, who received the award, and Pete Singer, Editor-in-Chief of Solid State Technology.

Coventor’s SEMulator3D is a 3D semiconductor process modeling platform that can predictively model any fabrication process applied to any semiconductor design. Starting from a “virtual” silicon wafer, the product performs a series of unit processes like those in the fab to create highly accurate 3D computer models of the predicted structures on wafer.

“It’s a very powerful software modeling platform that has been widely adopted for advanced process development and integration for 10nm, 7nm nodes and beyond,” said Dinesh Bettadapur, vice president, business development at Coventor. Bettadapur accepted the award in the Coventor booth, presented by Solid State Technology’s Pete Singer and SEMI’s Karen Savala.

Bettadapur noted that advanced devices are increasingly becoming 3D, whether it’s finFET structures, 3D NAND or gate-all-around. “We enable you to both visualize the device you’re trying to build in advance without running a single wafer, and also accurately predict process variations,” he said.

Using unique physics-driven 3D modeling technology, the SEMulator3D modeling engine can model a wide variety of unit process steps. Each process step requires only a few geometric and physical input parameters that are easy to understand and calibrate. Just as in an actual fab, upstream unit process parameters (such as deposition conformality, etch anisotropy, selectivity, etc.) interact with each other and design data in a complex way to impact the final device structure.

“You can analyze any process variation, whether it’s film thicknesses, sidewall angles, etch depths, litho biases and so forth. You can vary any process parameter that you have entered in our process simulator and then look at the upstream and downstream process effects,” Bettadapur said.

Starting from input design data, SEMulator3D follows an integrated process flow description to create the virtual equivalent of the complex 3D structures created in the fab. Because the full integrated process sequence is modeled, SEMulator3D has the ability to predict downstream ramifications of process changes that would otherwise require build-and-test cycles in the fab.

On display at Coventor’s booth is 3D sculpture modeled on 14nm FinFET Technology (see photo). This piece received the grand prize at the Design Automation Conference (DAC) last month.

The piece was produced on a state-of-the-art 3D printer from Stratasys, using SEMulator3D to generate the data. The effort was supported by GrabCad, a digital manufacturing hub that helps designers and engineers build great products faster.

With SEMulator3D, Coventor created a large model of 14nm FinFET transistors, across a wide area of SRAM design, at high resolution, integrated from starting wafer through Metal 3, with some artistic cut-outs for visibility.   The resulting model reinforced all the key advanced capabilities of SEMulator3D, including multietch, visibility-limited deposition, selective epitaxy and many others.

As DAC grand prize winner, the 14nm FinFET 3D Sculpture will now be moved to the Computer History Museum in Mountain View, CA where it will be on display for one year.

Hear more about the SEMulator 3D and all of the Best of West finalists today at the Best of West Showcase in the Advanced Manufacturing Forum at TechXPOT South from 2:00pm-3:30pm.

SEMulator3D Viewer, showing a hypothetical 22nm FinFET SRAM cell

SEMulator3D Viewer, showing a hypothetical 22nm FinFET SRAM cell

By Ed Korczynski, Sr. Technical Editor

New Materials Need New Handling Approaches photo

Wenge Yang, Vice President of Corporate Marketing, Entegris

Wenge Yang is vice president of corporate marketing for Entegris, and before joining the company in 2012 he earned a Ph.D. in Materials Engineering and served in various executive roles at Advanced Micro Devices, Tokyo Electron, and two startup companies, so he has a uniquely valuable perspective on materials trends in IC fabs. Yang spoke with the Show Daily about major trends in High Volume Manufacturing (HVM), and about the topics that will be discussed in the Entegris Yield Breakfast Forum “Yield Enhancement Challenges in Today’s Memory IC Production” happening Thursday morning, July 14.

 

3D-NAND

On the memory side the biggest challenge is that investment into different memory technologies has slowed innovation in DRAM. “People will hold the R&D money away from DRAM to try to find a DRAM-killer. So most of the innovation in memory is in 3D-NAND, and obviously Samsung is leading the industry with moves to build two new production lines to try to dominate the market.”

One of the known difficulties in 3D-NAND HVM is the etching and filling of contacts to the side “staircase” structure. Today the material used for contact fill is tungsten (W), while standard WF6 gas precursor shows some limits in ability to fill these contacts and in reliability. Going to more layers generally means deeper holes to fill, so fabs are exploring new fluoride-free-tungsten using chloride chemistry precursors which promise better process results.

EUVL

EUV lithography has been debated for many years,” reminded Yang. “Finally, it has been developed to the point that it will be used in 2018 for pilot and in 2020 for production. Logic fabs will use it for 7nm-node processing, while in foundry fabs the 5nm-node will be the insertion point.”

Inpria and many of the legacy photoresist suppliers are developing new metal-core photoresist chemistry for improved sensitivity and Line-Width Roughness (LWR) in EUVL. Yang explains that new handling technologies will be needed for such photoresists, “A new requirement in purification is needed, while the filtration requirement for particles remains. This comes along with what we call ‘metal-phobia’ at the leading edge. In the past part-per-trillion levels were not issues, while today the whole delivery path becomes an issue and customers now ask about the materials of construction of all fluid-path components to ensure that no contaminants leach out into chemistry.”

Purity uncertainties

At the leading edge, a lot of focus is on gas purity requirements of new metal-organic precursors needed for ALD/CVD. “In reality, if we talk to IDMs they say that they honestly don’t know what is the right spec. Maybe part-per-trillion is too much, but they will say that they do not want to leave risk in the process,” confided Yang. “There are cases where a customer sees something happen and they can trace the problem back to a metal contamination level in a precursor. Obviously we know that less metal should be better, but we generally lack the ability to know exactly so the spec tends to stay at the prior node level.”

“In terms of the business dynamics, it is a challenge for us to create new products that meet the evolving needs of our leading customers,” explained Yang. “However the greater challenge is the serious overhead investment needed for more on-site customer support and more analytical lab tests. Supporting today’s customers is painful today, so smaller companies may find it too difficult and expensive to stay in the market.”

On Thursday morning of SEMICON West in the Yerba Buena level of the Marriott Marquis hotel, Entegris will host the 7th annual Yield Breakfast Forum. Micron will talk about XPoint manufacturing technology it has co-developed with Intel. XMC will talk about the dynamic of China developing it’s own materials supply-chain.

By Pete Singer, Editor-in-Chief

Fan-out wafer level packaging (FOWLP) is gaining traction, leading to higher I/Os and larger formats, and new mobile displays are pushing the limits of pixel per inch (PPI) while also moving to larger formats. Both trends are driving new requirements for lithography equipment, including steppers, track systems and photoresists. Both packages and displays are employing new types of materials and thinner substrates as well. “There’s a lot of commonality between the advanced display technologies and packaging technologies,” said Rich Rogoff, vice president and general manager of Rudolph’s Lithography Systems Group. “The step-and-repeat system approach is ideally suited to address those challenges.”

Key lithographic challenges of advanced packaging and displays are shown in Figure 1.

Figure 1. Key lithographic challenges of advanced packaging and displays are shown.

Figure 1. Key lithographic challenges of advanced packaging and displays are shown.

Rogoff said another big challenge is the ability to manage what he calls dimensionally unstable material. “These are materials that change with time, with temperature, with humidity and with process steps, every time they come back through a lithography step they can change form. Steppers have to be able to deal with that,” he said.

Rogoff also said he’s seeing changes in imaging chemistries which are creating another challenges. “We’re doing things now from broadband resist to i-line resist, from thin-films to thick films, to dry films to organic chemistries. It’s all over the field here with respect to what types of chemistries are being used to image, and the challenge is of course when going from a thick material to a thin material and varied compositions, you get a much different kind of imaging characteristic. Really you need to be able to manage all of those without having to change your lithography system,” he said.

In packaging applications, large topography is yet another challenge. In a fan-out type of situation, there can be significant differences in heights between the substrate and the die, for example. “You’re having to image through, in some cases, >20 microns of photoresist for a two or three micron line, and that becomes a very big challenge,” Rogoff said. “The package size and the display sizes are also getting bigger, and so you need to try to get as much as you can into one imaging field. The lenses need to have a very large field of view.”

FOWLP, where individual die are connected on redistribution layer, is expected to lead to a major change in process equipment. Today, die are “reconstituted” on a wafer. In the future, as volume increases, a move to high density panels is expected. “As the demand goes up, certainly panels make the most sense,” Rogoff said.

Earlier this year, Rudolph announced that a leading outsourced assembly and test facility (OSAT) has placed an order for the JetStep Lithography System for the semiconductor advanced packaging industry’s first panel manufacturing line. “That’s the first true panel fan-out application that’s moving forward, especially in the OSAT world,” Rogoff said.

While the stepper part of the litho equation is ready for “panelization,” the rest of the industry infrastructure is working from two directions. One, from printed-circuit board type solutions where thick resist are dry films. The other, from the display side, uses thin chemical resists. “Somehow we have to bridge the gap between a thin film and a thick film,” Rogoff said. “These are some of the infrastructure things that are still being worked out, but I think those are relatively easy to solve.”

Elvino da Silveira, Rudolph’s vice president of marketing, said he’s seen some recent changes. “Last year, when we were talking to the various customer and partners that we interact with in terms of the panel level fan out, everybody was really focused on doing reconstituted panels, the face-down type chips. Basically taking the EWLB process and scaling it up to the panel level. As time has gone on, and with TSMC bringing out InFO and so forth, there have been several players that are more open to doing this on a carrier. It adds some costs, but at least based on the general feedback we’ve gotten from some of the industry , scaling up to the larger substrate offsets the additional cost of the carrier,” he said.

Figure 2 (presented at SEMI’s Industry Strategy Symposium in January by Babak Sabi, corporate vice president, director, assembly and test technology department, Intel Corp.) shows the expected progression of packaging technology as IO density increases. Flip chip, ball grid array on the left (the orange box) has 15-60 micron feature sizes depending on the layer and the type of feature being exposed.

Figure 2. As IO density increases, new packaging technologies will be required (SWIFT, SLIT, SLIM and INFO-WLP are trademarks of Amkor, ASE and TSMC). Source: Intel (SEMI Industry Strategy Symposium 2016)

Figure 2. As IO density increases, new packaging technologies will be required (SWIFT, SLIT, SLIM and INFO-WLP are trademarks of Amkor, ASE and TSMC). Source: Intel (SEMI Industry Strategy Symposium 2016)

The next generation, (the yellow box) indicates fan out packaging. “We’re still more towards that boundary between the orange and the yellow, because really no one’s producing sub-five microns in HVM today. Most of it is between 5 and 10,” da Silveira said.

The next level (the green box) indicates embedded technology, such as Intel’s Embedded Multi-die Interconnect Bridge (EMIB). Instead of using a large silicon interposer typically found in other 2.5D approaches, EMIB uses a very small bridge die, with multiple routing layers. Here, the IOs are getting much higher, and the feature sizes are getting pushed toward two microns. As technology moves from the yellow box to the green box, expect a switch from wafers to panels.

SEMI honored four industry leaders for their outstanding accomplishments in developing Standards for the electronics and related industries. The SEMI Standards awards were announced at the SEMI International Standards reception held during SEMICON West 2016.

The 2016 SEMI International Standards Excellence Award, inspired by Karel Urbanek,is the most prestigious award in the SEMI International Standards Program. Yesterday, it was awarded to Terry Asakawa of Tokyo Electron.   His leadership was critical in establishing the PV Automation Global Technical Committee and its subsequent transformation into the Automation Technology Global Technical Committee, as he envisioned how the SEMI Standards Program could effectively address simpler, flow-oriented manufacturing in industries outside of semiconductor manufacturing. In addition, he led the identification of previously unknown incompatibility issues and lack of evaluation methods for interoperability and closed the gap with two important documents on FOUP-Load Port Interoperability Implementation. In recent years, Asakawa has been very active in development work to enhance the GEM300 Standards with contemporary concepts (e.g., scheme for secure recipe management and use of prediction in real time carrier logistics controls). He continues to make major contributions to increasing the usability and relevance of SEMI equipment communication Standards, which are essential to Smart Manufacturing.

In addition to the 2016 SEMI International Standards Excellence Award, the recipients of three other major SEMI Standards awards were also announced:

The Merit Award

The Merit Award recognizes major contributions to the SEMI International Standards Program.  Award winners typically take on a very complex problem at the task-force level, gain industry support, and drive the project to completion. This year, the award was presented to Kurt Haller of KLA-Tencor. Haller has been a key member of the Silicon Wafer technical committee for years, and is currently the North American leader for the International Automated Advance Surface Inspection Task Force. His diplomatic leadership strengthened collaboration within the international community, enabling the task force to efficiently revise and maintain wafer inspection standards to current technology including SEMI M35 – Guide for Developing Specifications for Silicon Wafer Surface Features Detected by Automated Inspection, M50 – Test Method for Determining Capture Rate and False Count Rate for Surface Scanning Inspection Systems by the Overlay Method, M52 – Guide for Specifying Scanning Surface Inspection Systems for Silicon Wafers for the 130nm to 11nm Technology Generations, M58 – Test Method for Evaluating DMA Based Particle Deposition Systems and Processes, MF1048 – Test Method for Measuring the Reflective Total Integrated Scatter, and MF1811 – Guide for Estimating the Power Spectral Density Function and Related Finish Parameters from Surface Profile Data within the past three years.

The Leadership Award 

The Leadership Award recognizes outstanding leadership in guiding the SEMI International Standards Program. Sean Larsen of Lam Research has been the leader of the North America EHS Technical Committee (TC) Chapter and task forces for over a decade. He is the co-leader of SEMI S22 (Electrical Design) Revision Task Force, SEMI S2 Non-Ionizing Radiation Task Force, and Control of Hazardous Energy Task Force. Larsen is very engaged in global EHS Committee activities, as well as the North American Regional Standards Committee and, previously, the International Standards Committee. In both the North America (NA) EHS Technical Committee and the NA Regional Standards Committee, he has established forums for discussing Standards rules, questions, and problems, as well as developed processes for suggesting changes to the Regulations when determined to be appropriate. Larsen’s deep knowledge of the Standards Program provides guidance and support to the challenging EHS Committee.

The Legacy Award 

Win Baylies of BayTech-Resor was recognized with the SEMI Standards Legacy Award for his valuable contributions and continued dedication to the SEMI International Standards Program, which is celebrating its 43rd anniversary this year. Since the 1970s, Baylies has been involved with numerous committees including Flat Panel Display, Photovoltaic, Silicon Wafer, Traceability, Compound, High-Brightness LED, 3-Dimensional Stacked Integrated Circuits, and MEMS. Baylies has tirelessly promoted Standards development internationally, recruited key volunteers throughout the supply chain and conducted countless education programs. His long-standing dedication to the advancement of SEMI Standards has been instrumental for SEMI.

For more information about SEMI International Standards, visit www.semi.org/en/Standards.

Leti, an institute of CEA Tech, and the Korea Institute of Science and Technology (KIST) today announced an agreement to jointly explore a variety of technologies, including monolithic 3D, neuromorphic architectures, non-volatile 3D memory, spintronics and ultra-low power semiconductors.

The five-year joint project also will focus on creating a broad network to foster international collaboration on ultra-low power semiconductors, which both institutes agree will be required to power the ever-increasing spread of digital devices and the Internet of Things.

“Like Leti, KIST has helped set the standards for government-supported research institutes for 50 years,” said Leti CEO Marie Semeria. “This agreement reflects that we have identified numerous vital technology fields that must be developed to make industry more productive, companies more innovative and society more responsive to people in many aspects of their lives.”

“Post-Silicon Semiconductor Institute (PSI) of KIST is playing a key role in semiconductor R&D in Korea. With this agreement, KIST and Leti will strengthen the collaborative relationship to achieve global leadership in the field of semiconductors.” said KIST president Byung Gwon LEE.

Leti partners with large industrials, SMEs and startups to tailor advanced solutions that strengthen their competitive positions. It has launched 59 startups. Its 8,500m² of new-generation cleanroom space feature 200mm and 300mm wafer processing of micro and nano solutions for applications ranging from space to smart devices. With a staff of more than 1,900, Leti is based in Grenoble, France, and has offices in Silicon Valley, Calif., and Tokyo.

KIST is a multi-disciplinary research institute located in Seoul, S. Korea. Founded in 1966, it is the first multi-disciplinary scientific research institute in Korea and has contributed significantly to the economic development of the country, particularly during the years of accelerated growth in the 1970s and 1980s.

By Shannon Davis, Web Editor

Kateeva is out to change the way displays are being made, and during Tuesday’s Silicon Innovation Forum keynote, Kateeva President and COO Conor Madigan, PhD, laid out how their YIELDJet inkjet system is making that happen.

In recent years, OLED displays have captured the imagination of the industry because of the materials’ capability to enable new kinds of form factors, specifically flexible displays. One of the compelling characteristics of OLED is designers can make a display on a thin piece of plastic, freeing them from rigid glass.

Another compelling aspect, Madigan explained, is that OLED displays have fewer subcomponents than their LCD counter parts, so manufacturing cost can be lower. And he believes inkjet technology will play a key role in making OLED more affordable. His company, Silicon Valley-based Kateeva, has focused their efforts on developing an inkjet platform for OLED manufacturing called YIELDJet, a completely different style of inkjet system.

Kateeva’s YIELDJet inkjet printing platform.

Kateeva’s YIELDJet inkjet printing platform.

When the concept of flexible OLEDs was first catching on, designers had some significant manufacturing obstacles to overcome, Madigan explained. Designers in R&D were using vacuum-based technique for depositing the films in the OLED structure.

“It was very slow; it required planarization to make a smooth surface, and this didn’t do that well,” said Madigan. “There were many particle defects, and the cost was high.”

Kateeva worked with adapting inkjet technology to this process. Madigan explained that YIELDJet uses individual droplets of ink in a pattern, merges that ink together, and then uses UV lights to cure into a single layer, which has improved the quality of the films.

“Nowadays, we’re focused on broadly enabling low cost, mass production OLEDs with inkjet printing,” Madigan said. “What we’re working on now is a general deposition platform for putting down patterned films at high speed over large areas, realizing the full potential of inkjet technology for the display industry.”

In developing Kateeva’s YIELDJet, Madigan said they focused on how the glass would be handled, how to perform maintenance on a printer system that would be completely enclosed in a nitrogen environment, and managing particle decontamination.

YIELDJet employs a technique that floats a panel of glass on a vacuum and pressure holds, holding it at the very edge, which significantly reduces the size of the system when compared to conventional system which requires glass be moved on a large, often bulky holder. To address accessibility of their complicated system, Kateeva engineers made the system fully automated and able to recover quickly if it needed to be opened up to air.

“It was a new thing to make a printer that was low particle contaminating,” said Madigan. “In one of these printers, you have about ten thousand nozzles, to do fast coating.”

Kateeva was able to develop techniques to monitor all of these nozzles simultaneously, resulting in completely uniform coatings and films.

“The analysis that we’ve done with our customers is that, once they can move to inkjet printing, then you’ll quickly see OLED come down to cost parity and even be below LCD in cost,” Madigan concluded.

By Pete Singer, Editor-in-Chief

N2O, or Nitrous Oxide, also known as laughing gas, is a weak anesthetic gas that has been in use since the late 18th century. Most people have experienced nitrous in the context of dentistry, but it’s also used to make whipped cream, in auto racing, deep sea diving, or – in the semiconductor industry — as the oxygen source for chemical vapor deposition (CVD) of silicon oxy-nitride (doped or undoped) or silicon dioxide, where it is used in conjunction with deposition gases such as silane. It’s also used in diffusion, rapid thermal processing and for process chamber treatments.

The problem – and why it’s no laughing matter – is that after CO2 and CH4, N2O is the 3rd most impactful man-induced greenhouse gas (GHG), accounting for 7% of emissions. According to the U.S. Environmental Protection Agency, 5% of U.S. N2O originates from industrial manufacturing, largely semiconductor manufacturing. “It’s very much of interest because of its high global warming potential, combined with its long atmospheric lifetime of over 100 years,” said Mike Czerniak Environmental Solutions Business Development Manager, Edwards. “After PFCs, this is one of the most impactful gases from semiconductor manufacturing.” With a TLV of 50ppm, N20 is also poses a health risk.

There are two ways to get rid of N2O: reducing and oxidizing. “Reducing means getting rid of the oxygen in it so you just drive it down to be nitrogen, or you can oxidize it and add additional oxygen to it,” Czerniak explained.

Oxidizing is the easier approach in that it involves putting the gas through an ordinary flame. “The problem with doing this is you then make nitrogen oxides, NOx, and that generally is very bad because that’s the gas that’s the acid rain contributor and it also does nasty things to people,” Czerniak said. When NOx and volatile organic compounds (VOCs) react in the presence of sunlight, they form photochemical smog, a significant form of air pollution, especially in the summer. “If you do make NOx, then you probably want to do some additional treatment to try and get rid of the NOx that you’ve generated,” Czerniak said.

Reduction, therefore, is preferable. N2O can be catalytically reduced to H20 + N2. A reducing flame can be used in a combustor; this requires the presence of a reducing agent, such as methane (a commonly used fuel gas) or even a hydrogen-containing process gas such as silane. “You can avoid forming NOx if you use low temperatures, moderate amounts of oxygen, and you add a reducing agent like methane,” Czerniak said.

Edwards presently offers the Atlas series of inward-fired combustion gas abatement solutions. Atlas systems have low fuel consumption compared with previous-generation gas abatement devices and utilize proven Alzeta inward-fired combustor technology to achieve significantly reduced costs of ownership. With one to six inlets with a number of options, including a temperature management system (TMS), they can reach a flow capacity of up to 600 slm and they offer enhanced ease-of-use and more efficient maintenance.

After CO2 and CH4, N2O is the 3rd most impactful man-induced greenhouse gas (GHG). Source: Climate Analysis Indicators Tool, World Resources Institute.

After CO2 and CH4, N2O is the 3rd most impactful man-induced greenhouse gas (GHG). Source: Climate Analysis Indicators Tool, World Resources Institute.

9:00 am – 10:00 am
“CONNECT” Executive Summit
SEMI’s Denny McGuirk moderates a panel of execs from Lam, Qualcomm, Intel and Entegris
Keynote Stage

9:00 am – 3:00 pm
Women in Technology Forum
Room 304, Esplanade

12:30 am –2:00 pm
The Business Case for Supplier Diversity: Why it Matters to You
Intel presentation and panel discussion
Rm 308, Esplanade

1:00 pm – 5:00 pm
From Collision to Convergence: Co-creating Soutions in the Semiconductor and MEMS/Sensors Industries
San Francisco Marriott Marquis

2:00 pm – 4:00 pm
World of IoT Innovation
Innovation and IoT Theater

3:00 pm –4:30 pm
Bulls & Bears Panel
W Hotel