Leading semiconductor companies are making significant strides in global expansion with the announcement of two new fabrication facilities. TSMC is set to greenlight a factory in Germany, while GlobalFoundries plans to establish its first 12-inch wafer plant in Singapore.

TSMC’s Bold Move: Germany’s Green Light

TSMC from its presence in the USA, China (Shanghai and Nanjing), to Japan (Kumamoto City), TSMC’s global manufacturing footprint is expanding. Reuters reported on August 7 that TSMC’s board is inclined to approve the construction of a plant in Dresden, Germany. The German government pledges a substantial 5 billion euros (about $5.49 billion USD) to support the facility. However, the German Ministry of Economy refrains from commenting on the matter.

TSMC has been negotiating with the Saxony German state since 2021 to establish a collaborative FAB plant. In partnership with Bosch, Infineon, and Onsemi, TSMC aims to utilize the Dresden plant primarily for automotive chip production. Pending board approval, this venture could involve financing discussions with Berlin, ultimately requiring European Commission endorsement. TSMC, Intel, and Wolfspeed stand out among chip manufacturers seeking government assistance for European manufacturing ventures.

GlobalFoundries Poised to Build 12-Inch Wafer Plant in Singapore

According to udn.com, GlobalFoundries is set to make a substantial investment in the establishment of a 12-inch wafer fabrication plant in Singapore. The project’s funding could exceed NT$100 billion (approximately $3.2 billion USD). Reports suggest that this Singaporean facility will focus on producing 28-nanometer chips, with a potential completion date as early as 2026.

Industry experts note that GlobalFoundries’ move to set up a 12-inch facility in Singapore implies a significant shift in the competitive landscape. TSMC, UMC, PSMC, and GlobalFoundries – the four major semiconductor foundries – will all possess 12-inch production capabilities. Additionally, each of these companies has international expansion plans for such facilities. Notably, TSMC’s ventures span across the USA and Japan, UMC, and GlobalFoundries are both targeting Singapore, while PSMC’s strategy involves establishing a plant in Japan in collaboration with local partners.

Major Manufacturers Expand Against the Current Downturn

TSMC has been proactive in its expansion strategy, unveiling plans for ten new facilities in the past two years. These include 5 wafer plants and 2 advanced packaging facilities in Taiwan, alongside 3 overseas wafer plants. Despite the industry’s current challenges, TSMC’s expansion momentum remains strong, driven by a heightened focus on global manufacturing diversity.

TSMC is well aware of the potential risks tied to significant expansion efforts. In its latest annual report, the company acknowledges that expanding on a global scale demands substantial resources, highlighting possible challenges like rising costs, workforce shortages, disasters, land scarcity, cyber threats, government support, cultural differences, intellectual property protection, and tax variations.

Expanding during a semiconductor downturn has become a strategic approach for the foundry players. Typically, a fab construction takes 2 to 4 years, with equipment installation lasting 0.5 to 1 year and production ramp-up stretching 1 to 2 years. Looking ahead, semiconductor foundries are gearing up for a fresh wave of capacity release throughout 2024 and 2025.

Despite the industry’s ongoing slump, encouraging signs suggest that the downturn might be reaching its conclusion. Industry experts are cautiously optimistic, anticipating the arrival of the next upswing in the cycle.

(Source: https://mp.weixin.qq.com/s/4Xu_uc58kG85E_6R4Y3qhQ)

Over the past few decades, semiconductor manufacturing technology has evolved from the 10,000nm process in 1971 to the 3nm process in 2022, driven by the need to increase the number of transistors on chips for enhanced computational performance. However, as applications like artificial intelligence (AI) and AIGC rapidly advance, demand for higher core chip performance at the device level is growing.

While process technology improvements may encounter bottlenecks, the need for computing resources continues to rise. This underscores the importance of advanced packaging techniques to boost the number of transistors on chips.

In recent years, “advanced packaging” has gained significant attention. Think of “packaging” as a protective shell for electronic chips, safeguarding them from adverse environmental effects. Chip packaging involves fixation, enhanced heat dissipation, electrical connections, and signal interconnections with the outside world. The term “advanced packaging” primarily focuses on packaging techniques for chips with process nodes below 7nm.

Amid the AI boom, which has driven demand for AI servers and NVIDIA GPU graphics chips, CoWoS (Chip-on-Wafer-on-Substrate) packaging has faced a supply shortage.

But what exactly is CoWoS?

CoWoS is a 2.5D and 3D packaging technology, composed of “CoW” (Chip-on-Wafer) and “WoS” (Wafer-on-Substrate). CoWoS involves stacking chips and then packaging them onto a substrate, creating a 2.5D or 3D configuration. This approach reduces chip space, while also lowering power consumption and costs. The concept is illustrated in the diagram below, where logic chips and High-Bandwidth Memory (HBM) are interconnected on an interposer through tiny metal wires. “Through-Silicon Vias (TSV)” technology links the assembly to the substrate beneath, ultimately connecting to external circuits via solder balls.

The difference between 2.5D and 3D packaging lies in their stacking methods. 2.5D packaging involves horizontal chip stacking on an interposer or through silicon bridges, mainly for combining logic and high-bandwidth memory chips. 3D packaging vertically stacks chips, primarily targeting high-performance logic chips and System-on-Chip (SoC) designs.

When discussing advanced packaging, it’s worth noting that Taiwan Semiconductor Manufacturing Company (TSMC), rather than traditional packaging and testing facilities, is at the forefront. CoW, being a precise part of CoWoS, is predominantly produced by TSMC. This situation has paved the way for TSMC’s comprehensive service offerings, which maintain high yields in both fabrication and packaging processes. Such a setup ensures an unparalleled approach to serving high-end clients in the future.

Applications of CoWoS

The shift towards multiple small chips and memory stacking is becoming an inevitable trend for high-end chips. CoWoS packaging finds application in a wide range of fields, including High-Performance Computing (HPC), AI, data centers, 5G, Internet of Things (IoT), automotive electronics, and more. In various major trends, CoWoS packaging is set to play a vital role.

In the past, chip performance was primarily reliant on semiconductor process improvements. However, with devices approaching physical limits and chip miniaturization becoming increasingly challenging, maintaining small form factors and high chip performance has required improvements not only in advanced processes but also in chip architecture. This has led to a transition from single-layer chips to multi-layer stacking. As a result, advanced packaging has become a key driver in extending Moore’s Law and is leading the charge in the semiconductor industry.

(Photo credit: TSMC)

According to the news from Commercial Times, in a recent press conference, the four major American cloud service providers (CSPs) collectively expressed their intention to expand their investment in AI application services. Simultaneously, they are continuing to enhance their cloud infrastructure. Apple has also initiated its foray into AI development, and both Intel and AMD have emphasized the robust demand for AI servers. These developments are expected to provide a significant boost to the post-market prospects of Taiwan’s AI server supply chain.

Industry insiders have highlighted the ongoing growth of the AI spillover effect, benefiting various sectors ranging from GPU modules, substrates, cooling systems, power supplies, chassis, and rails, to PCB manufacturers.

The American CSP players, including Microsoft, Google, Meta, and Amazon, which recently released their financial reports, have demonstrated growth in their cloud computing and AI-related service segments in their latest quarterly performance reports. Microsoft, Google, and Amazon are particularly competitive in the cloud services arena, and all have expressed optimistic outlooks for future operations.

The direct beneficiaries among Taiwan’s cloud data center suppliers are those in Tier 1, who are poised to reap positive effects on their average selling prices (ASP) and gross margins, driven by the strong demand for AI servers from these CSP giants in the latter half of the year.

Among them, the ODM manufacturers with over six years of collaboration with NVIDIA in multi-GPU architecture AI high-performance computing/cloud computing, including Quanta, Wistron, Wistron, Inventec, Foxconn, and Gigabyte, are expected to see operational benefits further reflected in the latter half of the year. Foxconn and Inventec are the main suppliers of GPU modules and GPU substrates, respectively, and are likely to witness noticeable shipment growth starting in the third quarter.

Furthermore, AI servers not only incorporate multiple GPU modules but also exhibit improvements in aspects such as chassis height, weight, and thermal design power (TDP) compared to standard servers. As a result, cooling solution providers like Asia Vital Components, Auras Technology, and SUNON; power supply companies such as Delta Electronics and Lite-On Technology; chassis manufacturers Chenbro; rail industry players like King Slide, and PCB/CCL manufacturers such as EMC, GCE are also poised to benefit from the increasing demand for AI servers.

(Source: https://ctee.com.tw/news/tech/915830.html)

Last week, major power semiconductor manufacturer Infineon announced plans to invest up to 5 billion euros over the next five years to construct the world’s largest 8-inch SiC power wafer factory in Kulim, Malaysia. This expansion will raise the total investment in the Kulim plant from 2 billion euros to 7 billion euros.

Interestingly, in February of this year, Wolfspeed announced its own plans to build what is touted as the world’s largest 8-inch SiC factory in the Saarland region of Germany. Infineon’s significant investment in the Malaysian 8-inch SiC factory sets the stage for potential competition with Wolfspeed, sparking an impending battle for Silicon Carbide production capacity.

In fact, driven by the rapid growth of industries like electric vehicles, the space for SiC power devices is expanding, attracting both Chinese companies and international enterprises to ramp up production.

According to statistics from TrendForce, aside from Wolfspeed, the first half of this year saw numerous companies, including STMicroelectronics, Mitsubishi Electric, Rohm, Soitec, and ON Semiconductor, expanding their production capacities. STMicroelectronics, for instance, announced a $4 billion investment in January to expand 12-inch wafer production. In June, they partnered with San’an Optoelectronics to establish a joint venture for 8-inch SiC device manufacturing, with an estimated total investment of around $3.2 billion.

On the Chinese front, there have been seven expansion projects related to Silicon Carbide. CRRC is investing 11.12 billion yuan to establish a project for the industrialization of medium and low-voltage power devices. YASC is also planning to construct a Compound Semiconductor power device production project, encompassing epitaxial growth, wafer manufacturing, packaging, and testing lines. Upon completion, the facility will have an annual production capacity of 360,000 6-inch SiC wafers and 61 million power device modules.

Additionally, BYD plans to invest 200 million yuan to establish a SiC epitaxial trial production and mass production project at its automotive production base in Shenzhen. The expansion will add 6,000 SiC epitaxial wafers per year, bringing the total capacity to 18,000 wafers per year.

(Photo credit: Tesla)

According to the latest report from TrendForce, the primary factors influencing the global market share of notebook CPUs in 2024 can be categorized into “Architectural Design” and “Economic Factors.”

“Architectural Design” as a long-term factor affecting market share:

(1) Both AMD (AMD 3D V-Cache) and Intel (Intel Foveros Direct) may potentially integrate 3D packaging technology into notebook computers in the future.

(2) Apple’s M-series processors, using the Arm core architecture, as well as Intel processors, have adopted a big/little core hybrid design. AMD might also introduce this in the Ryzen 8000 series.

(3) Despite further advancements in processor technology by 2024, the notebook computer market remains highly sensitive to the cost for IT equipment.

“Economic Factors” as more immediate influencers of market share:

(1) Until 2024, a return to lower interest rates in the global economic environment could favor corporate expansion of capital expenditure. This could result in increased procurement of business-oriented notebook models, potentially allowing Intel to further expand its CPU market share beyond 70% in the business sector.

(2) Concerns about economic prospects among global citizens until 2024 could have significant negative implications for the consumer notebook computer market. With the restart of physical economic activities, the demand for consumer-oriented notebook models has declined from the high levels seen during the pandemic. Consequently, the consumer market demand outlook for 2024 remains uncertain. For AMD, which relies more on consumer market demand, changes in market share may be harder to predict compared to Intel.

In the post-pandemic era, AMD, Arm/Apple, and Intel are pursuing distinct technological competition strategies to capture market share in the personal computing market.

AMD:

(1) The Socket AM5 platform is poised to aid AMD CPUs in achieving substantial performance and efficiency gains.

(2) The AMD Ryzen 7040 incorporates an artificial intelligence engine to emphasize AI computing performance’s importance in the thin and light notebook market.

Arm/Apple:

(1) The M2 Ultra processor heralds Apple’s complete transition of personal computing products to the Arm core. Apple Mac computer products will no longer be sold with Intel processor.

(2) The Apple M-series processors, built on the Arm core architecture, facilitate a “fanless design” to maintain MacBook’s slim profile. This feature highlights its irreplaceable positioning in the portable notebook computer market, emphasizing portability.

Intel:

(1) With the waning trend of the “hybrid work mode,” Intel is optimistic about diversified development in the post-pandemic era for desktop computer products. This includes microcomputers, micro workstations, and general workstations. Due to the characteristic of continuous operation for 24 hours, desktop computers still possess unique attributes that cannot be replaced by notebook computers.

(Photo credit: Intel)