ROHM and <span style='color:red'>TSM</span>C Launch Strategic Gallium Nitride Technology Collaboration for Automotive Industry
  ROHM Co., Ltd. (ROHM) announced today that ROHM and TSMC have entered a strategic partnership on development and volume production of gallium nitride (GaN) power devices for electric vehicle applications.  The partnership will integrate ROHM's device development technology with TSMC's industry-leading GaN-on-silicon process technology to meet the growing demand for superior high-voltage and high-frequency properties over silicon for power devices.  GaN power devices are currently used in consumer and industrial applications such as AC adapters and server power supplies. TSMC, a leader in sustainability and green manufacturing, supports GaN technology for its potential environmental benefits in automotive applications, such as on-board chargers and inverters for electric vehicles (EVs).  The partnership builds on ROHM and TSMC’s history of collaboration in GaN power devices. In 2023, ROHM adopted TSMC’s 650V GaN high-electron mobility transistors (HEMT), whose process is increasingly being used in consumer and industrial devices as part of ROHM's EcoGaN™ series, including the 45W AC adapter (fast charger) "C4 Duo" produced by Innergie, a brand of Delta Electronics, Inc.  "GaN devices, capable of high-frequency operation, are highly anticipated for their contribution to miniaturization and energy savings, which can help achieve a decarbonized society. Reliable partners are crucial for implementing these innovations in society, and we are pleased to collaborate with TSMC, which possesses world-leading advanced manufacturing technology" said Katsumi Azuma, Member of the Board and Senior Managing Executive Officer at ROHM. “In addition to this partnership, by providing user-friendly GaN solutions that include control ICs to maximize GaN performance, we aim to promote the adoption of GaN in the automotive industry."  “As we move forward with the next generations of our GaN process technology, TSMC and ROHM are extending our partnership to the development and production of GaN power devices for automotive applications,” said Chien-Hsin Lee, Senior Director of Specialty Technology Business Development at TSMC. “By combining TSMC's expertise in semiconductor manufacturing with ROHM's proficiency in power device design, we strive to push the boundaries of GaN technology and its implementation for EVs.”  About TSMC  TSMC pioneered the pure-play foundry business model when it was founded in 1987, and has been the world’s leading dedicated semiconductor foundry ever since. The Company supports a thriving ecosystem of global customers and partners with the industry’s leading process technologies and portfolio of design enablement solutions to unleash innovation for the global semiconductor industry. With global operations spanning Asia, Europe, and North America, TSMC serves as a committed corporate citizen around the world.          TSMC deployed 288 distinct process technologies, and manufactured 11,895 products for 528 customers in 2023 by providing broadest range of advanced, specialty and advanced packaging technology services. The Company is headquartered in Hsinchu, Taiwan.  EcoGaN™ is a trademark or registered trademark of ROHM Co., Ltd.
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Release time:2025-04-02 15:36 reading:253 Continue reading>>
IC Design Companies Seek Advanced Process Second Source, Overview of Competition Between <span style='color:red'>TSM</span>C and Samsung
  According to TechNews’ report, Apple, NVIDIA, AMD, Qualcomm, and MediaTek all utilize TSMC’s semiconductor processes for manufacturing their latest chips, with some potentially employing Samsung’s foundry, though typically not for flagship products.  With Samsung’s improved yield rates in recent months, the company is eager to secure a portion of the orders, particularly for the 3-nanometer GAA (Gate-All-Around) process.  Earlier market reports suggested that Qualcomm’s Snapdragon 8 Gen 4 might adopt a dual-foundry strategy, simultaneously utilizing TSMC’s N3E process technology and Samsung’s SF3E process technology.  However, both Qualcomm and MediaTek currently plan to employ TSMC’s second-generation 3-nanometer process technology (N3E) for manufacturing chips like the Snapdragon 8 Gen 4 and Dimensity 4, without pursuing a dual-foundry strategy at this time.  As of the end of June 2022, Samsung announced the commencement of production for 3-nanometer process chips at its Hwaseong Industrial Complex in South Korea. These chips incorporate a new GAA transistor architecture technology, rumored to be more energy-efficient compared to TSMC’s 3-nanometer FinFET technology. Despite this, in the realm of 3nm, Samsung has yet to secure substantial orders from major clients.  Interestingly, the company has seen more success in the 4nm domain. It is reported that Samsung has gradually addressed yield and various issues in the 4-nanometer process technology domain. The third generation of 4-nanometer process technology has seen improvements in performance, reduced power consumption, increased density, and achieved yields close to TSMC’s level. Market sources indicate that Samsung has gained recognition from companies like AMD and Tesla, securing new orders.  Currently, TSMC’s 3-nanometer process technology production capacity is ramping up, with an expected monthly capacity of 100,000 wafers by the end of 2024. The revenue contribution is projected to increase from the current 5% to 10%.  Meanwhile, Samsung plans to introduce the second generation of its 3-nanometer process technology, named SF3 (3GAP), in 2024. Building upon the existing SF3E, it aims for further optimization, and Samsung’s in-house Exynos 2500 is expected to be one of the first high-performance chips to adopt this new process technology.
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Release time:2023-11-27 13:51 reading:1823 Continue reading>>
Intel’s Next Gen CPU to Produce at <span style='color:red'>TSM</span>C with 3nm in First Half of Next Year
  Intel’s upcoming Lunar Lake platform has entrusted TSMC with the 3nm process of its CPU. This marks TSMC’s debut as the exclusive producer for Intel’s mainstream laptop CPU, including the previously negotiated Lunar Lake GPU and high-speed I/O (PCH) chip collaborations. This move positions TSMC to handle all major chip orders for Intel’s crucial platform next year, reported by UDN News.  Regarding this news, TSMC refrained from commenting on single customer business or market speculations on November 21st. Intel has not issued any statements either.  Recent leaks of Lunar Lake platform internal design details from Intel have generated discussions on various foreign tech websites and among tech experts on X (formerly known as Twitter). According to the leaked information, TSMC will be responsible for producing three key chips for Intel’s Lunar Lake—CPU, GPU, and NPU—all manufactured using the 3nm process. Orders for high-speed I/O chips are expected to leverage TSMC’s 5nm production, with mass production set to kick off in the first half of next year, aligning with the anticipated resurgence of the PC market in the latter half of the year.  While TSMC previously manufactured CPUs for Intel’s Atom platform over a decade ago, it’s crucial to note that the Atom platform was categorized as a series of ultra-low-voltage processors, not Intel’s mainstream laptop platform. In recent years, Intel has gradually outsourced internal chips, beyond CPUs, for mainstream platforms to TSMC, including the GPU and high-speed I/O chips in the earlier Meteor Lake platform—all manufactured using TSMC’s 5nm node.  Breaking from its tradition of in-house production of mainstream platform CPUs, Intel’s decision to outsource to TSMC hints at potential future collaborations. This move opens doors to new opportunities for TSMC to handle the production of Intel’s mainstream laptop platforms.  It’s worth noting that the Intel Lunar Lake platform is scheduled for mass production at TSMC in the first half of next year, with a launch planned for the latter half of the year, targeting mainstream laptop platforms. Unlike the previous two generations of Intel laptop platforms, Lunar Lake integrates CPU, GPU, and NPU into a system-on-chip (SoC). This SoC is then combined with a high-speed I/O chip, utilizing Intel’s Foveros advanced packaging. Finally, the DRAM LPDDR5x is integrated with the two advanced packaged chips on the same IC substrate.
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Release time:2023-11-22 11:18 reading:1912 Continue reading>>
Microsoft First In-House AI Chip “Maia” Produced by <span style='color:red'>TSM</span>C’s 5nm
  On the 15th, Microsoft introducing its first in-house AI chip, “Maia.” This move signifies the entry of the world’s second-largest cloud service provider (CSP) into the domain of self-developed AI chips. Concurrently, Microsoft introduced the cloud computing processor “Cobalt,” set to be deployed alongside Maia in selected Microsoft data centers early next year. Both cutting-edge chips are produced using TSMC’s advanced 5nm process, as reported by UDN News.  Amidst the global AI fervor, the trend of CSPs developing their own AI chips has gained momentum. Key players like Amazon, Google, and Meta have already ventured into this territory. Microsoft, positioned as the second-largest CSP globally, joined the league on the 15th, unveiling its inaugural self-developed AI chip, Maia, at the annual Ignite developer conference.  These AI chips developed by CSPs are not intended for external sale; rather, they are exclusively reserved for in-house use. However, given the commanding presence of the top four CSPs in the global market, a significant business opportunity unfolds. Market analysts anticipate that, with the exception of Google—aligned with Samsung for chip production—other major CSPs will likely turn to TSMC for the production of their AI self-developed chips.  TSMC maintains its consistent policy of not commenting on specific customer products and order details.  TSMC’s recent earnings call disclosed that 5nm process shipments constituted 37% of Q3 shipments this year, making the most substantial contribution. Having first 5nm plant mass production in 2020, TSMC has introduced various technologies such as N4, N4P, N4X, and N5A in recent years, continually reinforcing its 5nm family capabilities.  Maia is tailored for processing extensive language models. According to Microsoft, it initially serves the company’s services such as $30 per month AI assistant, “Copilot,” which offers Azure cloud customers a customizable alternative to Nvidia chips.  Borkar, Corporate VP, Azure Hardware Systems & Infrastructure at Microsoft, revealed that Microsoft has been testing the Maia chip in Bing search engine and Office AI products. Notably, Microsoft has been relying on Nvidia chips for training GPT models in collaboration with OpenAI, and Maia is currently undergoing testing.  Gulia, Executive VP of Microsoft Cloud and AI Group, emphasized that starting next year, Microsoft customers using Bing, Microsoft 365, and Azure OpenAI services will witness the performance capabilities of Maia.  While actively advancing its in-house AI chip development, Microsoft underscores its commitment to offering cloud services to Azure customers utilizing the latest flagship chips from Nvidia and AMD, sustaining existing collaborations.  Regarding the cloud computing processor Cobalt, adopting the Arm architecture with 128 core chip, it boasts capabilities comparable to Intel and AMD. Developed with chip designs from devices like smartphones for enhanced energy efficiency, Cobalt aims to challenge major cloud competitors, including Amazon.
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Release time:2023-11-17 16:00 reading:1744 Continue reading>>
Intense Competition in Advancing Processes at the 2nm by Samsung, Intel, and <span style='color:red'>TSM</span>C
  According to TechNews’ report, Gitae Jeong, Vice President of Samsung Electronics, recently revealed in an interview that the company is set to introduce the SF1.4 (1.4nm) process, expected to enter mass production in 2027.  This announcement intensifies the competition in advanced semiconductor manufacturing, particularly in the development of 2.5D/3D integrated heterogeneous structure packaging among the three major semiconductor foundry giants.  *TSMC: N3P Process Superior to Intel 18A, N2 to Lead Industry’s Advanced Processes  Previously, the semiconductor industry reported challenges with both TSMC and Samsung achieving yields above 60% for their 3nm processes due to undisclosed issues. TSMC’s yield was reported to be only 55%, below the normal yield rate.  However, TSMC’s President, C.C. Wei, expressed optimism, stating that current N3 demand is better than three months ago, contributing to a healthy growth outlook for TSMC in 2024.  Wei also anticipates that TSMC’s 3nm process will contribute a mid-single-digit percentage (4%-6%) to the company’s annual wafer revenue in 2023.  Regarding competition with rival Intel’s 18A process, Wei believes that TSMC’s N3P process offers better performance, power, and area (PPA), alongside improved cost efficiency and technical maturity. Furthermore, TSMC’s upcoming N2 process is expected to be the industry’s most advanced when introduced.  *Intel: Striving for the Fourth Customer for 18A Process Outsourcing Orders  Intel’s CEO, Pat Gelsinger, has revealed that the 18A process has secured orders from three customers and aims to acquire a fourth customer by the end of the year. The advanced 18A process is scheduled to begin production at the end of 2024, with one customer already having made an advance payment. External expectations suggest that the customer could possibly be NVIDIA or Qualcomm.  Intel has stated that Intel 4 and Intel 3 processes are similar, as are Intel 20A and Intel 18A processes. Consequently, Intel’s primary focus will be on offering Intel 3 and Intel 18A to semiconductor foundry customers. Meanwhile, Intel 4 and Intel 20A processes are more likely to be used internally. However, Intel is open to accommodating customer requests if they express interest in adopting these later processes.  *Samsung: Commencing Mass Production of SF2 in 2025, Prioritizing Internal Use  Due to challenges with the three-nanometer (3nm) manufacturing process, there have been reports that Samsung plans to shift directly to the more advanced two-nanometer (2nm) process.  According to Samsung’s Foundry Forum (SFF) plan, they will begin mass production of the 2nm process (SF2) in 2025 for mobile applications, expand to high-performance computing (HPC) applications in 2026, and further extend to the automotive sector and the expected 1.4nm process by 2027.  Similar to Intel, Samsung intends to prioritize the production of its own products using the 2nm process. The 2nm process products will initially be utilized for Samsung’s in-house products rather than external customer products.  *Summary  While TSMC’s N3 series currently enjoys broad support, including N3E, N3X, and N3P process series, the move to 2nm introduces new variables as it adopts a completely new GAAFET architecture. Regardless, whether it’s TSMC’s N2, Intel’s 18A, or Samsung’s SF2, each of them possesses its competitive strengths. The industry is also eagerly anticipating the future developments in advanced semiconductor processes.
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Release time:2023-11-03 14:50 reading:1543 Continue reading>>
<span style='color:red'>TSM</span>C’s Capacity and Orders Surge, Is the Semiconductor Industry Bouncing Back?
  As reported by China Taiwanese media, there’s a gradual uptick in TSMC’s capacity utilization lately, accompanied by a noticeable surge in orders from TSMC’s clients. Some segments of the market are showing signs of rekindled demand, hinting at a possible upswing in the semiconductor industry. Nevertheless, certain semiconductor manufacturing firms remain cautious in their industry outlook.  TSMC’s Capacity Utilization Rate on the Rise  Media’s report indicates that TSMC’s capacity utilization rate has gradually recovered. The 7/6nm utilization, which had dropped to 40% at one point, is now around 60% and could potentially reach 70% by the end of the year. Similarly, the 5/4nm utilization is at 75-80%, and the 3nm capacity, which increases seasonally, is approximately 80%.  Concurrently, TSMC is experiencing a significant uptick in orders from their clients, including tech giants like Apple, MediaTek, NVIDIA, AMD, Intel, Broadcom, Marvell, and STMicroelectronics. Furthermore, AI chip clients such as AMD’s subsidiary Xilinx, Amazon, Cisco, Google, Microsoft, and Tesla have all accepted TSMC’s plan for a price increase in 2024.  Taking Tesla as an example, they are building a supercomputer facility in Austin to accelerate the development of their autonomous driving system, expanding the computing power of Dojo. The core D1 of Dojo is produced using TSMC’s 7nm process and advanced packaging technology. Based on this, Tesla is deepening its collaboration with TSMC, and it’s expected that their order volume will increase from around 5,000 pieces this year to 10,000 pieces next year.  Amid the ongoing AI surge, NVIDIA is actively seeking additional production capacity. On October 19th, NVIDIA’s CEO, Jensen Huang, revealed in an interview that the global demand for AI chips remains robust. He has met with TSMC’s CEO, C.C. Wei, to discuss providing more capacity to serve customers. NVIDIA is in the planning stages for the next generation of chips designed for AI-based infrastructure and has also engaged in discussions with partners such as Quanta and ASUS to strategize collaboration.  Is the Semiconductor Industry on the Rebound?  During TSMC’s Q3 earnings call, C.C. Wei pointed out that, in addition to strong AI demand, there’s a rebound in demand for smartphones and personal computers. As for automotive electronics, benefiting from the continued growth of electric vehicles, the demand for next year is expected to be quite robust. Regarding when the semiconductor industry might hit bottom, Wei remarked that there are some early signs appearing in the PC and mobile phone sectors. However, it remains challenging to predict a strong resurgence as customers are still cautiously managing their inventories.  In response to industry concerns about smartphone growth, TSMC’s CFO, Wendell Huang, noted that smartphone growth is anticipated to remain lower than the company’s future growth rate. High-Performance Computing (HPC) is expected to be the most robust growth segment, making substantial contributions to growth in the coming years.  On the other hand, other semiconductor foundry companies, such as PSMC, have also shared their perspectives on the fourth quarter and future industry developments. Recently, PSMC’s President, Brian Shieh, pointed out that the supply chain’s inventory seems to have reached a reasonable level, with growing demand for mobile panel driver ICs, surveillance system CIS chips, and visibility extending beyond one quarter. Prices for special memory products have started to show an upward trend. Demand for Power Management ICs (PMIC) also displays signs of recovery, even though the trend isn’t as pronounced as that of driver ICs and CIS chips.  Regarding UMC, the company is scheduled to hold an earning call on 25th October. In their previous earnings call for the last quarter, UMC mentioned that due to ongoing adjustments in the supply chain’s inventory, the outlook for wafer demand remains uncertain. Although the industry glimpsed a modest recovery in the second quarter, the overall sentiment in the end-market remains subdued, and customers continue to maintain stringent inventory management practices.
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Release time:2023-10-25 11:18 reading:1504 Continue reading>>
Intel, Samsung, <span style='color:red'>TSM</span>C Race in Cutting-Edge Processes
  Driven by emerging technologies like AI and high-performance computing, the semiconductor foundry industry increasingly emphasizes the importance of advanced manufacturing processes. Recently, the industry has seen significant developments. Intel announced that it has commenced large-scale production of its Intel 4 process node, while TSMC and Samsung are equally committed to advancing their advanced process technologies.  Intel’s Mass Production of Intel 4 Process Node  On October 15th, Intel China’s official public account revealed that Intel has initiated large-scale production of the Intel 4 process node using Extreme Ultraviolet Lithography (EUV) technology. According to Intel, they are making significant progress with their “Four Years, Five Nodes” plan. This plan aims to produce next-generation products that meet the computational demands driven by AI’s role in the “Siliconomy.”  Being the first process node produced by Intel using EUV lithography technology, Intel 4 offers substantial improvements in performance, efficiency, and transistor density compared to its predecessors. Intel 4 was unveiled at the Intel Innovation 2023 held in September this year.  In comparison to Intel 7, Intel 4 achieves a 2x reduction in area, providing high-performance computing (HPC) logic libraries and incorporating various innovative features.  In detail, Intel 4 simplifies the EUV lithography process, optimizing it for high-performance computing applications, supporting both low voltage (<0.65V) and high voltage (>1.1V) operations. Compared to Intel 7, Intel 4 boasts more than a 20% improvement in iso-power performance, and high-density Metal-Insulator-Metal (MIM) capacitors deliver outstanding power supply performance.  Intel’s “Four Years, Five Nodes” plan is advancing with the following process updates:  Intel 7 and Intel 4 are currently in large-scale production. Intel 3 is on track to meet its planned target by the end of 2023.  Intel’s Intel 20A and Intel 18A, which use Ribbon FET all-around gate transistors and PowerVia backside power delivery technology, are also progressing well, with a target of 2024. Intel will soon introduce the Intel 18A process design kit (PDK) for Intel Foundry Services (IFS) customers.  With the adoption of Intel 4 process nodes, the Intel Core i9 Ultra processor, codenamed “Meteor Lake,” will be released on December 14th this year, ushering in the AIPC era.  On Intel 3 process nodes, the energy-efficient E-core Sierra Forest processor will be launched in the first half of 2024, and the high-performance P-core Granite Rapids processor will follow closely.  Samsung’s 2nm Process Detailed Production Plan  Samsung has already commenced production of its second-generation 3nm chips and plans to continue focusing on 2nm chips.  On June 28th, Samsung Electronics unveiled its latest foundry technology innovations and business strategies at the 7th Samsung Foundry Forum (SFF) in 2023.  In the era of artificial intelligence, Samsung’s foundry program, based on advanced GAA process technology, offers robust support for customers in AI applications. To this end, Samsung has disclosed a detailed production plan and performance levels for its 2nm process. The plan is to achieve mass production for mobile applications by 2025 and respectively expand to HPC and automotive electronics in 2026 and 2027.  Samsung reports that the 2nm process (SF2) improves performance by 12% compared to the 3nm process (SF3), increases efficiency by 25%, and reduces the area by 5%.  Furthermore, reports indicated that Samsung is ensuring the production capacity for products using the next-generation EUV lithography machine, High-NA, in September. This equipment is expected to have a prototype by the end of this year and officially enter production next year.  TSMC’s Mass Production of 2nm by 2025  This year, TSMC has unveiled its latest advanced semiconductor manufacturing roadmap in various locations, including Santa Clara, California, and Taiwan. The roadmap covers a range of processes from 3nm to 2nm.  TSMC’s current roadmap for 3nm includes N3, N3E, N3P, N3X, and N3 AE, with N3 serving as the foundational version, N3E as an enhanced version with further cost optimization, N3P focusing on improved performance with a planned start in the second half of 2024, N3X targeting high-performance computing devices with a mass production goal in 2025, and N3 AE designed specifically for the automotive sector, offering greater reliability and the potential to shorten time-to-market by 2-3 years.  In the 2nm realm, TSMC is planning to achieve mass production of the N2 process by 2025. TSMC has reported that the N2 process will offer a 15% speed improvement over N3E at the same power or a 30% reduction in power consumption, with a 15% increase in transistor density. In September, media reports revealed that TSMC has formed a task force to accelerate 2nm pilot production and mass production, aiming for risk production next year and official mass production in 2025.  To ensure the smooth development of 2nm process technology, TSMC has initiated efforts in the upstream equipment sector. On September 12th, TSMC announced the acquisition of a 10% stake in IMS Nanofabrication, a subsidiary of Intel, for a price not exceeding $432.8 million. IMS specializes in the research and production of electron beam lithography machines, which find extensive applications in semiconductor manufacturing, optical component manufacturing, MEMS manufacturing, and more. The industry sees TSMC’s IMS acquisition as vital for developing crucial equipment and meeting the demand for 2nm process commercialization.
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Release time:2023-10-18 13:12 reading:1479 Continue reading>>
<span style='color:red'>TSM</span>C Expected to Lower Capital Expenditure, Potentially Falling Below $30 Billion for the Year
  As TSMC’s earnings call approaches, the market is abuzz with rumors that the company may revise down its capital expenditure target for this year. This potential adjustment is believed to be driven by delays in Intel’s 3-nanometer outsourcing and the deferral of the production schedule for TSMC’s 4-nanometer US fab. The initial capital expenditure target, which was close to the $32 billion to $36 billion range, may now be lowered to below $30 billion, marking its lowest point in nearly three years.  According to Taiwan’s Economic Daily, TSMC has refrained from commenting on these speculations. Even if TSMC does adjust its capital expenditure for this year, industry sources suggest that the company will increase its annual R&D expenses, continuing its commitment to advanced research and development.  In recent years, TSMC has rapidly expanded its capital expenditure, reaching a record high of $36.3 billion last year. In the first half of this year, the actual capital expenditure amounted to $18.11 billion, including $8.17 billion in the second quarter, slightly down from the $9.94 billion in the first quarter.  During their July earnings conference, TSMC stated that their capital expenditure for the year would remain in the range of $32 billion to $36 billion. However, considering market dynamics, the actual expenditure for the full year is expected to be towards the lower end of this range.  The latest reports suggest that due to the delays in Intel’s 3-nanometer outsourcing and the postponement of the 4-nanometer production schedule at the US fab, approximately $4 billion originally earmarked for this year’s capital expenditure may be postponed until next year, resulting in capital expenditure for this year falling below $30 billion. As for next year’s capital expenditure, it may remain on par with this year.  ASML, a leading supplier of semiconductor lithography equipment, previously revealed in its July earnings conference that there were delays in shipments of EUV equipment due to installation delays at customer factories. However, ASML maintained a robust order backlog and expects overall performance to continue growing in 2024.  Industry experts believe that the “installation delays” mentioned by ASML at that time were related to TSMC, and because of the delay in EUV equipment installation, TSMC’s capital expenditure for this year may be deferred accordingly.  Analysts in the industry suggest that if we consider TSMC’s earlier projection of capital expenditure falling within the $32 billion to $36 billion range, and subtract the actual expenses incurred in the first half of the year, the capital expenditure for the second half of the year could see a decline, estimated to be around $13.89 billion or more. If the postponement rumors materialize, second-half capital expenditure might fall below $10 billion.
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Release time:2023-10-17 11:03 reading:1622 Continue reading>>
<span style='color:red'>TSM</span>C’s 2nd Plant in Japan May Receive Up to 900 Billion JPY Subsidy
  TSMC is in the process of constructing a semiconductor factory in Kikuyo-cho, Kumamoto Prefecture, Kyushu, Japan (referred to as Plant 1). Production is expected to commence in December 2024. Besides this facility, TSMC has shown interest in establishing a second plant in Japan (referred to as Plant 2). According to Japanese reports, the government is considering providing TSMC with a substantial subsidy of up to 900 billion Japanese Yen for Plant 2.  On October 4, during the Public-Private Partnership Forum on Increasing Domestic Investment led by Japanese Prime Minister Fumio Kishida, plans were announced for economic measures to be finalized within October. The Ministry of Economy, Trade, and Industry of Japan (METI) will request a budget of 3.4 trillion Japanese Yen to establish three funds supporting semiconductor production and research and development. These funds are the ” Research and Development Project of the Enhanced Infrastructures for Post-5G Information and Communication Systems,” the “Specified Semiconductor Funding Program,” and the “Ensuring Stable Supply Support Fund.”  As reported by Asahi Shimbun, sources suggest that the METI deems it necessary to grant 900 billion Japanese Yen in subsidies for TSMC’s proposed Plant 2, nearly 600 billion Japanese Yen for the “Rapidus” national team aiming to produce next-gen semiconductor chips domestically, and 700 billion Japanese Yen for traditional chips like Sony CMOS image sensors.  The Japanese government will allocate the required funds for these economic measures in the 2023 fiscal year supplementary budget. If the METI’s budget request is approved, the budget for semiconductor-elated activities in the 2023 fiscal year supplementary budget (3.4 trillion Japanese Yen) will be 2.6 times higher than that in the 2022 fiscal year supplementary budget (1.3 trillion Japanese Yen).  The Kishida administration also announced plans to ease land restrictions for crucial manufacturing facilities such as semiconductor plants during the forum. As early as December, local governments will be able to issue development permits for agricultural land, forests, and other areas.  Before that, local governments could only grant permits for industries related to food logistics, data centers, and plant facilities. Now, this is being expanded to include vital strategic materials. Furthermore, changing the land category from agricultural land often required approvals from multiple government departments, a process that could take more than a year. In the future, these procedures are expected to be shortened to around four months.
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Release time:2023-10-13 11:03 reading:1523 Continue reading>>
Advanced Packaging in High Demand, <span style='color:red'>TSM</span>C and OAST Increasing Equipment Orders
  As AI demand continues to surge, TSMC (Taiwan Semiconductor Manufacturing Company) has initiated an extensive expansion plan for its CoWoS (Chip-on-Wafer-on-Substrate) production. Within the industry, reports suggest that TSMC, a leading semiconductor foundry, placed a significant wave of orders with Taiwanese equipment manufacturers last week, creating a notable impact.  Additionally, outsourced semiconductor assembly and testing (OSAT) giants, which were originally inquiring about orders, have also significantly increased their orders for advanced packaging. This wave of orders is estimated to be fulfilled between March and April of the upcoming year.  The growth in demand for advanced semiconductor processes due to AI applications necessitates advanced packaging technologies to keep pace. With packaging technologies advancing from 2D and 2.5D to the more advanced 3D IC (Integrated Circuit) configurations, the number of IC stacking layers is increasing, leading to a greater demand for advanced packaging equipment. Considering the current emphasis on CoWoS technology, the industry estimates that production capacity will reach 12,000 to 14,000 wafers in 2023 and double to over 30,000 wafers in 2024.  According to a report by Taiwan’s Money DJ, information from equipment industry sources reveals that TSMC recommenced orders for CoWoS equipment in April 2023, with a second wave of orders in June. Subsequently, sporadic additional orders were placed, and last week witnessed a new significant wave of orders, surprising many.  An anonymous executive from a Taiwanese equipment company expressed that they initially believed TSMC’s orders for CoWoS equipment had concluded, making the recent wave of orders even more unexpected. Furthermore, the increase in orders for advanced packaging equipment by semiconductor testing and packaging facilities is also seen as encouraging.  Market experts believe that semiconductor testing and packaging facilities and semiconductor foundries have different positions and advantages in the advanced packaging market. Their cooperative relationships outweigh their competition. Major OSAT players like ASE, Amkor, and JCET have long possessed advanced packaging technology and are positioned to become an alternative choice for major foundries due to their technical upgrades and competitive pricing. In other words, top-tier orders from customers will be firmly in TSMC’s grasp, while other opportunities will likely be pursued by SATS companies.  Regarding the supply of CoWoS equipment, suppliers like Scientech have received over 30 orders for wet etching processing equipment, while Grand Process Technology and others have shipped nearly 20 units. Meanwhile, G2C+ Alliance members such as GMM and C Sun have reportedly received over 40 orders from the TSMC’s Longtan factory.
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Release time:2023-10-12 11:10 reading:1903 Continue reading>>

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