18 Months, Over 50x Surge: KIOXIA's Epic Comeback

marsbit發佈於 2026-06-23更新於 2026-06-23

文章摘要

KIOXIA, a NAND flash memory giant, staged a dramatic comeback driven by AI demand. After a period of significant losses, a failed merger, and missed HBM opportunities, its 2024 IPO began modestly. However, fueled by explosive demand for AI data storage, its stock price skyrocketed over 50 times within 18 months, making it Japan's most valuable company, surpassing Toyota. Its Q1 FY2026 profit guidance soared 30-fold year-over-year, with 2026 NAND capacity already sold out. Key to its success is its 3D NAND technology, BiCS FLASH. As the inventor of NAND, KIOXIA advanced its technology through generations, reaching over 200 layers by 2023. Key innovations include CBA (CMOS directly Bonded to Array), which separately manufactures control circuits and memory arrays for better performance, and OPS (On Pitch Select Gate) to increase density. The company is now developing high-capacity packages like an 8TB solution stacking 32 dies. Looking beyond NAND, KIOXIA is exploring 3D DRAM with its OCTRAM technology, using oxide semiconductor transistors for ultra-low leakage to reduce power consumption. This fundamental research differs from HBM and represents a long-term bet to extend its 3D expertise from NAND into future DRAM architectures. KIOXIA's story highlights how technological assets and shifting market cycles can rapidly transform a company's fortunes. While questions remain about sustaining growth beyond the current AI boom, its resurgence demonstrates that in semiconductors,...

Author: Du Qin DQ

Previously, we have deeply analyzed this flash memory giant's regrettable trough period in another article: burdened by the past glory of Toshiba Memory but 'born at the wrong time'; cold-shouldered by the capital markets, leading to a last-minute IPO setback; suffering consecutive huge losses in an industry downturn, and unfortunately missing out on the enormous opportunity of HBM, with even its attempt to seek refuge through a merger with Western Digital falling through... At that time, KIOXIA seemed to have become a 'hot potato' in the eyes of outsiders amid the semiconductor industry reshuffle.

However, just over a year later, KIOXIA staged a comeback that can be described as epic. Driven by the frenzy of AI large models, the market logic for storage underwent a fundamental shift. KIOXIA not only successfully reversed its fortunes but also achieved a dual explosion in both capital markets and technology.

KIOXIA's stock price trend since listing

The Super Myth in the Capital Markets

KIOXIA successfully listed on the Tokyo Stock Exchange at the end of 2024, with its initial market capitalization hovering around only 800 billion yen (approximately $50 billion). However, with the comprehensive explosion of AI storage demand, KIOXIA performed an epic reversal in the 18 months following its listing: its stock price skyrocketed over 50 times within 18 months, rising 8-fold in 2026 alone.

Currently, KIOXIA's market capitalization has exceeded 51 trillion yen (approximately 481 trillion Korean won), repeatedly surpassing Toyota Motor, the symbol of Japanese manufacturing, to become the highest-valued company on the Japanese stock market.

According to KIOXIA's Q1 FY2026 (April–June) earnings forecast, its quarterly operating profit is expected to reach as high as 1.3 trillion yen (approximately $81 billion), a staggering increase of nearly 30 times year-over-year; the quarterly net profit guidance is 869 billion yen, a 48-fold increase year-over-year. The performance of a single quarter surpassed the full-year net profit forecast for FY2025.

As major customers scrambled to sign long-term supply contracts, KIOXIA's 2026 NAND capacity has been completely sold out, and the supply-demand imbalance is expected to persist until 2027. The market anticipates KIOXIA's operating profit margin this year to exceed 60%, setting a record for the highest profitability level in the global memory industry. Furthermore, with market expectations for shareholders to receive returns such as stock splits and dividends, its target stock price is hoped to rise to 200,000 yen.

This wave of soaring value has delivered investment returns beyond imagination to parent company Bain Capital, which held on during the downturn, and indirect major shareholder SK Hynix.

According to the Financial Times, the AI boom has made Bain's 2018 acquisition of Toshiba Memory (now KIOXIA) one of the most profitable private equity deals in history. Bain Capital has realized profits by selling most of its shares, with returns exceeding $150 billion, a near 20x return on investment. Its flagship private equity fund is estimated to have gained over $8 billion in profit.

SK Hynix invested a total of 395 billion yen (approximately 3.9 trillion Korean won at the time) in Toshiba Memory in 2018 through a consortium involving Korea, the US, and Japan, among other forms. Currently, this consortium still holds an 18% stake in KIOXIA. With the surge in KIOXIA's stock price, SK Hynix has seen enormous paper gains, and the market expects the consortium's eventual total profit to far exceed $70 billion.

The former 'hot potato' instantly transformed into a 'super ATM'.

In the past, the benefits of artificial intelligence were mainly concentrated in GPU and HBM companies like NVIDIA and SK Hynix. HBM was the star on the AI training side, while NAND became a scarce resource in AI inference, model storage, data lakes, enterprise SSDs, and nearline storage. The market expects KIOXIA's net profit for FY2027 to reach 2.8389 trillion yen, a 5.1-fold increase compared to the previous year.

3D NAND, The Foundation of KIOXIA's Existence

KIOXIA invented NAND flash memory over 35 years ago. In 2007, KIOXIA introduced BiCS FLASH 3D flash memory, a 3D flash memory technology system centered around vertical stacking, lateral scaling, wafer bonding, select gate optimization, and advanced packaging.

The basic idea of 3D NAND is: unlike 2D NAND, which only shrinks cells on a plane, it stacks memory cells vertically like building a skyscraper. KIOXIA's explanation is vivid: originally it was one floor with limited land area; 3D NAND is equivalent to turning a one-story building into a multi-story apartment, accommodating more 'residents' on the same area.

The core of BiCS FLASH is its batch processing technology. Its general process logic is: first, alternately stack plate-like electrodes and insulating layers; then drill a large number of holes along the vertical direction in one go; next, fill the holes with charge storage films and pillar-like electrodes; the intersection of the plate-like electrode and pillar-like electrode forms a memory cell. This shows that KIOXIA's BiCS FLASH is not the traditional 'create memory cells separately for each added layer,' but rather stacks the structure first, then forms memory cells by 'punching and plugging' through multiple layers at once. Therefore, when the number of layers increases, the manufacturing cost does not rise completely linearly, improving the economic viability of continued stacking for 3D NAND.

KIOXIA's officially disclosed commercialization timeline for BiCS FLASH is roughly as follows: BiCS FLASH products achieved commercialization with 48 layers in 2015, then progressed to 96 layers, 112 layers, 162 layers; as of March 2023, stacking of over 200 layers has been achieved.

Among these, the 8th-generation BiCS FLASH is a key milestone. KIOXIA states that the 8th-generation product uses 218 word-line stacks, achieves a storage density of 18.3Gb/mm² for the 1Tb TLC product, and supports a 3.2Gbps external data transfer speed, 40μs read time, and 205MB/s programming throughput.

KIOXIA's 8th-generation BiCS FLASH not only jumped from 162 layers to 218 layers but also introduced two key technologies:

CBA (CMOS directly Bonded to Array): CBA can be understood as manufacturing the peripheral CMOS control circuit and the memory array separately, followed by wafer bonding. In the past, CMOS circuits and the memory array were manufactured on the same wafer. However, the optimal process conditions for both are not identical: the memory array may require processes better suited for charge storage and stacked structures, while CMOS circuits focus more on logic control, electrical performance, and speed. Manufacturing them on the same wafer forces compromises.

CBA's approach is: manufacture the CMOS wafer separately, manufacture the memory array wafer separately, optimize the processes for each independently, and finally bond them together with high precision. The benefits are: improved bit density, increased NAND I/O speed, allowing the memory array to use high-temperature processes previously limited by CMOS constraints, and reduced electrical interference between adjacent memory cells.

OPS (On Pitch Select Gate): OPS solves the problem of wasted space within the memory array. In traditional structures, there exist 'dummy' areas between memory cells that are not used for data storage. These areas do not directly contribute to capacity but occupy area. KIOXIA's OPS technology, by rearranging select gates and insulating isolation structures, reduces or eliminates these ineffective areas, allowing more effective memory cells to be placed in the same area. KIOXIA's official explanation states that OPS removes unnecessary dummy regions, enabling more actual memory cells to be placed in the same space, significantly improving storage density.

The 9th-generation BiCS FLASH primarily targets 512Gb and 1Tb TLC products, positioned to support applications in the mid-to-low capacity range that require high performance and low power consumption. It continues to use CBA and OPS technologies to improve production efficiency and provide more advanced flash memory solutions. The 9th generation does not follow the route of increasing layer count but emphasizes the balance between performance, power consumption, cost, and production efficiency.

The 10th-generation BiCS FLASH clearly leans more towards future high-capacity, high-performance demands. KIOXIA states that the 10th-generation product uses the same CMOS technology as the 9th generation while increasing the number of memory layers to 332, approximately 1.5 times that of the 8th generation, to enhance bit density and power efficiency.

Beyond front-end manufacturing processes, KIOXIA is also advancing back-end packaging capabilities. Official materials mention that KIOXIA developed a single-package 8TB flash memory, achieved by stacking 32 flash memory dies, each 2Tb, within one package. This relies on advanced back-end processes like wafer thinning, material design, and wire bonding. This 32-die stacking can assemble 32 pieces of 2Tb dies into a package with a height under 2mm, forming an 8TB flash memory solution.

From 3D NAND to 3D DRAM, KIOXIA's New Gambit

KIOXIA is also deploying a secret weapon to break through the single-product-line barrier of being a 'pure NAND vendor.' Why is KIOXIA venturing into 3D DRAM? This is because DRAM has also reached a planar scaling bottleneck similar to what NAND faced. As an established player in 3D NAND, KIOXIA also possesses process-validated advantages.

Continued scaling of traditional DRAM encounters several challenges: storage capacitors become increasingly difficult to shrink, access transistor leakage increases, data retention time shortens, refresh frequency rises, and higher capacity leads to higher refresh power consumption. Imec also mentioned in a technology review that the traditional DRAM 1T1C structure faces scaling, cost, and power efficiency challenges, especially as large capacitors limit the 3D integration path, and smaller transistors lead to more pronounced leakage paths, causing increased refresh power consumption.

In December 2024, KIOXIA announced the development of OCTRAM (Oxide-Semiconductor Channel Transistor DRAM) technology, a new 4F² DRAM composed of oxide semiconductor transistors, offering both high on-current and ultra-low off-current. This achievement was jointly developed by KIOXIA and Nanya Technology and presented at the 2024 IEEE IEDM.

Panoramic view of OCTRAM (Source: KIOXIA, same below)

Traditional DRAM cells are generally 1T1C, meaning one access transistor plus one capacitor. Its problem is: as the cell continues to shrink, the capacitor becomes harder to make, and transistor leakage also increases refresh power consumption. KIOXIA's OCTRAM attempts to reduce leakage through InGaZnO transistors and push the cell structure towards higher density.

Cross-sectional TEM image of the InGaZnO vertical transistor

Due to its large bandgap and high electron mobility, InGaZnO transistors can theoretically achieve both ultra-low leakage and high on-current. KIOXIA, by optimizing contact electrode materials and spacer thickness, experimentally achieved over 15μA on-current while also realizing ultra-low leakage current below 10⁻¹⁸ A (as shown in the figure below). A significant portion of DRAM power consumption comes from refresh. Lower leakage leads to longer data retention time, reducing refresh pressure. Therefore, the core value of OCTRAM is using low-leakage oxide semiconductor transistors to reduce DRAM refresh power consumption.

(a) On-current characteristics and (b) Off-current characteristics of the developed InGaZnO transistor

In September 2025, KIOXIA disclosed further reliability research on OCTRAM, focusing on TDDB lifetime issues of sub-25nm Gate-All-Around vertical InGaZnO transistors. TDDB stands for Time-Dependent Dielectric Breakdown. Simply put, it's whether the transistor's insulating layer gradually degrades and eventually fails under long-term electric field stress. KIOXIA stated they found lifetime degradation stems from two factors: intrinsic factors from scaling and extrinsic factors from the manufacturing process. By optimizing the process and reducing extrinsic degradation, KIOXIA achieved a projected TDDB lifetime exceeding 10 years.

In December 2025, KIOXIA announced progress closer to the core of 3D DRAM: developing oxide-semiconductor channel transistors capable of high stacking, having fabricated 8-layer horizontal transistor stacks with on-current exceeding 30μA and off-current below 1 aA, i.e., 10⁻¹⁸ A.

As of now, KIOXIA's 3D DRAM remains in the forefront R&D stage, not yet a commercial product.

KIOXIA is not a traditional DRAM giant, but its accumulated expertise in stacking processes, material integration, and array manufacturing from 3D NAND may give it an entry point in exploring next-generation 3D DRAM. Semiconductor Engineering also analyzed that KIOXIA's 3D DRAM path leverages mature oxide/nitride stacking capabilities from NAND to achieve lower-cost bit scaling, then uses IGZO to replace the channel to reduce thermal degradation issues.

However, one crucial point to emphasize is: KIOXIA's 3D DRAM is not HBM. HBM is packaging-level 3D; it stacks already manufactured DRAM dies to address high-bandwidth needs next to GPUs. KIOXIA's 3D DRAM is device/cell-level 3D; it aims to solve the problem of scaling the DRAM cell itself. Therefore, KIOXIA is not directly chasing HBM but is exploring a more fundamental 3D DRAM device path. If this path matures in the future, it may open a new technology branch for high-capacity, low-power working memory in the AI era.

Although 3D DRAM is still far from true commercialization. It currently resembles more of a future-facing technology ticket than an immediate revenue-contributing product line. But for KIOXIA, the significance of this ticket is not small. In the short term, KIOXIA can capitalize on the NAND recovery driven by AI; in the medium term, it advances high-layer BiCS FLASH; and in the long term, it bets on 3D DRAM, extending its 3D stacking capabilities from NAND to DRAM.

Conclusion

From massive losses and merger deadlock to the super myth of surpassing Toyota to become Japan's top-valued company in 2026, KIOXIA's rollercoaster trajectory is almost filled with the brutality and allure of the semiconductor memory industry. It was once cold-shouldered by capital markets for its single product line and missing the HBM wave, yet amid the tsunami of 'massive data flow' triggered by AI large models, it ushered in its own golden era by steadfastly adhering to NAND flash memory.

KIOXIA's comeback may not yet prove that Japanese semiconductors have truly revived. But at least it demonstrates one thing: in the semiconductor industry, a low point does not necessarily lead to exit. As long as technological assets remain, the realignment of cycles, capital, and demand can at any time bring a forgotten company back to the center of the table.

For KIOXIA, finding a long-term balance between fervent capital追捧 (pursuit) and the冷酷 (harsh) industry cycles moving forward will determine whether this lone sprout carrying the hopes of Japanese semiconductor revival is merely a fleeting flower in the AI supercycle or truly opens a new storage empire of its own.

*Disclaimer: This article was originally written by the author. The content represents the author's personal views. Semiconductor Industry Insights republishes it to convey a different perspective. This does not imply Semiconductor Industry Insights' agreement with or support for this view. If you have any objections, please contact Semiconductor Industry Insights.

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相關問答

QWhat triggered Kioxia's dramatic turnaround from a loss-making 'hot potato' to a stock market sensation in Japan?

AKioxia's dramatic turnaround was primarily triggered by the explosive demand for AI storage. The advent of large-scale AI models fundamentally shifted the market logic for memory. NAND flash, Kioxia's core product, became a scarce resource for AI inference, model storage, data lakes, enterprise SSDs, and nearline storage, leading to a supply shortage and surging profitability.

QWhat are the two key technologies (acronyms) introduced in Kioxia's 8th generation BiCS FLASH that significantly improved performance?

AThe two key technologies introduced in Kioxia's 8th generation BiCS FLASH are CBA (CMOS directly Bonded to Array) and OPS (On Pitch Select Gate). CBA improves density and speed by bonding separately optimized CMOS and array wafers, while OPS increases storage density by eliminating dummy areas within the memory array.

QWhat is the main technical advantage of Kioxia's OCTRAM (3D DRAM) technology over traditional DRAM?

AThe main technical advantage of Kioxia's OCTRAM technology is its use of InGaZnO (Oxide-Semiconductor) transistors, which offer extremely low leakage current (off-state current). This dramatically reduces refresh power consumption, a major challenge for traditional DRAM as it scales down, thereby enabling higher density and lower power 3D DRAM architectures.

QHow does Kioxia's approach to 3D DRAM (OCTRAM) fundamentally differ from High Bandwidth Memory (HBM)?

AKioxia's 3D DRAM (OCTRAM) is a device/cell-level 3D technology that aims to solve the fundamental scaling problems of the DRAM memory cell itself by stacking transistors vertically. In contrast, HBM is a package-level 3D technology that stacks pre-manufactured DRAM dies to achieve high bandwidth, primarily for GPU-adjacent memory. They address different layers of the memory hierarchy and scaling challenges.

QWhich major investors reaped enormous returns from Kioxia's stock surge, and what was the scale of one of their profits?

AThe major investors were Bain Capital (the parent company) and SK Hynix (an indirect major shareholder). Bain Capital's investment from the 2018 Toshiba Memory buyout became one of the most profitable private equity deals ever, with profits exceeding $15 billion and a return of nearly 20 times. The SK Hynix-led consortium is also expected to realize total profits far exceeding $70 billion.

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什麼是 $S$

什麼是 AGENT S

Agent S:Web3中自主互動的未來 介紹 在不斷演變的Web3和加密貨幣領域,創新不斷重新定義個人如何與數字平台互動。Agent S是一個開創性的項目,承諾通過其開放的代理框架徹底改變人機互動。Agent S旨在簡化複雜任務,為人工智能(AI)提供變革性的應用,鋪平自主互動的道路。本詳細探索將深入研究該項目的複雜性、其獨特特徵以及對加密貨幣領域的影響。 什麼是Agent S? Agent S是一個突破性的開放代理框架,專門設計用來解決計算機任務自動化中的三個基本挑戰: 獲取特定領域知識:該框架智能地從各種外部知識來源和內部經驗中學習。這種雙重方法使其能夠建立豐富的特定領域知識庫,提升其在任務執行中的表現。 長期任務規劃:Agent S採用經驗增強的分層規劃,這是一種戰略方法,可以有效地分解和執行複雜任務。此特徵顯著提升了其高效和有效地管理多個子任務的能力。 處理動態、不均勻的界面:該項目引入了代理-計算機界面(ACI),這是一種創新的解決方案,增強了代理和用戶之間的互動。利用多模態大型語言模型(MLLMs),Agent S能夠無縫導航和操作各種圖形用戶界面。 通過這些開創性特徵,Agent S提供了一個強大的框架,解決了自動化人機互動中涉及的複雜性,為AI及其他領域的無數應用奠定了基礎。 誰是Agent S的創建者? 儘管Agent S的概念根本上是創新的,但有關其創建者的具體信息仍然難以捉摸。創建者目前尚不清楚,這突顯了該項目的初期階段或戰略選擇將創始成員保密。無論是否匿名,重點仍然在於框架的能力和潛力。 誰是Agent S的投資者? 由於Agent S在加密生態系統中相對較新,關於其投資者和財務支持者的詳細信息並未明確記錄。缺乏對支持該項目的投資基礎或組織的公開見解,引發了對其資金結構和發展路線圖的質疑。了解其支持背景對於評估該項目的可持續性和潛在市場影響至關重要。 Agent S如何運作? Agent S的核心是尖端技術,使其能夠在多種環境中有效運作。其運營模型圍繞幾個關鍵特徵構建: 類人計算機互動:該框架提供先進的AI規劃,力求使與計算機的互動更加直觀。通過模仿人類在任務執行中的行為,承諾提升用戶體驗。 敘事記憶:用於利用高級經驗,Agent S利用敘事記憶來跟蹤任務歷史,從而增強其決策過程。 情節記憶:此特徵為用戶提供逐步指導,使框架能夠在任務展開時提供上下文支持。 支持OpenACI:Agent S能夠在本地運行,使用戶能夠控制其互動和工作流程,與Web3的去中心化理念相一致。 與外部API的輕鬆集成:其多功能性和與各種AI平台的兼容性確保了Agent S能夠無縫融入現有技術生態系統,成為開發者和組織的理想選擇。 這些功能共同促成了Agent S在加密領域的獨特地位,因為它以最小的人類干預自動化複雜的多步任務。隨著項目的發展,其在Web3中的潛在應用可能重新定義數字互動的展開方式。 Agent S的時間線 Agent S的發展和里程碑可以用一個時間線來概括,突顯其重要事件: 2024年9月27日:Agent S的概念在一篇名為《一個像人類一樣使用計算機的開放代理框架》的綜合研究論文中推出,展示了該項目的基礎工作。 2024年10月10日:該研究論文在arXiv上公開,提供了對框架及其基於OSWorld基準的性能評估的深入探索。 2024年10月12日:發布了一個視頻演示,提供了對Agent S能力和特徵的視覺洞察,進一步吸引潛在用戶和投資者。 這些時間線上的標記不僅展示了Agent S的進展,還表明了其對透明度和社區參與的承諾。 有關Agent S的要點 隨著Agent S框架的持續演變,幾個關鍵特徵脫穎而出,強調其創新性和潛力: 創新框架:旨在提供類似人類互動的直觀計算機使用,Agent S為任務自動化帶來了新穎的方法。 自主互動:通過GUI自主與計算機互動的能力標誌著向更智能和高效的計算解決方案邁進了一步。 複雜任務自動化:憑藉其強大的方法論,能夠自動化複雜的多步任務,使過程更快且更少出錯。 持續改進:學習機制使Agent S能夠從過去的經驗中改進,不斷提升其性能和效率。 多功能性:其在OSWorld和WindowsAgentArena等不同操作環境中的適應性確保了它能夠服務於廣泛的應用。 隨著Agent S在Web3和加密領域中的定位,其增強互動能力和自動化過程的潛力標誌著AI技術的一次重大進步。通過其創新框架,Agent S展現了數字互動的未來,為各行各業的用戶承諾提供更無縫和高效的體驗。 結論 Agent S代表了AI與Web3結合的一次大膽飛躍,具有重新定義我們與技術互動方式的能力。儘管仍處於早期階段,但其應用的可能性廣泛且引人入勝。通過其全面的框架解決關鍵挑戰,Agent S旨在將自主互動帶到數字體驗的最前沿。隨著我們深入加密貨幣和去中心化的領域,像Agent S這樣的項目無疑將在塑造技術和人機協作的未來中發揮關鍵作用。

934 人學過發佈於 2025.01.14更新於 2025.01.14

什麼是 AGENT S

如何購買S

歡迎來到HTX.com!在這裡,購買Sonic (S)變得簡單而便捷。跟隨我們的逐步指南,放心開始您的加密貨幣之旅。第一步:創建您的HTX帳戶使用您的 Email、手機號碼在HTX註冊一個免費帳戶。體驗無憂的註冊過程並解鎖所有平台功能。立即註冊第二步:前往買幣頁面,選擇您的支付方式信用卡/金融卡購買:使用您的Visa或Mastercard即時購買Sonic (S)。餘額購買:使用您HTX帳戶餘額中的資金進行無縫交易。第三方購買:探索諸如Google Pay或Apple Pay等流行支付方式以增加便利性。C2C購買:在HTX平台上直接與其他用戶交易。HTX 場外交易 (OTC) 購買:為大量交易者提供個性化服務和競爭性匯率。第三步:存儲您的Sonic (S)購買Sonic (S)後,將其存儲在您的HTX帳戶中。您也可以透過區塊鏈轉帳將其發送到其他地址或者用於交易其他加密貨幣。第四步:交易Sonic (S)在HTX的現貨市場輕鬆交易Sonic (S)。前往您的帳戶,選擇交易對,執行交易,並即時監控。HTX為初學者和經驗豐富的交易者提供了友好的用戶體驗。

2.0k 人學過發佈於 2025.01.15更新於 2026.06.02

如何購買S

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歡迎來到 HTX 社群。在這裡,您可以了解最新的平台發展動態並獲得專業的市場意見。 以下是用戶對 S (S)幣價的意見。

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