Why Asia may be the biggest winner of the global AI boom
Asia is central to the global AI boom—driving semiconductor supply, productivity gains, and investment opportunities amid shifting policy and labor dynamics.
Asian semiconductor value chains are now clearly recognized as critical enablers of the rapidly evolving global AI story.1 This dynamic positions Asia to reap cost-effective productivity gains, potentially making the region a net beneficiary of AI advances.
But the impact will vary widely across Asia economies.
Economies like Japan and South Korea may benefit from AI alleviating labor shortages, but labor-abundant countries like China and India are facing challenges like youth unemployment. Tax policies are emerging as a pivotal factor in shaping these outcomes: many Asia governments are deploying aggressive tax incentives to support AI and related infrastructure, diverging from a US landscape that, so far, lacks AI-specific tax measures.
Asia anchors AI through hardware; the West scales through capital
The Asia-Pacific region—led by Taiwan, South Korea, Japan, and China—has become the epicenter of global semiconductor manufacturing, which is the foundation of modern AI technologies. Including Japan, Asia now produces around 72% of the world’s semiconductors and 95% of the most advanced chips needed for AI accelerators like GPUs.2 This dominance is critical. Asian hardware is foundational to generative AI development.3 Asian firms enjoy near-monopoly positions in key AI supply-chain niches—from high-bandwidth memory chips in South Korea to advanced semiconductor chemicals and manufacturing equipment in Japan.
By contrast, recent headlines in the West have been dominated by massive capital expenditure (CapEx) announcements. US hyperscalers including Microsoft, Google (Alphabet), Amazon, Meta, and Oracle are projected to spend $697 billion in 2026 and $873 billion in 2027. But the “hidden reality” is Western AI ambitions critically depend on Asian hardware. Every advanced server, GPU cluster, and cloud data center US tech firms build is fundamentally underpinned by chips and electronics from Asia.4 In effect, Western investments in AI funnel into demand for Asia’s semiconductors and electronics on the back end.
Meanwhile, the economics of deploying advanced AI has shifted dramatically due to a wave of cheaper, “good enough” models—many open source or from Chinese challengers—that offer strong performance at a fraction of costs.5 For example, cost-efficient Chinese model DeepSeek cut the price of their premium V4-Pro offering by nearly 75% recently.6
Chinese startup DeepSeek’s innovative low-cost model in 2025 triggered a surge in domestic AI adoption and a wave of new AI CapEx beneficiaries. DeepSeek’s recent price cut to its flagship V4-Pro model, which set model output costs at one-seventh of Anthropic’s and one-ninth of OpenAI’s models, is likely to further accelerate AI adoption and deployment in Asia.
While China’s leading tech firms still invest far less in AI infrastructure than US giants (roughly $50 billion projected for China’s top four in 2025 vs. $300 billion for the US Big Four), differences in purchasing power and an open-source ecosystem allow them to do more with less.
Some mid-size Chinese internet companies are achieving real productivity gains (higher revenue and margins in areas like e-commerce and fintech) by embracing these cost-effective AI solutions. Crucially, these trends do not diminish the strategic importance of US hyperscalers’ heavy CapEx frontier push—rather, they highlight a complementary dynamic. US leaders continue to push the boundaries and set new performance benchmarks.
Key takeaways
The structural differences in approach mean that investors eyeing the AI boom must look beyond Silicon Valley and consider Asia. The region’s strength in core hardware and manufacturing—high-tech semiconductors, electronics, batteries, and 5G infrastructure—makes it a critical anchor of the AI value chain. Through the lens of the Jevons paradox, declining AI costs could drive greater adoption and usage, reinforcing demand for AI hardware. The commoditization of advanced AI via cheaper models is also narrowing the pricing power of frontier providers, potentially shifting more value capture to the underlying infrastructure, platform, and application layers where Asia excels.
Notably, market valuations for Asian tech remain lower. Top Asian tech firms trade at discounts in price-to-earnings compared to their US peers, which many see as an undervalued opportunity given Asia’s secular growth potential in the AI age.
In short, Asia’s hardware-centric, application-focused AI development not only differentiates it from the West’s software-centric, frontier-model-focused, capital-intensive path, but may also offer attractive investment value and resilience—with Asia effectively selling the “picks and shovels” of the AI gold rush.
Productivity boosts: Why Asia is a net AI beneficiary
“Greater bang for the buck” captures why Asia’s AI adoption is already translating into measurable productivity gains without proportionate cost escalation. The key distinction is that Asia’s AI deployment is hardware-anchored and operational, not infrastructure heavy.
First, AI is raising output and throughput within existing industrial capacity. In Taiwan, AI-server and semiconductor manufacturing has scaled through higher fab utilization, yield optimization, and automation, delivering record industrial output growth without a commensurate rise in labor input.7 Advanced fabs increasingly use machine-learning models for process control and defect detection, lifting chips per tool hour rather than requiring large new CapEx.8
In South Korea, AI-enabled robotics and inspection systems are offsetting labor scarcity, with automated welding, vision-based quality control, and AI-guided scheduling improving throughput and uptime across electronics, shipbuilding, and memory fabs.9 As such, South Korea leads the world in robot density, with nearly five times the global average at 1000+ robots per 10,000 employees.
Second, applied AI is compressing cycle times and easing skilled-labor bottlenecks. In Japan, AI is deployed as a substitute for scarce expertise in precision manufacturing, automating highly skilled manufacturing tasks, thereby dramatically shrinking labor time. For instance, an AI-based software ARUMCODE can write complex machining programs for precision parts in 15 minutes vs. the 16 hours previously required by an expert human—an effective doubling of output per engineer. Japanese manufacturers also use AI for predictive maintenance and production optimization, boosting output and uptime without needing equivalent increases in headcount.10
Singapore is a highly automated economy with the second highest robot density in the world. Some of its Lighthouse 4.0 plants reported 40-70% productivity gains using AI-driven scheduling and predictive quality control.11 One semiconductor fab achieved similar jump in productivity with sharply shorter cycles that dramatically reduced resource usage. Furthermore, scalable productivity and efficiency gains are beginning to resonate with its high innovation economy. Winners include Rolls Royce, Coco Cola, Airbus, and Edward Lifesciences.12
At scale, AI and digital twin deployments are revolutionizing manufacturing efficiency. Foxconn’s Zhengzhou campus—China’s largest electronics factory—is a WEF-designated “Lighthouse Factory” where the introduction of an AI assistant (“Xiaoqing”) and digital twin control systems has more than doubled production efficiency (+102%) and raised equipment utilization by 27%, enabling far greater output without additional labor.13
Taken together, these examples point to a common mechanism across Asia: AI is extracting more output from existing capital stock—via yield improvement, downtime reduction, faster cycle times, and labor substitution—rather than justifying massive new infrastructure builds. This contrasts with the more capital-intensive Western model centered on hyperscale computing and proprietary platforms.
Key takeaways
Asia can capture a meaningful AI productivity dividend at lower relative cost. This is clearly visible in high exports and strong GDP growth prints in Q1 2026. As a net supplier of semiconductors and electronics, the region also benefits from global AI CapEx cycles, earning export revenues from others’ infrastructure build-outs while simultaneously improving domestic productivity. The binding constraint is diffusion—how effectively these factory-level gains spread across firms, sectors, and labor markets—which varies widely across the region and will shape the next phase of AI-led growth.
Divergent labor market impacts: From Japan’s aging to India’s youth bulge
A striking aspect of AI’s advance in Asia is how unevenly its impacts will be felt across different economies, largely due to demographic and labor market differences. Some countries may see AI as a salvation for labor shortages, while others worry about job displacement in already crowded labor markets:
- Aging, labor-scarce economies—AI as a solution: In Japan and South Korea, record-low birth rates and greying populations have led to chronic labor shortages and “tight” labor markets. Japan’s overall unemployment rate is about 2.5% (with youth joblessness at an astounding low of 2.1% as of Dec 2025). With nearly 30% of Japanese citizens projected to be over 65 by 2040, the country faces an urgent need to fill a shortfall of millions of workers in coming decades.14 These nations are turning to AI, robotics, and automation to keep their economies running amid workforce declines.
Japan is rapidly integrating robots in sectors from construction and trucking to agriculture—achieving dramatic labor savings (for example, a farming pilot cut human hours by 95% using AI-driven robots).15 Japan’s Prime Minister Takaichi has explicitly called to “go all in on AI” to address the demographic crisis, viewing automation as critical to maintaining productivity as workers age and retire (Figure 1).16
South Korea, with the world’s lowest fertility rate and similarly low unemployment (2.8% average in 2025), likewise sees AI as part of the solution to its labor shortfall. High AI adoption in Korea’s large firms is already boosting output and productivity, and government policy emphasizing retraining and “labor market flexibility” is helping workers transition into new roles created by AI.17
- Labor-abundant economies—AI as a challenge: In contrast, China and India—the world’s two most populous countries—face the opposite problem: large young workforces and not enough jobs, raising concerns that unbridled AI adoption could aggravate unemployment.
China’s urban youth unemployment hit a record 21.3% in June 202318 and remained so troubling that Beijing stopped publishing the statistic thereafter. India’s official overall unemployment appears lower, but surveys indicate very high joblessness among educated youth—for instance, in 2022, roughly 20% of young Indian men (20–24) and over 30% of young women with degrees were unemployed.19 In such contexts, rapid automation of business processes through AI and robotics could displace workers or dampen job creation for the millions of new entrants seeking work each year. This risk is especially salient in industries like manufacturing and services, where AI might substitute routine tasks.
It’s not all doom and gloom for labor-rich countries. AI can also create new opportunities and improve job quality if managed well. For example, efficient AI adoption could boost economic growth (indirectly creating new jobs) and augment human workers’ productivity rather than simply replacing them. To date, however, AI has not generated sizable net new employment in these labor-rich economies. Job displacement risks and unrealized hiring clearly outweigh any emergent “AI jobs” creation. Indeed, global data already show more roles eliminated by AI and automation (over 425,000 jobs displaced since 2023 worldwide) than new AI-related roles created (about 285,000 since 2024).20
Policy responses will play a key role in managing the transition. Both China and India are investing in AI education and digital skills programs to make their youthful workforces more complementary to AI, not simply in competition with it. India’s Economic Survey 2024-25 emphasizes leveraging its “young, tech-savvy population” to use AI for productivity while ramping up skilling initiatives. Similarly, China’s government has highlighted AI as a national priority for economic growth, coupled with efforts to move up the value chain and create high-tech jobs. This has attracted investment to AI research hubs and chip design that are spurring domestic innovation.21
Key takeaways
The structural diversity of Asian labor markets means AI’s impact will not be homogeneous. In aging societies AI may be a boon, offering a timely productivity injection and labor substitute. In youthful, developing economies, the immediate benefits of AI may be less automatic, especially if its gains are concentrated in capital or skill-intensive parts of the economy.
This makes supportive policies—such as education, reskilling, and inclusive technology deployment—crucial to ensuring AI’s productivity gains are broadly shared. It also underscores why Asia’s AI surge must be analyzed in a country-specific context.
The critical role of tax policy: East’s incentives vs. West’s caution
As governments grapple with AI’s far-reaching economic implications, taxation and fiscal policy have become a key lever to encourage innovation—or to cushion its side effects. Here, too, Asia’s approach is diverging from the US in notable ways:
Asia: Using tax incentives to turbocharge AI and tech investment
Across Asia-Pacific, many policymakers are proactively revising tax codes to stimulate AI development, encourage the build-out of tech infrastructure, and attract high-tech investments:
- Massive tax breaks for AI infrastructure: In India, the latest Union Budget (FY2026) took the remarkable step of offering a 21-year tax holiday (zero corporate tax) for any foreign company that sets up large-scale data centers in India to provide cloud and AI services globally.22 This unprecedented tax holiday until 2047 is aimed at making India a competitive hub for AI computation and cloud infrastructure, leveraging its large market and talent base. The same budget also earmarked a ₹40,000 crore (approx. $4.8 billion) public investment in a new Semiconductor Mission 2.0 to boost domestic chip manufacturing—another move to bolster the hardware backbone of AI.23
- Enhanced R&D tax credits: Japan and South Korea—both technological powerhouses—are expanding R&D tax incentives targeting AI and related strategic sectors. Japan’s ruling coalition in late 2025 approved a tax reform that raises the R&D tax credit to as high as 40–50% of investment for companies pursuing projects in “national strategic technologies” like AI, advanced robotics, and semiconductors.24 This is a dramatic increase designed to spur domestic innovation and keep R&D activity onshore. The reform also introduces a new 7% tax credit (or immediate full expensing option) for large capital investments across industries to encourage modernization and technology deployment at scale.25
- Strategic tech as national priority: South Korea has likewise designated AI and chip technologies as national strategic industries eligible for generous tax benefits. A 2025 tax reform plan in South Korea officially added AI data centers and related technologies to its national strategic technology list, boosting tax deductions for these investments to 15–25% (up from just 1%–10% previously).26 This means, for example, that a 7 trillion won ($4.6 billion) AI data center project in Korea could now receive over 1 trillion won in tax credits—a massive reduction in effective cost.27 These moves build on Seoul’s broader strategy of supporting high-tech sectors. Notably, back in 2017, South Korea had curtailed certain automation-related tax allowances (an early “robot tax” in effect) to slow possible job losses, but the current trend is to incentivize AI investment alongside policies for workforce “coexistence” (for example, support for retraining).
- China’s tax and fiscal support: While more often relying on direct state investment and industrial policy to drive AI leadership, China also uses its tax system to encourage innovation. The government offers super-sized R&D tax deductions (up to 200% of R&D expenses in some cases), far outpacing the support provided by most Western countries.28 These super-deductions—alongside substantial government research grants and procurement—lower the cost of AI research for Chinese firms. Moreover, Chinese tech companies benefit from preferential tax rates when they achieve “high-tech enterprise” status, and certain local governments provide tax rebates for AI enterprises. The aggressive use of tax tools is one reason the OECD estimates that China’s R&D tax incentive support is more than 10 times what US firms effectively receive today.29
The US: Caution and debate
By comparison, the United States has not introduced AI-specific tax incentives or targeted taxes, instead taking a more cautious approach:
- Lack of direct AI tax incentives: The US relies on broad-based measures like the R&D tax credit and investment in fundamental science. In fact, some aspects of US tax policy for innovation have become less generous recently. A 2022 law change began requiring companies to spread R&D expenditures over 5 years instead of immediate deduction, effectively halving the value of the R&D tax deduction and leading firms to cut R&D spending and hiring for innovation.30 Overall, US tax support for R&D is now modest by international standards—roughly one-fifth the OECD average, and under one-tenth of China’s level.31 While the 2022 CHIPS Act introduced a 25% investment tax credit for domestic semiconductor manufacturing facilities32 (to bolster the chip supply chain critical to AI), there are no specific tax breaks targeting AI development or adoption at the federal level. Overall, the US is still competitive on tax incentives, but Asia’s clear lead coupled with a supportive ecosystem and cost competitiveness could make those incentives more effective in practice.
- Debating a “robot tax”: In Washington, the more pressing discussion has been about potentially taxing AI and automation, largely out of concern for future job losses. Several public figures and lawmakers have floated the idea of a “robot tax” that reduces tax incentives on AI systems and robots that displace human labor.33 For example, US Senators Bernie Sanders and Mark Kelly recently have suggested taxes on AI-driven automation or on the profits of AI companies to fund worker retraining and disincentivize replacing employees.34 So far, these proposals remain speculative. Leading economists also have cautioned that taxing AI investments could hinder innovation and productivity—drawing parallels to past missteps of over-taxing capital goods, which has historically slowed growth.35 The prevailing view from many experts is that it’s better to encourage adaptation (through, say, training tax credits or strengthened social safety nets) than to try to slow AI adoption via new taxes.36
Key takeaways
The fiscal policy stance on AI differs markedly between Asia and the US. Most Asian governments are treating AI as an opportunity—competing to lure AI talent and investment with tax breaks, funding, and infrastructure support. The US policy response remains more hands-off (aside from general tech and chip subsidies) and tinged with caution about AI’s disruptive potential (Figure 2).
Figure 2: AI and tech taxation and incentives policy landscape offers varying perspectives
| Country | AI & tech taxation and incentives policy |
|---|---|
| United States | No dedicated AI tax or incentive program to date. Relies on general R&D tax credits (recently weakened by 2022 law) and major subsidies like the CHIPS Act (25% tax credit for US semiconductor fabs). Some policymakers have proposed “robot taxes” on AI/automation to address job losses, but no such measures have been enacted. |
| China | Aggressive pro-AI tax incentives. Offers super-sized R&D tax deductions (up to 200% of expenses), far exceeding Western norms. Significant state investment and subsidies for AI startups and chip makers; reduced corporate tax rates for certified “high-tech” enterprises. No known plans for taxing AI deployment; focus is on subsidizing growth. |
| Japan | Boosting tax breaks for strategic tech. As of FY2026, Japan is expanding R&D tax credits to 40–50% of expenditures in “national strategic” fields like AI, robotics, and semiconductors. Also introducing a new 7% tax credit or immediate full expensing for large capital investments in advanced technologies. Aims to keep R&D and production at home by staying competitive with US/EU incentives. |
| South Korea | Designated AI as national strategic technology for tax credits. In 2023–25 reforms, Korea raised tax deductions for AI data centers and related tech to 15–25% (previously 1–10%). This greatly lowers AI infrastructure costs (for example, a $5 billion AI cloud center can get ~$0.8–1 billion in tax relief). Earlier, Korea scaled back automation equipment tax incentives (informally dubbed a “robot tax”) in 2017 to combat potential job loss, but current policy is geared toward incentivizing and managing AI growth (with support for worker retraining). |
| India | Tax holidays and high-tech investment push. Union Budget 2026–27 offers a “tax holiday” until 2047 for foreign firms building cloud/AI data centers in India. This 21-year zero-tax incentive, alongside a new ₹40,000 crore ($4.8 billion) government outlay for semiconductors, is designed to attract global tech giants and strengthen India’s digital infrastructure. India is also funding AI-skilling programs and innovation hubs, using fiscal tools to ensure the country becomes a key AI innovation and adoption hub. |
Impact of the Iran war: Lower margins may lead to higher prices eventually
Geopolitics is also starting to interact with the AI supply chain. While markets are just beginning to grasp the potential inflationary effects of the Iran conflict,37 two more nuanced dynamics are emerging for Asia’s AI and semiconductor ecosystem.
First, the AI/semiconductor optimism has proven resilient, with activity sharply exceeding expectations. Second, the conflict could exert pressure primarily through margins rather than immediate price pass-through, raising the risk that costs accumulate beneath the surface before selectively feeding through to prices.38
Since the war began, tech-linked macro indicators in Asia have exceeded bullish expectations with a margin. Q1 GDP growth rates for Singapore (6.0% y/y, 6q high), South Korea (3.6%), Taiwan (13.7%) and Japan (2.1% q/q saar) have all surprised to the upside of the consensus and hit muti-year highs. Furthermore, higher frequency data such as monthly exports, industrial production (IP), semiconductor exports are continuing to come in strong in April and May. For example, Singapore’s April IP rose 17.6% y/y with a 44% jump in electronics output. Similarly, South Korea’s May exports rose 53.2% on the back of a 291% rise in computer related exports and finally Taiwan’s manufacturing PMI hit a 5y high in May. Some of this likely reflects front-loaded orders, but it also underscores that AI-related demand remains robust despite geopolitical stress. Crucially, firms have sustained output by absorbing higher input and logistics costs and drawing on inventories, diversified sourcing, and efficiency gains to protect delivery schedules and customer relationships.39
The conflict has nonetheless exposed structural fragilities which are now reflected in falling supplier delivery times as well as in higher price indices in the PMI data. Disruptions around the Strait of Hormuz and damage to Qatar’s Ras Laffan complex highlighted Asia’s dependence on Gulf energy and helium—both critical for chip fabrication and data centers.40 Helium is particularly difficult to substitute. It is a byproduct of natural gas processing, produced in only a handful of locations globally, and uniquely suited for ultra-clean cooling and leak detection in semiconductor fabs. Shortages are especially disruptive41 because there is no scalable synthetic alternative and new supply cannot be ramped up quickly.42 A rising shortage of sulfur (in conjunction with export limitations from China) and bromine (critical for chip chemistry) add to the challenges, apart from LNG.
If shortages persist, margin pressure is more likely to intensify before prices adjust. Energy, freight, and helium costs have risen, but firms have so far cushioned customers from these shocks. However, both input as well as output prices are beginning to rise (Figure 4) among PMI data while upstream producer price indicators for electronic components have begun to firm, a subtle signal that cost pressures are building.43 With strong demand and selective supply tightness, pricing power exists, but it is likely to be exercised gradually and unevenly, only after margin buffers and stopgaps are tested.44
Asia’s position in the AI race: Room to grow
The structural AI story in Asia Pacific remains one of enduring strength, complementing the rapidly evolving, software- and platform-led AI shifts in the West. Asia’s hardware-centric innovation engine has anchored the region at the core of the global AI value chain, supplying critical chips and supporting collaborative development models that have helped scale AI at lower unit costs. This positioning, reinforced by proactive industrial and fiscal policies, suggests the region can still capture meaningful productivity gains from AI, even as firms increasingly absorb higher energy, logistics, and materials costs in the near term.
Over time, this combination of scale, capability, and policy support leaves Asia well placed to emerge as a net economic beneficiary of the AI era, albeit with some pressure on margins before benefits fully materialize.
That said, Asia’s diversity ensures AI’s economic and labor-market impacts will be uneven. Governments across the region are not leaving these outcomes to chance. Taxation and fiscal incentives have become a strategic battleground. In the years ahead, these policy choices—supporting adoption while managing cost pressures—will play a decisive role in determining which regions lead the next phase of the AI-driven productivity cycle, and how broadly those gains are shared across Asia’s diverse economies.