Public money, private innovation: How government funding built – and sustains – America’s technological leadership

The US has long been the world’s innovation powerhouse, based on a system that combines public funding with private initiative. Yet this model is under strain. Using newly digitised US patent data since 1950, this column shows that publicly funded but privately owned patents – just 2% of all US patents – account for around 20% of medium-term fluctuations in productivity and GDP growth. As funding cuts threaten the most productive funders of public R&D, the authors argue that America’s innovation edge rests on the visible hand of public support for basic research.

The US has long been the world’s innovation powerhouse. From semiconductors to the internet, from biotechnology to artificial intelligence, America’s scientific leadership has rested on an ecosystem that combines public funding with private initiative. Yet this model is under strain. Recent debates over proposed budget cuts to the National Institutes of Health (NIH) and the National Science Foundation (NSF) come at a time when other economies — notably China and the EU — are increasing public investment in frontier technologies. These shifts have reignited a central question: how much of America’s innovation edge depends on public money?

In a new paper (Gazzani et al. 2025), we provide fresh empirical evidence on the macroeconomic impact of the post-war American innovation model — the one first envisioned by Vannevar Bush in Science, the Endless Frontier (1945). Using newly digitised US patent data that distinguish funding sources and ownership structures, we show that government-funded but privately owned patents — just 2% of all patents — account for roughly 20% of medium-term fluctuations in US productivity and GDP growth. These public–private innovations also crowd in private R&D and investment, underscoring the outsized returns to government support for basic research.

Our findings suggest that the US owes much of its technological dynamism not to the invisible hand of the market alone, but to what might be called the visible hand of government-enabled innovation.

The global race for innovation leadership

The US government’s role in shaping technological progress is often taken for granted. But in the current policy climate, where deficit concerns dominate, public research funding faces renewed scrutiny. The NIH and NSF — central pillars of American science since the 1950s — are under pressure even as China channels massive state resources into artificial intelligence, quantum computing, and green technologies. The EU, too, has expanded its Horizon Europe programme and national innovation funds to address its lagging productivity growth (see Buti and Papaconstantinou 2025).

This is not the first time such a tension has surfaced. As argued by Mazzucato (2013), government agencies have long been the ‘entrepreneurial state’, de-risking the fundamental research that private firms later commercialise. Recent research has examined this theme from various angles — from the macroeconomic effects of public R&D (Fieldhouse and Mertens 2023) to the connection between fiscal policy in a high-debt environment and productivity growth (Fornaro and Wolf 2025). Our work complements this line of research by tracing, at the aggregate level, how different forms of public and private innovation have shaped US productivity dynamics over the past seven decades.

Mapping America’s innovation architecture

Following Bush’s blueprint, post-war US innovation has been built on three pillars:

1. Government funding for areas of public interest
2. Universities and research institutes to conduct fundamental research
3. Private firms to commercialise the resulting knowledge.

Using the Government Patent Register database (Gross and Sampat 2025), we classify all US patents granted since 1950 into three groups:

• Public–private (funded by government, owned by a private entity)
• Private–private (fully privately funded and owned)
• Public–public (funded and owned by the government)

We then link these time series to macroeconomic indicators such as total factor productivity (TFP), GDP, R&D expenditure, and investment. By controlling for the business cycle and showing that our innovation measures are not predicted by fiscal and monetary shocks, we isolate the medium-term co-movements between innovation activity and aggregate outcomes.

The results are striking. Figure 1 displays the macroeconomic effects of innovation, showing that public-private patents (first column) are characterised by the largest medium-term impact on both output (first row) and productivity (second row), doubling those of private sector innovations over the same horizons (second column). Government-funded but privately owned patents are also associated with sustained increases in private R&D spending, business investment, and real wages. Though public–private patents make up just 2% of the total, they account for about one-fifth of medium-term GDP and TFP fluctuations (Figure 2). Innovation through public–public patents, not shown here, has muted average effects — though it disproportionately features the most disruptive breakthroughs in health and biotechnology. These results hold across ten different econometric approaches, consistently pointing to government-funded research as a key driver of medium-term productivity gains.

Figure 1 Macroeconomic effects of innovation

Notes: The figure displays the dynamic effects of innovation shocks in each category of patents (public-private, private-private, public-public; by column) on (log) real per-capita private GDP and (log) TFP. The estimates are done by means of local projections, where the size of the shock is normalised such as to increase total patents by 1% on impact. Shaded areas report 68% and 90% confidence intervals. Sample: 1950:Q1-2015:Q4.

Figure 2 Contribution of innovation to GDP and TFP

Note: The figure displays the forecast error variance contribution of innovation shocks in two categories of patents (public-private and private-private) on (log) real per-capita GDP expenditure and (log) TFP (by row). Shaded areas report 68% and 90% confidence intervals.

Why are government-funded patents so impactful? Because they tend to be more basic than privately funded ones. Basic research expands the knowledge frontier, generating broadly applicable insights that create powerful spillovers and amplify innovation across the economy. Figure 3 shows that government-funded patents account for a large share of the ‘most basic’ ones, according to measures of basicness based on patents’ similarity to subsequent ones (‘importance’) and on the number of citations to scientific papers (‘reliance on science’). Even though they are far fewer, government-funded patents tend to be much more basic than private ones.

Figure 3 Basicness of publicly funded patents

The multiplier of public–private innovation

The macroeconomic patterns we uncover echo Vannevar Bush’s post-war vision: the government should fund basic research that private investors find too risky or with too large upfront costs, while universities and firms translate discoveries into applications. This collaboration between public funding and private ownership appears to generate powerful spillovers.

A back-of-the-envelope calculation suggests that every dollar of public R&D funding generates between eight and fourteen dollars in cumulative GDP, more than twice the return on privately financed innovation. These multipliers align with recent evidence that public R&D crowds in — rather than crowds out — private innovation (see Bloom et al. 2019, Myers and Lanahan 2022, Bergeaud et al. 2025).

NIH, NSF, and the geography of transformative science

Drilling down by federal agency, the NIH and NSF emerge as the most productive funders of innovation. Patents supported by these two agencies are most strongly linked to medium-term gains in productivity, output, and business-sector R&D. By contrast, patents financed by the Department of Defense or NASA exhibit smaller macroeconomic correlations.

The sectoral composition of innovations sheds further light on why. In health and biotechnology — fields dominated by NIH funding — publicly financed patents outperform private ones by a wide margin. This reflects both the ‘public good’ nature of biomedical research and the long horizon of medical discovery, which private firms may find hard to justify to shareholders. Similar patterns arise in basic energy research, where the Department of Energy’s publicly funded projects have generated significant spillovers into private R&D, consistent with evidence in Myers and Lanahan (2022).

Who delivers the biggest impact?

Beyond federal agencies, the data reveal systematic differences across types of innovators. Research institutes and universities — rather than for-profit companies — produce the most growth-enhancing patents when supported by government funds. When universities rely solely on private funding, however, their macroeconomic impact is roughly half as large.

Among for-profit entities, start-ups and venture-capital-backed firms stand out as more productive engines of innovation than established corporations — but only when they receive public support. Without government funding, their productivity advantage vanishes. These findings suggest that public financing does not displace entrepreneurial activity; it amplifies it.

Such complementarities between public and private sectors echo the arguments made by Aghion (2023) and Mitra et al. (2024) on the design of innovation policy in Europe: when the state takes early-stage risks, the private sector is more likely to scale up transformative technologies. America’s post-war experience offers a textbook example of this dynamic.

The macroeconomics of innovation policy

The aggregate correlations we document are large enough to explain some of the key swings in US productivity growth since the 1950s. Surges in public–private innovation coincide with the ‘prosperous’ 1950s, the ‘roaring’ 1990s, and the productivity slowdown of the 2000s. Had government-funded innovation during the 2000s remained at its 1990s pace, total factor productivity in 2007 would have been 5–10% higher than it actually was.

This underscores an often-overlooked aspect of innovation policy: its macroeconomic externalities. When fiscal tightening or budget cuts reduce public research spending, the impact extends well beyond the lab. It dampens private R&D, slows productivity growth, and ultimately lowers potential output. Conversely, strategic investment in science can serve as a medium-term stabiliser — a finding consistent with the fiscal-growth literature on ‘productive government spending’ (Antolin-Diaz and Surico 2025, Fornaro and Wolf 2025).

Policy lessons

Our findings point to three key lessons for policymakers:

1. Protect public research budgets. Cutting funding for NIH and NSF may deliver short-term savings, but risks undermining the long-run engine of US productivity and global competitiveness.
2. Leverage public–private complementarities. The most powerful innovations arise when government funds fundamental research, and private actors translate it into applications. Policy should continue to encourage this division of labour.
3. Invest in basic science. Research institutes and universities generate the highest macroeconomic returns per dollar of public support, especially in health, energy, and emerging technologies.

At a time when the US faces mounting competition from state-driven innovation models abroad, the evidence from seven decades of data is unambiguous: America’s technological leadership is itself a public achievement. As Vannevar Bush warned in 1945, “Industry will rise to the challenge of applying new knowledge — but basic research is essentially non-commercial in nature. It will not receive the attention it requires if left to industry.”

Source : VOXeu