There is a thought experiment worth sitting with. Imagine a first-year engineering student in 2026. Before she understands what a differential equation represents โ€” what it feels like to struggle with one, to stare at it, to fail, and eventually to break through โ€” she has already learned to type it into an AI assistant and receive a worked solution. Before a junior solicitor has memorised the structure of a tortious claim, he has learned to prompt a legal AI for the framework. Before a new medical resident has developed the clinical intuition to recognise sepsis from a constellation of subtle signs, her hospital's AI system has already flagged the alert.

The work gets done. The patient is treated. The brief is filed. The calculation is submitted. But something else has also happened โ€” or rather, failed to happen. The hard, frustrating, neurologically formative process of struggling with difficult material, getting it wrong, and building a mental model through effort has been quietly bypassed. The question this article confronts is a serious one: at scale, and over time, is artificial intelligence routing around the very cognitive processes that make expertise possible?

This is not a Luddite argument. AI is a genuinely transformative technology, and many of its educational and productivity applications are real and valuable. The Harvard physics study we discuss below demonstrated that a well-designed AI tutor can double learning gains. The question is not whether AI is good or bad. The question is whether we are using it in ways that systematically undermine the development of human judgment โ€” and whether we have thought through what that means for the next generation of professionals.

โš ๏ธ The Performance Paradox
A growing body of research has documented what cognitive scientists are calling the "performance paradox": AI tools consistently boost a student's or worker's performance on an immediate task while simultaneously diminishing the durable learning and skill retention that is the actual goal of education and professional formation. You get the output. You do not get the growth.

How We Actually Learn: Why the Struggle Matters

To understand what AI risks short-circuiting, it helps to understand what cognitive scientists know about skill acquisition. The dominant model in educational psychology, developed through decades of research by scholars including K. Anders Ericsson, Robert Bjork, and John Sweller, is that durable learning requires desirable difficulty. That is, learning proceeds fastest โ€” and sticks most reliably โ€” when the learner is operating at the edge of their current ability, making errors, and being forced to retrieve and reconstruct knowledge rather than simply recognising it.

Robert Bjork's concept of desirable difficulties โ€” techniques like spaced retrieval practice, interleaving problem types, and reducing immediate feedback โ€” produce slower apparent progress in the short term but dramatically superior long-term retention and transfer. The mechanisms are neurological: when you struggle to retrieve a memory, the hippocampus strengthens the encoding. When you are given the answer, the encoding pathway is bypassed.

This is the fundamental tension with AI assistance. When a student asks an AI to solve a maths problem, explain a concept, or draft an argument, the product is generated outside the student's working memory. There is no effortful retrieval. There is no error, no correction, no neural reinforcement of the correct pathway. The student receives an output that may be excellent. They learn almost nothing.

"We distinguish between the experience of learning, which should feel challenging and even uncomfortable, and the experience of being informed, which feels effortless. AI tools are extraordinarily good at informing. They may be actively harmful as learning tools when used to replace effortful practice." โ€” Frontiers in Psychology, The Cognitive Paradox of AI in Education: Between Enhancement and Erosion, 2025

This distinction matters enormously in professional formation. The junior lawyer who reads fifty contracts doesn't just learn what contracts contain โ€” they develop a pattern-recognition system for anomalies, unusual clauses, and risks that cannot be easily articulated or transferred. The junior engineer who manually calculates dozens of drainage designs doesn't just get the numbers โ€” they develop an intuitive sense of when a result is plausible, a professional instinct that is the foundation of responsible engineering judgment. These capacities are not separable from the struggle of acquiring them.

The Evidence: What Research Is Finding

The empirical literature on AI and cognition is still young โ€” generative AI tools only reached mass adoption in 2022โ€“2023 โ€” but a clear and consistent pattern is emerging across multiple independent research programmes.

The MIT Media Lab EEG Study (2025)

Perhaps the most striking study to date comes from MIT's Media Lab, where researchers fitted 54 students with electroencephalography (EEG) headsets and monitored their neural activity during writing tasks over four months. Students were divided into three groups: one used ChatGPT, one used search engines, and one wrote without AI assistance.

The results were stark. Students who used ChatGPT showed significantly weaker brain connectivity compared to the other groups โ€” the kind of neural patterning associated with reduced memory consolidation and lower-order processing. Most alarmingly, 83% of the AI-assisted group could not accurately recall passages from essays they had just written. The essays existed as text; the learning had not occurred.

The most troubling finding was the persistence of the effect. Even after students stopped using AI, their brain activity remained sluggish relative to baseline โ€” suggesting that the cognitive habits formed during AI use may not be easily reversed. It is worth noting that this study is small (54 participants) and has not yet completed peer review, and should be treated as preliminary; however, it is consistent with the broader direction of the literature.

The MDPI / Society Studies on Cognitive Offloading (2025)

A broader review published in the MDPI journal Society synthesised evidence on cognitive offloading โ€” the phenomenon of outsourcing mental work to external tools โ€” and found a significant negative correlation between frequent AI tool usage and critical thinking abilities, with the relationship mediated by increased cognitive offloading. Younger participants showed higher AI dependence and lower critical thinking scores than older participants, consistent with developmental vulnerability during the years when professional reasoning skills are being formed.

The University of Technology Sydney Report (2026)

A white paper from UTS published in early 2026 warned specifically of "cognitive atrophy" in school-age learners where AI use is unstructured. The paper argued that consistent offloading of cognitive work to AI systems during critical developmental windows creates a dependency that progressively reduces the learner's capacity for independent reasoning โ€” not through any dramatic failure, but through a gradual, asymptomatic erosion of mental muscle.

The Positive Case: Harvard Physics (2024)

Not all the evidence is negative, and it is important to be honest about this. A well-designed randomised controlled trial at Harvard, led by Gregory Kestin and Kelly Miller, found that students using a custom AI tutor in an introductory physics class achieved approximately double the learning gains of students in standard active-learning lectures โ€” in less time. The key design choice was that the AI (called "PS2 Pal") was explicitly programmed not to provide direct answers. It guided students one step at a time, asked questions, and required the student to do the cognitive work. The AI functioned as a Socratic tutor, not an answer machine.

This finding is critically important. It demonstrates that AI can enhance learning โ€” but only when it is designed to require cognitive engagement rather than replace it. The Harvard result is a reproach not to AI in education but to the manner in which most AI is currently used in education.

๐Ÿ“Œ The Key Distinction
The evidence consistently supports a single conclusion: AI that demands active thinking from the learner can improve outcomes. AI used as a shortcut around thinking consistently degrades long-term skill development. The problem is not the technology; it is how we have chosen to deploy it.

Summary of Key Studies

Study / Source Year Finding Verdict
MIT Media Lab EEG Study 2025 AI-assisted writers showed weaker brain connectivity; 83% couldn't recall what they had written. Effects persisted after stopping AI use. Concerning
MDPI Society โ€” Cognitive Offloading 2025 Significant negative correlation between AI use frequency and critical thinking; stronger effect in younger users. Concerning
Frontiers in Psychology โ€” Cognitive Paradox 2025 Documents "performance paradox": AI boosts task performance while reducing durable learning. Concerning
UTS โ€” Cognitive Atrophy in Schools 2026 Unstructured AI use in schools risks progressive cognitive atrophy in developing minds. Concerning
Harvard Physics AI Tutor (Kestin & Miller) 2024 Custom AI tutor doubled learning gains vs active-learning lecture โ€” but was designed to require effortful student thinking. Positive (design-dependent)
Aalto University โ€” Dunning-Kruger AI Study 2025 AI users significantly overestimate their own competence; effect is strongest among the most AI-literate participants. Concerning
UK HEPI Student AI Survey 2025 92% of students use AI; only 28% say their institution meaningfully integrates AI literacy into programmes. Mixed / Urgent
NCBI / Oncology โ€” Intuition Rust Study 2024 Year-long study of cancer specialists found initial AI gains hid "intuition rust" and chronic skill atrophy over time. Concerning

We Have Been Here Before: The GPS Precedent

For those who find the AI-cognition research alarming, there is both comfort and warning in a directly analogous story that played out over the preceding two decades: the adoption of GPS navigation.

A peer-reviewed study published in Scientific Reports in 2020 examined the relationship between habitual GPS use and spatial memory, using a large longitudinal dataset. The findings were unequivocal: people with greater lifetime GPS experience show worse spatial memory during self-guided navigation. More significantly, greater GPS use since initial testing was associated with a steeper decline in hippocampal-dependent spatial memory over time. The mechanism is straightforward โ€” GPS-based navigation removes the cognitive requirement of building a mental map. Because the external tool does the work, the brain's spatial processing circuits receive less activation, and their capacity gradually diminishes.

This is cognitive offloading made manifest in the hippocampus. It is not hypothetical. It is documented, longitudinal, and neurological. The GPS analogy is instructive in another way: we accepted the trade-off largely without discussion. Almost nobody argues that we should ban GPS. But we also did not, as a society, think carefully about which cognitive capacities it was eroding or design compensating practices into education systems.

We are making the same mistake with AI, at far greater scale and across far more cognitively central domains.

The Writing Skills Crisis in Higher Education

Writing is not merely a communication skill. It is a thinking technology โ€” the process of committing ideas to text forces clarification, exposes logical gaps, and generates the kind of slow, deliberate reasoning that complex problem-solving requires. When we outsource writing to AI, we do not merely save time. We lose the cognitive product that writing produces.

The scale of AI adoption in student writing is now beyond dispute. A 2025 survey by the UK's Higher Education Policy Institute found that 92% of students used AI in some capacity, up from 66% the previous year. A large majority reported using it for essay drafts, literature summaries, and argument construction. A systematic review in ScienceDirect (2026) on ChatGPT's cognitive impact in higher education found that "students who regularly delegated essay composition to AI showed significantly weaker performance on timed analytical writing tasks where AI was unavailable" โ€” suggesting that the skill is not developing even as AI-assisted output improves.

The Brookings Institution, in a widely cited 2025 analysis, argued directly that "AI has rendered traditional writing skills obsolete" and that "education needs to adapt." But there is a meaningful distinction between adapting assessment frameworks and accepting that the underlying cognitive capacity need no longer be developed. The ability to construct a coherent, evidence-grounded, logically sequenced argument is not merely an assessment box to be ticked. It is the fundamental cognitive product of a university education โ€” and arguably of professional life.

"They can do B-plus work all the time. The worry is not that they are writing badly. The worry is that they are not developing the capacity to think at all." โ€” University of Edinburgh writing instructor, quoted in Tandfonline / Taylor & Francis: AI & the End of College Writing as We've Known It, 2025

The problem is compounded by what researchers have called "AI-induced cognitive dissonance": students know, at some level, that the work is not theirs, but they also feel productive and capable. Over time, the gap between their perceived competence and their actual independent capability grows โ€” often invisibly, until a high-stakes moment (a professional presentation, a complex client deliverable, a technical examination) exposes the deficit.

The Overconfidence Trap: A Reverse Dunning-Kruger Effect

Among the most troubling findings in the recent literature is research from Aalto University suggesting that AI use is generating a systematic and paradoxical overconfidence in users' own capabilities.

The classic Dunning-Kruger effect holds that people with limited knowledge in a domain tend to overestimate their competence, while genuine experts tend toward under-confidence. AI appears to invert this. Researchers at Aalto found that AI-literate users โ€” those most experienced with AI tools โ€” were the most likely to overestimate their own independent performance. The mechanism is cognitive: using AI to produce high-quality output generates a feeling of competence that is not tethered to any genuine capability. The student feels like a good writer because the AI produces good writing under their direction. The junior engineer feels competent because the AI's structural calculations are sound. The confidence is real; the underlying skill may not be.

A separate study published in TechXplore (October 2025) confirmed this pattern: AI use makes users overestimate their cognitive performance on tasks completed with AI assistance, and the overestimation does not diminish with experience โ€” it grows. Users become more confident the more they use AI, even as their independent performance remains static or declines.

๐Ÿง  The Competence Illusion
This is the most dangerous cognitive effect of AI dependence: students and professionals who have never developed a skill feel confident that they possess it, because AI tools produce its outputs. They will not discover the gap until they are in a situation where the AI is unavailable, unreliable, or simply wrong โ€” and they lack the independent judgment to recognise it.

This has direct professional safety implications. A structural engineer who cannot sanity-check an AI-generated load calculation is not merely less capable โ€” they are a liability. A doctor who cannot form an independent differential diagnosis when the AI system gives an implausible result is a patient safety risk. A lawyer whose legal reasoning has never been formed through effortful practice cannot recognise when the AI's case summary contains a material error. The competence illusion is not merely an academic problem. It is a safety and ethics problem.

The Vanishing Apprenticeship: AI and the Entry-Level Crisis

Professional formation in most fields has always relied on a structured progression: entry-level roles provide the foundational experience โ€” the tedious debugging, the routine client correspondence, the standard contract drafts, the routine site inspections โ€” through which young professionals develop the pattern recognition, professional judgment, and cultural understanding that cannot be taught in a classroom. This apprenticeship model, whether formalised or informal, is how expertise transfers from one generation to the next.

AI is disrupting this model at its base. The tasks that were routinely assigned to graduates and junior staff โ€” precisely because they were instructive, even if not complex โ€” are now increasingly automated. And the hiring decisions that follow reflect this.

The Numbers

The data on entry-level hiring in AI-exposed sectors are stark:

Salesforce CEO Marc Benioff confirmed in late 2024 that the company would not be hiring any new software engineers in 2025, citing a 30% productivity increase from its internal use of AI tools. While Salesforce later reversed course โ€” hiring 1,000 graduates and interns in a high-profile announcement โ€” the initial decision reflected a calculation that many other companies have quietly executed without announcement: if one senior engineer with AI assistance can now produce the output of three, why maintain a junior cohort?

The Structural Problem

The answer to that question โ€” one that many organisations are failing to ask โ€” is that junior roles are not merely cheap labour. They are the mechanism by which senior talent is produced. The five-to-seven-year development pipeline from graduate intake to independent senior professional cannot be compressed or skipped. It can only be deferred โ€” at which point it becomes a crisis.

"Entry-level, junior-level roles are the breeding ground for the leadership of the future. If you overcut that junior layer, you will have a talent bottleneck at some point in the business that leads invariably to an increase in hiring costs." โ€” Quoted in CNBC, In Defense of Junior Staff: Why Replacing Young People with AI Could Spark a 'Talent Doom Cycle', November 2025

The CNBC reporting on the "talent doom cycle" captures the dynamic precisely: companies that eliminate junior hiring to capture short-term AI productivity gains will find themselves, in five to seven years, unable to staff senior roles from internal progression. They will then be forced to compete in an external senior talent market that is itself constrained, because their competitors made the same decision. Hiring costs surge, institutional knowledge is lost, and the very productivity advantage that justified the original cuts is eroded by the cost of external recruitment.

AI Weekly reported in early 2026 that analysts are projecting a significant senior talent shortage beginning around 2031 as a direct consequence of junior hiring freezes since 2023 โ€” precisely the five-to-seven-year pipeline timeline playing out.

Case Studies Across Professions

Software Engineering

The GitHub Copilot Code Quality Paradox

Research from Uplevel Data Labs found that developers with Copilot access showed a significantly higher bug rate, even as their throughput remained consistent โ€” suggesting that AI accelerates output while allowing errors to pass undetected. Separately, the Stack Overflow blog reported that tasks once assigned to junior developers โ€” debugging, writing tests, routine maintenance โ€” are now automated, eliminating the very experiences through which those developers would have learned to write correct code. Some organisations have responded with "Copilot-free Fridays" to prevent skill atrophy.

Medicine

The Colonoscopy Deskilling Study

A peer-reviewed multicenter randomised trial published in Springer Nature (2025) found that endoscopists who used AI assistance for adenoma detection showed a statistically significant drop in their detection rate โ€” from 28.4% to 22.4% โ€” when AI was removed and they reverted to unassisted practice. The AI had been doing the perceptual work; the clinicians' pattern recognition had not kept pace. The American Medical Association has highlighted deskilling risk across radiology, pathology, and cardiology as AI clinical tools proliferate.

Professional Services

Junior Lawyers and the Argument-Drafting Problem

Law firms that have adopted AI drafting tools report junior associates producing higher-volume output with reduced supervision time. The problem emerges at client meetings, oral argument preparation, and complex cross-jurisdictional matters โ€” situations where the AI cannot be present and the lawyer must reason independently. Partners at several major firms have noted, off-record, that associates who have relied heavily on AI drafting tools show weaker independent analytical performance than associates of equivalent experience from five years ago. No large-scale study has yet quantified this, but the concern is widespread in the profession.

Civil & Structural Engineering

The Lost Calculation Culture

Senior engineers at consulting firms report a growing concern: graduates who have been trained with AI-assisted structural analysis tools demonstrate fluency with software outputs but struggle with independent order-of-magnitude checking. The ability to estimate whether a result is physically plausible โ€” a core professional safety competence โ€” is typically developed through years of manual calculation. When the manual calculation is replaced by AI-generated outputs from day one, the intuitive sense of scale never develops. This is not a productivity concern. It is a professional liability concern.

Scientific Research

The Oncology "Intuition Rust" Study

A year-long longitudinal study of cancer specialists using AI diagnostic support, published via NCBI, found that initial operational gains โ€” faster diagnoses, reduced workload โ€” masked a progressive "intuition rust" in participating clinicians. Over time, asymptomatic effects evolved into what the researchers called "chronic harms": reduced ability to form independent clinical judgments without AI support, and reduced confidence in doing so. The study is among the clearest longitudinal evidence that AI skill atrophy is not merely theoretical.

Journalism & Research

The Hallucination Trust Problem

Multiple newsrooms and research institutions have reported incidents where junior staff accepted AI-generated citations, quotes, or data summaries without verification, resulting in published errors. The underlying issue is not the AI's unreliability โ€” which is documented and known โ€” but a professional formation gap: junior staff who have learned to work with AI outputs from the outset have not developed the sceptical instinct that comes from years of manually verifying sources. When the AI confidently produces a plausible-sounding but fabricated citation, the unskilled reviewer cannot tell the difference.

The Microsoft Warning: When Industry Sounds the Alarm

It is one thing for academics and educators to raise concerns about AI and cognitive development. It is another thing entirely when the people building AI tools issue warnings about the professional pipeline they are inadvertently destroying.

In early 2026, Microsoft Azure CTO Mark Russinovich and VP of developer community Scott Hanselman published a peer-reviewed opinion piece in Communications of the ACM โ€” one of computing's most prestigious journals โ€” arguing that agentic AI coding tools are creating a structural crisis in the software engineering profession. The core argument was clear: AI gives senior engineers a massive productivity boost (what the authors call an "AI boost") while simultaneously imposing what they term an "AI drag" on early-in-career (EiC) developers who lack the judgment to steer, verify, and integrate AI output effectively.

The result, as the authors described it, is a new incentive structure in which companies hire senior engineers and automate junior functions โ€” while the talent pipeline that produces the next generation of senior engineers quietly collapses.

"We must keep hiring EiC developers, accept that they initially reduce capacity, and deliberately design systems that make their growth an explicit organisational goal." โ€” Mark Russinovich & Scott Hanselman, Communications of the ACM, 2026

Russinovich cited research showing that after GPT-4's release, employment of 22-to-25-year-olds in AI-exposed jobs including software development fell by roughly 13%, even as senior roles grew. Separate data placed the decline in entry-level developer hiring at 67% since 2022. The authors also made a striking intervention on the education side: "You need some classes where using AI is considered cheating." Not because AI is bad, but because there are foundational skills that can only be built through independent struggle โ€” and that struggle must be deliberately protected.

The proposed solution โ€” a "preceptorship" model adapted from medical residency training, in which senior engineers take formal responsibility for mentoring cohorts of junior developers within product teams โ€” reflects a recognition that the apprenticeship pipeline does not regenerate automatically. It must be actively maintained, even at short-term productivity cost, or it will fail.

๐Ÿฅ The Medical Residency Model
Medicine understood this problem a century ago. A newly qualified doctor does not practise independently โ€” they spend years in supervised clinical environments, taking responsibility for decisions under guidance, making errors in controlled settings, and developing judgment through experience. The training is inefficient by design: it produces friction, deliberate difficulty, and supervised failure. It is the most robust professional formation system in existence. Technology industries are beginning to rediscover why this model exists.

What Good AI Use Looks Like: The Force Multiplier Case

Intellectual honesty requires engaging with the counter-argument. There is genuine, documented evidence that AI, used appropriately, makes workers more capable rather than less โ€” and that the dichotomy between "AI dependence" and "genuine skill" is not as absolute as the alarm literature implies.

AI copilots demonstrably allow senior engineers to produce more output, handle more complex problems, and document their work more comprehensively than they could without assistance. In a 2023 randomised controlled trial involving professional software developers, GitHub Copilot increased coding speed by up to 55% โ€” with no significant reduction in code quality among experienced users. The RAND Corporation published research in 2024 suggesting that AI writing tools could reduce inequality in professional outcomes, allowing workers with strong ideas but weaker writing skills to produce professional-quality communications.

The critical variable in nearly all the research is the existing skill level of the user. Studies consistently find that AI amplifies what is already there. For a senior developer with twenty years of experience, Copilot is a productivity tool โ€” they can verify its outputs, correct its errors, and integrate it into a workflow built on deep understanding. For a first-year student who has never written a working programme independently, Copilot removes the cognitive struggle that would have created that understanding. The tool is identical; the developmental consequences are opposite.

โœ…

AI as a Force Multiplier (Expert Use)

When used by someone with established domain expertise, AI accelerates research, eliminates drudgery, enables faster iteration, improves documentation, and extends the professional's effective capacity. The expert can validate the output, reject errors, and integrate the AI's work into a framework of genuine understanding. This is genuinely valuable and should be embraced.

โš ๏ธ

AI as a Cognitive Bypass (Novice Use)

When used by a novice โ€” particularly in place of the effortful foundational work that builds expertise โ€” AI produces good-looking outputs that mask an absence of understanding. The novice cannot validate the output, cannot detect errors, and does not develop the mental model that would eventually make them an expert. Over time, the capability gap between their perceived and actual competence widens.

๐Ÿซ

Structured AI Use in Education

The Harvard physics study demonstrates that AI designed to demand active thinking can accelerate learning. AI tutors that ask "what do you think happens next?" rather than providing the answer, systems that require students to identify errors in AI-generated work, and tools that scaffold reasoning without completing it โ€” these represent genuinely promising pedagogical applications.

๐Ÿšซ

Unstructured AI Use in Education

AI used as an answer machine โ€” to generate essay drafts, solve problem sets, summarise readings, or produce any output that the student submits without performing the underlying cognitive work themselves โ€” is, on the current evidence, reliably harmful to the development of independent capability. The output is produced; the student is not formed.

What Needs to Change: Recommendations for Institutions and Individuals

The challenges outlined in this article are structural, not individual. They require responses at the level of educational institutions, professional bodies, employing organisations, and policy โ€” not merely the choices of individual students or graduates. The following recommendations reflect the emerging consensus in the research literature.

For Educational Institutions

For Employers and Professional Bodies

For Individual Professionals and Students

The Uncomfortable Verdict

Is AI Making Us Dumber?

The honest answer is: it depends โ€” and the conditions under which the answer is "yes" are exactly the conditions we have sleepwalked into. When AI is used to bypass the effortful, frustrating, neurologically formative work of learning โ€” when it writes the essay, solves the problem, generates the analysis, codes the function โ€” rather than to scaffold or challenge thinking, the evidence strongly suggests that cognitive development is impaired, not enhanced.

The performance paradox is real. The overconfidence effect is real. The GPS precedent is real. The entry-level talent pipeline is genuinely under threat. And the people building AI tools โ€” Microsoft's most senior engineering voices, published in one of computing's most prestigious journals โ€” are explicitly raising the alarm about the pipeline consequences.

None of this means AI should not be used. It means AI should be used with a deliberate, ongoing commitment to also doing the foundational cognitive work that AI could, but must not, replace. That commitment requires conscious effort from individuals, but more importantly it requires structural design from institutions โ€” educational, professional, and organisational โ€” that have not yet caught up with the technology they have unleashed.

The generation of professionals now in university and early career will be shaped by the choices made in the next five years. The question is whether the institutions responsible for their formation are paying attention.

Sources & Further Reading

All sources cited in this article were verified at the time of publication (May 2026).

๐Ÿ”— Related Reading on This Site
For a comprehensive overview of the AI tools and platforms discussed in this article's context, see our companion post: Agentic AI Workflows, Tools & Security in 2026. For the broader picture of how AI is affecting engineering practice, see Artificial Intelligence in Civil & Water Resources Engineering.