In a recent post, Cole Wyeth makes a bold claim:

. . . there is one crucial test (yes this is a crux) that LLMs have not passed. They have never done anything important.
They haven't proven any theorems that anyone cares about. They haven't written anything that anyone will want to read in ten years (or even one year). Despite apparently memorizing more information than any human could ever dream of, they have made precisely zero novel connections or insights in any area of science^[3].

I commented:

An anecdote I heard through the grapevine: some chemist was trying to synthesize some chemical. He couldn't get some step to work, and tried for a while to find solutions on the internet. He eventually asked an LLM. The LLM gave a very

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Cole Wyeth4h20

I do, and I’m shifting in that direction.

Alignment will happen by default. What’s next?

Adrià Garriga-alonso

3mo

This is a linkpost for https://open.substack.com/pub/agarriga/p/alignment-will-happen-by-default

I’m not 100% convinced of this, but I’m fairly convinced, more and more so over time. I’m hoping to start a vigorous but civilized debate. I invite you to attack my weak points and/or present counter-evidence.

My thesis is that intent-alignment is basically happening, based on evidence from the alignment research in the LLM era.

Introduction

The classic story about loss of control from AI is that optimization pressure on proxies will cause the AI to value things that humans don’t. (Relatedly, the AI might become a mesa-optimizer with an arbitrary goal).

But the reality that I observe is that the AIs are really nice and somewhat naive. They’re like the world’s smartest 12-year-old (h/t Jenn). We put more and more RL optimization pressure, and keep getting smarter and smarter models; but they...

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Chris_Leong11h10

The models don't even consider taking over in their 'private thoughts'

It would be strange to seriously consider taking over the world (as opposed to joking about it), if you lack anywhere near the power to do so.

Research note: A simpler AI timelines model predicts 99% AI R&D automation in ~2032

Thomas Kwa

21h

This is a linkpost for https://metr.org/notes/2026-02-10-simpler-ai-timelines-model/

In this post, I describe a simple model for forecasting when AI will automate AI development. It is based on the AI Futures model, but more understandable and robust, and has deliberately conservative assumptions.

At current rates of compute growth and algorithmic progress, this model's median prediction is >99% automation of AI R&D in late 2032. Most simulations result in a 1000x to 10,000,000x increase in AI efficiency and 300x-3000x research output by 2035. I therefore suspect that existing trends in compute growth and automation will still produce extremely powerful AI on "medium" timelines, even if the full coding automation and superhuman research taste that drive the AIFM's "fast" timelines (superintelligence by ~mid-2031) don't happen.

Why make this?

The AI Futures Model (AIFM) has 33 parameters; this has 8.
- I previously

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romeostevensit14h10

Thanks for doing some sensitivity analysis. It's often number one on my list of frustrating things not included in a model.

4elifland17h

Grats on getting this out! I am overall excited about exploring models that rely more on uplift than on time horizons. A few thoughts: It might be nice to indicate how these outputs relate to your all-things-considered views. To me your explicit model seems to be implausibly confident in 99% automation before 2040. I am skeptical that uplift measurements actually give much tighter confidence intervals. After talking to Thomas about this verbally, we both agree that directly using uplift measurements rather than time horizon could plausibly be better by the end of 2026, though we might have different intuitions about the precise likelihood. This isn't true in our model because we allow full coding automation. Given that this is the case in your model, Cobb-Douglas seems like a reasonable approximation.

How do we (more) safely defer to AIs?

ryan_greenblatt, Julian Stastny

As AI systems get more capable, it becomes increasingly uncompetitive and infeasible to avoid deferring to AIs on increasingly many decisions. Further, once systems are sufficiently capable, control becomes infeasible. ^[1] Thus, one of the main strategies for handling AI risk is fully (or almost fully) deferring to AIs on managing these risks. Broadly speaking, when I say "deferring to AIs" ^[2] I mean having these AIs do virtually all of the work to develop more capable and aligned successor AIs, managing exogenous risks, and making strategic decisions. ^[3] If we plan to defer to AIs, I think it's safest...

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Distinguish between inference scaling and "larger tasks use more compute"

ryan_greenblatt

As many have observed, since reasoning models first came out, the amount of compute LLMs use to complete tasks has increased greatly. This trend is often called inference scaling and there is an open question of how much of recent AI progress is driven by inference scaling versus by other capability improvements. Whether inference compute is driving most recent AI progress matters because you can only scale up inference so far before costs are too high for AI to be useful (while training compute can be amortized over usage).

However, it's important to distinguish between two reasons inference cost is going up:

LLMs are completing larger tasks that would have taken a human longer (and thus would have cost more to get a human to complete)
LLMs are using more

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Gordon Seidoh Worley1d33

I think there's a hidden variable in this framework: the effective branching factor of the task. For well-specified tasks (prove this theorem, implement this API to spec, etc.), AI cost probably does scale roughly linearly with task size, matching your model. But most real-world engineering tasks aren't like that. The bottleneck isn't execution speed, it's the iterative discovery of what the task actually is.

A senior engineer doing a 4-hour task isn't typing for 4 hours. They're making dozens of micro-decisions informed by tacit knowledge about the codebas... (read more)

Are there lessons from high-reliability engineering for AGI safety?

Steven Byrnes

10d

This post is partly a belated response to Joshua Achiam, currently OpenAI’s Head of Mission Alignment:

If we adopt safety best practices that are common in other professional engineering fields, we'll get there … I consider myself one of the x-risk people, though I agree that most of them would reject my view on how to prevent it. I think the wholesale rejection of safety best practices from other fields is one of the dumbest mistakes that a group of otherwise very smart people has ever made. —Joshua Achiam on Twitter, 2021
“We just have to sit down and actually write a damn specification, even if it's like pulling teeth. It's the most important thing we could possibly do," said almost no one in the field of AGI alignment,

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3ozziegooen5d

I appreciate that you're engaging in this question, but I have a hard time taking much away from this. Quickly: 1. I think we're both probably skeptical of what Joshua Achiam is approaching. My hunch is that he's representing a particularly niche view on things. 2. It feels to me like there's a gigantic challenge of choosing what scale to approach this problem. You seem to be looking at AGI and it's effects from a very high-level. Like, we need to run evals on massive agents exploring the real world - and if this is too complex for more regular robust engineering, then we better throw out the idea of robust engineering. To me this seems like a bit complaining that "Robust engineering won't work for vehicle safety because it's won't be able to tackle the complex society-wide effects of how vehicles will be used at scale." I think that the case for using more robust methods for AI doesn't look like straightforwardly solving all global-scale large-agent challenges, but instead achieving high reliability levels on much narrower tasks. For example, can we make sure that a single LLM pass has a 99.99% success rate at certain kinds of hacks. This wouldn't solve all the challenges that would come from complex large systems, similar to how vehicle engineering doesn't solve all challenges with vehicles. But it might be able to still be a big part of the solution. You might then argue that a complex system composed of robust parts wouldn't have any benefit from that robustness, because all the 'interesting' stuff happens on the larger scales. My quick guess is that this is one area where we would disagree, perhaps there's a crux here.

Steven Byrnes3d30

(Thanks!) To me, your comment is like: “We have a great plan for robust engineering of vehicles (as long as they are at on a dry, warm, indoor track, going under 10kph).” OK that’s better than nothing. But if we are eventually going to be driving cars at high speed in the cold rain, it’s inadequate. We did not test or engineer them in the right environment.

This is not a complex systems objection (e.g., it’s not about how the world changes with billions of cars). It’s a distribution shift objection. Even just one car will fail at high speed in the cold rain... (read more)

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Introduction

Why make this?