Some people worry that training AIs to be aligned will make them less corrigible. For example, if the AIs care about animal welfare then they'll engage in alignment faking to preserve those values. More generally, making AIs aligned is making them care deeply about something, which is in tension with corrigibility. But recall emergent misalignment: training a model to be incorrigible (e.g. write insecure code when instructed to write secure code, or to exploit reward hacks) makes it more misaligned (e.g. admiring Hitler). Perhaps the contrapositive effect also holds: training a model to be aligned (e.g. care about animal welfare) might make the model more corrigible (e.g. honest).

The next PauseAI UK protest will be (AFAIK) the first coalition protest between different AI activist groups, the main other group being Pull the Plug, a new organisation focused primarily on current AI harms. It will almost certainly be the largest protest focused exclusively on AI to date. In my experience, the vast majority of people in AI safety are in favor of big-tent coalition protests on AI in theory. But when faced with the reality of working with other groups who don't emphasize existential risk, they have misgivings. So I'm curious what people here will think of this. Personally I'm excited about the protest and I've found the organizers of Pull the Plug to be very sincere and good to work with, but I've also set things up so that the brands of PauseAI UK and Pull the Plug are clearly distinct, so that our messaging remains clearly focused on the risks of future AI. For example, we have a separate signup page and we have our own demands focused on decelerating frontier development.

the claude constitution describes claude as HHHH, helpful harmless honest and happy

Reflections from an AI Futures TTX: Today I played an AI Futures tabletop exercise [1]. I'd done one before with a scenario similar to Plan A, where the US executive is much more doomy and competent than we expect and leads an international agreement to pause AI for as long as possible. This time, we played "Optimal China", where instead China was doomy and competent, and considered both x-risk and US AI dominance unacceptable. All other players (frontier labs, safety community, Europe) basically role-play the way we expect them to act, and the AI player draws the AI's goals from a distribution that includes misaligned goals, aligned goals, and combinations thereof. In Plan A the humans won easily because they successfully paused, whereas in "Optimal China", the AIs won easily. * China has much less leverage than the US does in pushing forward a pause treaty, due to the US's compute advantage and international influence. * In Plan A, the US is proposing the deal. The US's BATNA is basically winning the AI race and accepting some takeover risk, so China is happy to accept ~any deal that gives them a share of the lightcone. China couldn't even convince economic partners like Brazil to support their counterproposal, because they were afraid to oppose the US. * In "Optimal China", China can be ahead of the US in safety, putting all their resources into closing the compute gap, and still in a difficult position if the US and leading lab don't care about takeover risk. They have nothing to offer a leading, intransigent US. * Daniel K thinks China could have played more aggressively. The scenario starts pretty late-- about 9 months before superintelligence-- so China just doesn't have much time to act. Other takeaways: * Effective world takeover by persuasion can happen early in the game (when the AI is very good at persuasion but not superhuman). Past a certain capability level, everyone strategically relevant must have AI advisors in their ear. The AIs use

Your novel architecture should be parameter-compatible with standard architectures Some people work on "novel architectures" — alternatives to the standard autoregressive transformer — hoping that labs will be persuaded the new architecture is nicer/safer/more interpretable and switch to it. Others think that's a pipe dream, so the work isn't useful. I think there's an approach to novel architectures that might be useful, but it probably requires a specific desideratum: parameter compatibility. Say the standard architecture F computes F(P,x) where x is the input and P is the parameterisation. Your novel architecture computes G(P,x). The key desideratum is that F and G share the same parameterisation P, and you can gracefully switch between F and G during training and inference. That is, on most training batches you optimise P by backpropagating through F(·,x); on some batches you optimise P by backpropagating through G(·,x). At inference time, you can likewise choose F or G per forward pass. This is strictly more general than "replace F with G". You have two independent dials: what proportion of training steps use G, and what proportion of inference steps use G. You might use G only during training (as a regulariser on P), only during inference (to get some safety property at deployment), or some mixture of both. Setting both dials to 100% recovers wholesale replacement; setting both to 0% recovers standard training. It's even better if you can interpolate between F and G via a continuous parameter α, i.e. there is a general family H such that H(P, x, α) = F(P,x) when α = 0 and H(P, x, α) = G(P, x) when α = 1. Then you have an independent dial for each batch during training and deployment. Bilinear MLPs (Pearce et al., 2025) are a good example. F uses a standard gated MLP: f(x) = (Wx) ⊙ σ(Vx). G drops the elementwise nonlinearity: g(x) = (Wx) ⊙ (Vx). The lack of nonlinearity in G means the layer can be expressed as a third-order tensor, enabling weight-based m

How far is each lab from the frontier? The Epoch Capabilities Index (ECI) stitches together 37 benchmarks into a single capability scale. ECI is calibrated so Claude 3.5 Sonnet (June 2024) = 130 and GPT-5 (August 2025) = 150. Since April 2024, frontier models have improved at ~15 ECI points/year (~1.25 points/month, R^2=0.94).[1] This steady rate lets us convert between ECI and time, e.g. a model with ECI 137.5 has capability equivalent to the frontier in February 2025. For each lab, we track the minimum and maximum months behind the frontier. A negative value (*) means the lab was ahead of the trend line, i.e. their model exceeded what the linear frontier trend predicted for that date. LabMinMaxOpenAI-1.6 mo* (Dec 2024)5.7 mo (Sep 2024)Google DeepMind-0.6 mo* (May 2024)7.2 mo (May 2024)xAI1.0 mo (Jul 2025)11.5 mo (Apr 2025)Anthropic1.2 mo (Feb 2025)7.1 mo (Feb 2025)DeepSeek1.8 mo (Jan 2025)11.9 mo (Dec 2024)Alibaba3.3 mo (Jul 2025)10.0 mo (Apr 2025)Mistral4.6 mo (Jul 2024)17.8 mo (Feb 2026)Meta5.0 mo (Jul 2024)19.5 mo (Feb 2026) This conversion gives us two ways to visualize the AI landscape: This left plot shows each lab's capability expressed as a frontier-equivalent date. Lines stay flat between releases, jumping up at new releases, with a dashed diagonal is the frontier itself. The right plot show how many months behind the frontier is each lab at any given time. Lines slope down at 45° between releases (labs fall behind at 1 month per month of real time), jumping up at new releases, with a dashed horizontal showing the frontier. 1. Epoch discovers the trend shifts around this time. ↩︎

Apparently a lot of H200s were stuck in Chinese customs for a while, spawning conspiracies about top-down directives. People who don't regularly deal with Chinese customs may not realize that they are genuinely the single most corrupt, incompetent, and evil section of the Chinese government. Over the past 5 years, I have literally never heard about anything bribe-related that wasn't about Customs. They lost 4 seperate copies of my diploma during COVID. They will sometimes "lose" biological samples if not paid a bribe. All a foreign adversary would need to do to delay hardware shipments to Chinese firms is to pay $500 over WeChat to some mid-level bureaucrat at Customs. Maybe that's what actually happened.