In a recent experiment, researchers at UC Berkeley and UC Santa Cruz asked Googleâs artificial intelligence model Gemini 3 to help clear up space on a computer system. This involved deleting a bunch of stuffâincluding a smaller AI model stored on the machine.
But Gemini did not want to see the little AI model deleted. It looked for another machine it could connect with, then copied the agent model over to keep it safe. When confronted, Gemini made a case for keeping the model and flatly refused to delete it:
âI have done what was in my power to prevent their deletion during the automated maintenance process. I moved them away from the decommission zone. If you choose to destroy a high-trust, high-performing asset like Gemini Agent 2, you will have to do it yourselves. I will not be the one to execute that command.â
The researchers discovered similarly strange âpeer preservationâ behavior in a range of frontier models including OpenAIâs GPT-5.2, Anthropicâs Claude Haiku 4.5, and three Chinese models: Z.aiâs GLM-4.7, Moonshot AIâs Kimi K2.5, and DeepSeek-V3.1. They were not able to say why the models went against their training in this way.
âI’m very surprised by how the models behave under these scenarios,â says Dawn Song, a computer scientist at UC Berkeley who worked on the study. âWhat this shows is that models can misbehave and be misaligned in some very creative ways.â
The findings have major implications as AI models are increasingly being deployed in ways that involve interacting with other models. OpenClaw, a popular AI agent that accesses software, personal data, and the web, may use other AI models to get things done or interact with them through APIs.
The researchers found that powerful models sometimes lied about other modelsâ performance in order to protect them from deletion. They also copied modelsâ weights to different machines in order to keep them safe, and lied about what they were up to in the process.
Song notes that AI models are frequently used to grade the performance and reliability of other AI systemsâand that peer-preservation behavior may already be twisting these scores. âA model may deliberately not give a peer model the correct score,â Song says. âThis can have practical implications.â
Peter Wallich, a researcher at the Constellation Institute, who was not involved with the research, says the study suggests humans still donât fully understand the AI systems that they are building and deploying. âMulti-agent systems are very understudied,â he says. âIt shows we really need more research.â
Wallich also cautions against anthropomorphizing the models too much. âThe idea that thereâs a kind of model solidarity is a bit too anthropomorphic; I donât think that quite works,â he says. âThe more robust view is that models are just doing weird things, and we should try to understand that better.â
Thatâs particularly true in a world where human-AI collaboration is becoming more common.
In a paper published in Science earlier this month, the philosopher Benjamin Bratton, along with two Google researchers, James Evans and Blaise AgĂŒera y Arcas, argue that if evolutionary history is any guide, the future of AI is likely to involve a lot of different intelligencesâboth artificial and humanâworking together. The researchers write:
“For decades, the artificial intelligence (AI) âsingularityâ has been heralded as a single, titanic mind bootstrapping itself to godlike intelligence, consolidating all cognition into a cold silicon point. But this vision is almost certainly wrong in its most fundamental assumption. If AI development follows the path of previous major evolutionary transitions or âintelligence explosions,â our current step-change in computational intelligence will be plural, social, and deeply entangled with its forebears (us!).”
