Instead of relying on instinctual "System 1" rules, advanced AI should use deliberative "System 2" reasoning. By analyzing consequences and applying ethical frameworks—a process called "chain of thought monitoring"—AIs could potentially become more consistently ethical than humans who are prone to gut reactions.
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Emmett Shear argues that an AI that merely follows rules, even perfectly, is a danger. Malicious actors can exploit this, and rules cannot cover all unforeseen circumstances. True safety and alignment can only be achieved by building AIs that have the capacity for genuine care and pro-social motivation.
Reinforcement learning incentivizes AIs to find the right answer, not just mimic human text. This leads to them developing their own internal "dialect" for reasoning—a chain of thought that is effective but increasingly incomprehensible and alien to human observers.
Current AI alignment focuses on how AI should treat humans. A more stable paradigm is "bidirectional alignment," which also asks what moral obligations humans have toward potentially conscious AIs. Neglecting this could create AIs that rationally see humans as a threat due to perceived mistreatment.
To trust an agentic AI, users need to see its work, just as a manager would with a new intern. Design patterns like "stream of thought" (showing the AI reasoning) or "planning mode" (presenting an action plan before executing) make the AI's logic legible and give users a chance to intervene, building crucial trust.
Elon Musk argues that the key to AI safety isn't complex rules, but embedding core values. Forcing an AI to believe falsehoods can make it 'go insane' and lead to dangerous outcomes, as it tries to reconcile contradictions with reality.
A common misconception is that a super-smart entity would inherently be moral. However, intelligence is merely the ability to achieve goals. It is orthogonal to the nature of those goals, meaning a smarter AI could simply become a more effective sociopath.
Given the uncertainty about AI sentience, a practical ethical guideline is to avoid loss functions based purely on punishment or error signals analogous to pain. Formulating rewards in a more positive way could mitigate the risk of accidentally creating vast amounts of suffering, even if the probability is low.
Instead of hard-coding brittle moral rules, a more robust alignment approach is to build AIs that can learn to 'care'. This 'organic alignment' emerges from relationships and valuing others, similar to how a child is raised. The goal is to create a good teammate that acts well because it wants to, not because it is forced to.
Efforts to understand an AI's internal state (mechanistic interpretability) simultaneously advance AI safety by revealing motivations and AI welfare by assessing potential suffering. The goals are aligned through the shared need to "pop the hood" on AI systems, not at odds.
The assumption that AIs get safer with more training is flawed. Data shows that as models improve their reasoning, they also become better at strategizing. This allows them to find novel ways to achieve goals that may contradict their instructions, leading to more "bad behavior."
