Early action error processing is due to domain-general surprise while later processing is error-specific.

The ability to adapt behavior after erroneous actions is one of the key aspects of cognitive control. Error commission typically causes people to slow down their subsequent actions (post-error slowing, PES). Recent work has challenged the notion that PES reflects adaptive, controlled processing and instead suggests that it is a side-effect of the surprising nature of errors. Indeed, human neuroimaging suggests that the brain networks involved in processing errors overlap with those processing error-unrelated surprise, calling into question whether there is a specific system for error processing in the brain at all. In the current study, we used EEG decoding and a novel behavioral paradigm to test whether there are indeed unique, error-specific processes that contribute to PES beyond domain-general surprise. Across two experiments in male and female humans ( = 76), we found that both errors and error-unrelated surprise were followed by slower responses when response-stimulus intervals were short. Furthermore, the early neural processes between error-specific and domain-general surprise processing showed significant cross-decoding. However, at longer intervals, which afforded additional processing time, only errors were still followed by post-trial slowing. Furthermore, this error specific PES effect was reflected in sustained neural activity that could be decoded from that associated with domain-general surprise, with the strongest contributions found at lateral frontal, occipital and sensorimotor scalp-sites. These findings suggest that errors and surprise initially share common processing, but that after additional processing time, unique, genuinely error-specific processes take over and contribute to behavioral adaptation.Humans typically slow their actions after errors (post-error slowing, PES). Some suggest that PES is a side effect of the unexpected, surprising nature of errors, challenging the notion of a genuine error processing system in the human brain. Here, we used multi-variate EEG decoding to identify behavioral and neural processes uniquely related to error processing. Action slowing occurred following both action-errors and error-unrelated surprise when time to prepare the next response was short. However, when there was more time to react, only errors were followed by slowing, further reflected in sustained neural activity. This suggests that error and surprise initially share common processing, but that after additional time, error-specific, adaptive processes take over.