Cognitive control enables flexible interaction with a dynamic environment. In two experiments, the authors investigated control adjustments in the stop-signal paradigm, a procedure that requires balancing speed (going) and caution (stopping) in a dual-task environment. Focusing on the slowing of go reaction times after stop signals, the authors tested five competing hypotheses for post-stop-signal adjustments: goal priority, error detection, conflict monitoring, surprise, and memory. Reaction times increased after both successful and failed inhibition, consistent with the goal priority hypothesis and inconsistent with the error detection and conflict hypotheses. Poststop-signal slowing was greater if the go task stimulus repeated on consecutive trials, suggesting a contribution of memory. We also found evidence for slowing based upon more than the immediately preceding stop signal. Post-stop-signal slowing was greater when stop signals occurred more frequently (Experiment 1), inconsistent with the surprise hypothesis, and when inhibition failed more frequently (Experiment 2). This suggests that more global manipulations encompassing many trials affect post-stop-signal adjustments.
Key Words/PhrasesPost-Stop-Signal Slowing; Proactive Control; Cognitive Control; Inhibition; Stop-Signal Paradigm Cognitive control, the ability to adapt mental processes to the demands of the task environment, is of central importance to goal-directed behavior (Logan, 1985;Miyake et al., 2000). Cognitive control often involves resolving competing demands. Many instances of control involve achieving a balance between going and stopping, speed and caution. For example, driving involves balancing when to accelerate and when to brake. In two experiments, we investigated the adjustments subjects made to balance speed and caution in the stop-signal paradigm (Logan & Cowan, 1984), which directly pits going against stopping. Previous research has shown that reaction time (RT) increases after both successful and failed inhibition (Rieger & Gauggel, 1999;Verbruggen, Logan, Liefooghe, & Vandierendonck, 2008). The first motivation for this research was to evaluate five competing hypotheses for these post-stop-signal adjustments: goal priority, error detection, Correspondence should be addressed to Patrick G. Bissett, (Patrick.g.bissett@vanderbilt.edu) or Gordon D. Logan (Gordon.logan@vanderbilt.edu). Both can be contacted at Department of Psychology, Vanderbilt University, Nashville, TN, 37240. Publisher's Disclaimer: The following manuscript is the final accepted manuscript. It has not been subjected to the final copyediting, fact-checking, and proofreading required for formal publication. It is not the definitive, publisher-authenticated version. The American Psychological Association and its Council of Editors disclaim any responsibility or liabilities for errors or omissions of this manuscript version, any version derived from this manuscript by NIH, or other third parties. The published version is available at www.apa.org/pubs/journa...
