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Javascript is required to display the University of Tokyo website correctly. Please enable Javascript in your browser settings and refresh the page. Skip to content Contact Giving to UTokyo Language 日本語 中文 한국어 Search People UTokyo FOCUS Features Articles Events Press releases Jobs Find stories Search People UTokyo FOCUS Features Articles Events Press releases Jobs Find stories HOME Access and Campus Maps Contact Make a donation 日本語 中文 한국어 FEATURES Japanese Search Search Why does time fly when you’re having fun? Public Relations Office November 25, 2022 Share Tweet Simple questions and UTokyo An introduction to academia starting with “Why?” After making a list of questions which would pique anyone’s interest, we asked faculty members on campus who might be knowledgeable in these areas to answer them from the perspective of their respective expertise. Let’s take a look into the world of research through questions that you feel you know something about, but cannot answer definitively when actually asked. Q4. Why does time fly when you’re having fun? Time seems to move faster when we are having a good time. Why does our perception of time change? A. Because neurotransmitters that “fast-forward” the mind’s clock are released. Answered by Yuko Yotsumoto Professor, Graduate School of Arts and Sciences Cognitive Neuroscience A “pacemaker” ticks in a manner that influences time perception How do we perceive time? One typical way of understanding this is called the “pacemaker model.” The model is based on the idea that there is a ticking pacemaker and accumulator in our mind and that when a certain number of ticks have accumulated in the pacemaker, we feel that a certain amount of time has passed. Fun times seem to pass quickly because the pacemaker ticks faster than usual, making time accumulate in a shorter period than it actually does. This is only a hypothetical conceptual model; we do not literally have a pacemaker in our minds. However, there is a trend in research to try to understand human time perception by assuming the existence of such a pacemaker. There are brain waves with different frequencies, such as alpha and beta waves, that may be related to what accelerates and decelerates the pacemaker. Brain cells are activated while brain waves of various frequencies are synchronized. The timing of the synchronized activity is likely associated with the speed of the pacemaker. fMRI that measures brain structure and function. The brain is scanned with this instrument to study the brain’s perception of time and other aspects of the brain. Image of the brain scanned by fMRI. Dopamine levels increase with enjoyment While our brains have visual and auditory cortices that process sounds and images, no regions dedicated solely to temporal information processing have been found in our brains. From another perspective, all brain regions can influence the pacemaker’s speed. In the brain, the subcortical areas control breathing and regulate body temperature while the cerebral cortex is responsible for higher cognitive functions such as information processing and thinking. Both cortices are also involved in temporal information processing. Among these areas, the basal ganglia are the most influential. They are involved in the release of the neurotransmitter called dopamine. If we lack dopamine, we cannot perceive time properly. The amount of dopamine increases when we feel happy or joyful. There are many things that are still not fully understood about how humans perceive time, and that is what I am researching to find out. My laboratory conducts psychological experiments and functional magnetic resonance imaging (fMRI) for the analysis of brain activity in order to understand the mechanism of time perception, ranging from a few seconds to a few minutes at the longest. For example, when electrodes for electroencephalography are attached to the back of the head for measurement, alpha wave components at around 8 Hz to 12 Hz are often observed. We apply electrical current externally to the electrodes to forcibly accelerate or decelerate the synchronized neural activity. This allows us to measure how time perception is affected. Basic research is not about predicting “what will be useful to the world.” Rather, it is about finding the answers to the mysteries that lie before us through experiments. That is the fun and joy of the process. Investigating the mechanism of human perception of time by measuring brain waves and behavioral experiments. Professor Yotsumoto wearing a head cap that can measure brain waves. Reference book Nou no Naka no Bikkuri Jiten (“An Encyclopedia of Surprises about the inside of the Brain”) (POPLAR Publishing, 2020) This book for children introduces various “disappointments” and “surprises” related to the brain in an easy-to-understand manner and explores the mysteries of the brain. Supervised by Professor Yotsumoto.   * This article was originally printed in Tansei 45 (Japanese language only). All information in this article is as of September 2022. Tansei Brain Medicine and Health Inquiries about the content of this page: Public Relations Office Send inquiry Social media directory Disseminating information for UTokyo during disasters Site map Site policy Privacy policy Jobs UTokyo Portal utelecon Frequently asked questions This website is managed by the Public Relations Office. For inquiries regarding the content of individual pages, please use the contact information listed on each page. 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