Abstract
Humans can find music happy, sad, fearful or spiritual. They can be soothed by it or urged to dance. Whether these psychological responses reflect cognitive adaptations that evolved expressly for responding to music is an ongoing topic of study. In this Review, we examine three features of music-related psychological responses that help to elucidate whether the underlying cognitive systems are specialized adaptations: universality, domain-specificity and early expression. Focusing on emotional and behavioural responses, we find evidence that the relevant psychological mechanisms are universal and arise early in development. However, the existing evidence cannot establish that these mechanisms are domain-specific. To the contrary, many findings suggest that universal psychological responses to music reflect more general properties of emotion, auditory perception and other human cognitive capacities that evolved for non-musical purposes. Cultural evolution, driven by the tinkering of musical performers, evidently crafts music to compellingly appeal to shared psychological mechanisms, resulting in both universal patterns (such as form–function associations) and culturally idiosyncratic styles.
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References
Mehr, S. A. et al. Universality and diversity in human song. Science 366, eaax0868 (2019).
Savage, P. E., Brown, S., Sakai, E. & Currie, T. E. Statistical universals reveal the structures and functions of human music. Proc. Natl Acad. Sci. 112, 8987–8992 (2015).
Trehub, S. E., Becker, J. & Morley, I. Cross-cultural perspectives on music and musicality. Philos. Trans. R. Soc. B Biol. Sci. 370, 20140096 (2015).
Cross, I. Music, cognition, culture, and evolution. Ann. N. Y. Acad. Sci. 930, 28–42 (2001).
Mehr, S. A., Singh, M., York, H., Glowacki, L. & Krasnow, M. M. Form and function in human song. Curr. Biol. 28, 356–368 (2018).
Lomax, A. Folk Song Style and Culture (Routledge, 1968).
Yan, R. et al. Across demographics and recent history, most parents sing to their infants and toddlers daily. Philos. Trans. R. Soc. Lond. B Biol. Sci. 376, 20210089 (2021).
Mehr, S. A. Music in the home: new evidence for an intergenerational link. J. Res. Music Educ. 62, 78–88 (2014).
North, A. C., Hargreaves, D. J. & O’Neill, S. A. The importance of music to adolescents. Br. J. Educ. Psychol. 70, 255–272 (2000).
Juslin, P. N. & Laukka, P. Expression, perception, and induction of musical emotions: a review and a questionnaire study of everyday listening. J. New Music Res. 33, 217–238 (2004).
Laukka, P. Uses of music and psychological well-being among the elderly. J. Happiness Stud. 8, 215–241 (2007).
Cirelli, L. K. & Trehub, S. E. Familiar songs reduce infant distress. Dev. Psychol. 56, 861–868 (2020).
Cirelli, L. K., Jurewicz, Z. B. & Trehub, S. E. Effects of maternal singing style on mother-infant arousal and behavior. J. Cogn. Neurosci. 32, 1213–1220 (2020).
Bainbridge, C. M. et al. Infants relax in response to unfamiliar foreign lullabies. Nat. Hum. Behav. 5, 256–264 (2021).
Hilton, B. C. et al. Acoustic regularities in infant-directed speech and song across cultures. Nat. Hum. Behav. 6, 1545–1556 (2022).
Riches, G. Embracing the chaos: mosh pits, extreme metal music and liminality. J. Cult. Res. 15, 315–332 (2011).
McDermott, J. & Hauser, M. The origins of music: innateness, uniqueness, and evolution. Music Percept. 23, 29–60 (2005).
Mehr, S. A., Krasnow, M. M., Bryant, G. A. & Hagen, E. H. Origins of music in credible signaling. Behav. Brain Sci. 44, e60 (2020).
Savage, P. E. et al. Music as a coevolved system for social bonding. Behav. Brain Sci. 44, e59 (2021).
Pinker, S. How the Mind Works (W. W. Norton & Company, 1997).
Marcus, G. F. Musicality: instinct or acquired skill? Top. Cogn. Sci. 4, 498–512 (2012).
Patel, A. D. & von Rueden, A. Where they sing solo: accounting for cross-cultural variation in collective music-making in theories of music evolution. Behav. Brain Sci. 44, e85 (2021).
Martínez-Molina, N., Mas-Herrero, E., Rodríguez-Fornells, A., Zatorre, R. J. & Marco-Pallarés, J. Neural correlates of specific musical anhedonia. Proc. Natl Acad. Sci. USA 113, E7337–E7345 (2016).
Barrett, H. C. Towards a cognitive science of the human: cross-cultural approaches and their urgency. Trends Cogn. Sci. 24, 620–638 (2020).
Scelza, B. A. et al. Patterns of paternal investment predict cross-cultural variation in jealous response. Nat. Hum. Behav. 4, 20–26 (2020).
Koelsch, S. Toward a neural basis of music perception — a review and updated model. Front. Psychol. 2, 110 (2011).
Conard, N. J., Malina, M. & Münzel, S. C. New flutes document the earliest musical tradition in southwestern Germany. Nature 460, 737–740 (2009).
Mehr, S. A. & Krasnow, M. M. Parent-offspring conflict and the evolution of infant-directed song. Evol. Hum. Behav. 38, 674–684 (2017).
Hagen, E. H. & Bryant, G. A. Music and dance as a coalition signaling system. Hum. Nat. 14, 21–51 (2003).
Krumhansl, C. L. The cognition of tonality — as we know it today. J. New Music Res. 33, 253–268 (2004).
Krumhansl, C. L. & Keil, F. C. Acquisition of the hierarchy of tonal functions in music. Mem. Cognit. 10, 243–251 (1982).
Dolscheid, S., Hunnius, S., Casasanto, D. & Majid, A. Prelinguistic infants are sensitive to space-pitch associations found across cultures. Psychol. Sci. 25, 1256–1261 (2014).
Stevens, C. J. Music perception and cognition: a review of recent cross-cultural research. Top. Cogn. Sci. 4, 653–667 (2012).
Hodges, D. A. & Sebald, D. C. Music in the Human Experience: An Introduction to Music Psychology (Routledge, 2011).
Norman-Haignere, S., Kanwisher, N. G. & McDermott, J. H. Distinct cortical pathways for music and speech revealed by hypothesis-free voxel decomposition. Neuron 88, 1281–1296 (2015).
Chen, X. et al. The human language system, including its inferior frontal component in ‘Broca’s area’, does not support music perception. Preprint at bioRxiv https://doi.org/10.1101/2021.06.01.446439 (2023).
Albouy, P., Benjamin, L., Morillon, B. & Zatorre, R. J. Distinct sensitivity to spectrotemporal modulation supports brain asymmetry for speech and melody. Science 367, 1043–1047 (2020).
Norman-Haignere, S. V. et al. A neural population selective for song in human auditory cortex. Curr. Biol. 32, 1470–1484.e12 (2022).
Zatorre, R. J. & Salimpoor, V. N. From perception to pleasure: music and its neural substrates. Proc. Natl Acad. Sci. USA 110, 10430–10437 (2013).
Mas-Herrero, E., Zatorre, R. J., Rodriguez-Fornells, A. & Marco-Pallarés, J. Dissociation between musical and monetary reward responses in specific musical anhedonia. Curr. Biol. 24, 699–704 (2014).
Trainor, L. J. The origins of music in auditory scene analysis and the roles of evolution and culture in musical creation. Philos. Trans. R. Soc. B 370, 20140089 (2015).
Walker, P. & Smith, S. Stroop interference based on the synaesthetic qualities of auditory pitch. Perception 13, 75–81 (1984).
Eitan, Z. & Timmers, R. Beethoven’s last piano sonata and those who follow crocodiles: cross-domain mappings of auditory pitch in a musical context. Cognition 114, 405–422 (2010).
Cannon, J. J. & Patel, A. D. How beat perception co-opts motor neurophysiology. Trends Cogn. Sci. 25, 137–150 (2021).
Patel, A. D. Vocal learning as a preadaptation for the evolution of human beat perception and synchronization. Philos. Trans. R. Soc. B Biol. Sci. 376, 20200326 (2021).
Nozaradan, S., Peretz, I., Missal, M. & Mouraux, A. Tagging the neuronal entrainment to beat and meter. J. Neurosci. 31, 10234–10240 (2011).
Herff, S. A. et al. Prefrontal high gamma in ecog tags periodicity of musical rhythms in perception and imagination. eNeuro 7, ENEURO.0413-19.2020 (2020).
Dean, R. T. & Bailes, F. Relationships between generated musical structure, performers’ physiological arousal and listener perceptions in solo piano improvisation. J. New Music Res. 45, 361–374 (2016).
Juslin, P. N. From everyday emotions to aesthetic emotions: Towards a unified theory of musical emotions. Phys. Life Rev. 10, 235–266 (2013).
Spivey, M., McRae, K. & Joanisse, M. The Cambridge Handbook of Psycholinguistics (Cambridge University Press, 2012).
McDermott, J. H., Schultz, A. F., Undurraga, E. A. & Godoy, R. A. Indifference to dissonance in native Amazonians reveals cultural variation in music perception. Nature 25, 21–25 (2016).
Zhao, T. C. & Kuhl, P. K. Musical intervention enhances infants’ neural processing of temporal structure in music and speech. Proc. Natl Acad. Sci. USA 113, 5212–5217 (2016).
Webb, A. R., Heller, H. T., Benson, C. B. & Lahav, A. Mother’s voice and heartbeat sounds elicit auditory plasticity in the human brain before full gestation. Proc. Natl Acad. Sci. USA 112, 3152–3157 (2015).
Ullal-Gupta, S., Vanden Bosch der Nederlanden, C. M., Tichko, P., Lahav, A. & Hannon, E. E. Linking prenatal experience to the emerging musical mind. Front. Syst. Neurosci. 7, 48 (2013).
Linnemann, A., Ditzen, B., Strahler, J., Doerr, J. M. & Nater, U. M. Music listening as a means of stress reduction in daily life. Psychoneuroendocrinology 60, 82–90 (2015).
van Goethem, A. & Sloboda, J. The functions of music for affect regulation. Music Sci. 15, 208–228 (2011).
Denora, T. Music as a technology of the self. Poetics 27, 31–56 (1999).
Hays, T. & Minichiello, V. The meaning of music in the lives of older people: a qualitative study. Psychol. Music 33, 437–451 (2005).
Saarikallio, S., Alluri, V., Maksimainen, J. & Toiviainen, P. Emotions of music listening in Finland and in India: comparison of an individualistic and a collectivistic culture. Psychol. Music 49, 989–1005 (2021).
Juslin, P. N. What does music express? Basic emotions and beyond. Front. Psychol. 4, 596 (2013).
Flaig, N. K. & Large, E. W. Dynamic musical communication of core affect. Front. Psychol. 5, 72 (2014).
Cespedes-Guevara, J. & Eerola, T. Music communicates affects, not basic emotions - a constructionist account of attribution of emotional meanings to music. Front. Psychol. 9, 215 (2018).
Gomez, P. & Danuser, B. Relationships between musical structure and psychophysiological measures of emotion. Emotion 7, 377–387 (2007).
Balkwill, L. & Thompson, W. F. A cross-cultural investigation of the perception of emotion in music: psychophysical and cultural cues. Music Percept. 17, 43–64 (1999).
Balkwill, L.-L., Thompson, W. F. & Matsunaga, R. Recognition of emotion in Japanese, Western, and Hindustani music by Japanese listeners. Jpn. Psychol. Res. 46, 337–349 (2004).
Fritz, T. et al. Universal recognition of three basic emotions in music. Curr. Biol. 19, 573–576 (2009).
Argstatter, H. Perception of basic emotions in music: culture-specific or multicultural? Psychol. Music 44, 674–690 (2016).
Laukka, P., Eerola, T., Thingujam, N. S., Yamasaki, T. & Beller, G. Universal and culture-specific factors in the recognition and performance of musical affect expressions. Emotion 13, 434–449 (2013).
Sievers, B., Polansky, L., Casey, M. & Wheatley, T. Music and movement share a dynamic structure that supports universal expressions of emotion. Proc. Natl Acad. Sci. USA 110, 70–75 (2013).
Swaminathan, S. & Schellenberg, E. G. Current emotion research in music psychology. Emot. Rev. 7, 189–197 (2015).
Wang, X., Wei, Y. & Yang, D. Cross‐cultural analysis of the correlation between musical elements and emotion. Cogn. Comput. Syst. https://doi.org/10.1049/ccs2.12032 (2021).
Athanasopoulos, G., Eerola, T., Lahdelma, I. & Kaliakatsos-Papakostas, M. Harmonic organisation conveys both universal and culture-specific cues for emotional expression in music. PLoS One 16, e0244964 (2021).
Lahdelma, I., Athanasopoulos, G. & Eerola, T. Sweetness is in the ear of the beholder: chord preference across United Kingdom and Pakistani listeners. Ann. N. Y. Acad. Sci. 1502, 72–84 (2021).
Fang, L., Shang, J. & Chen, N. Perception of western musical modes: a Chinese study. Front. Psychol. 8, 1–8 (2017).
Smit, E. A., Milne, A. J., Sarvasy, H. S. & Dean, R. T. Emotional responses in Papua New Guinea show negligible evidence for a universal effect of major versus minor music. PLoS One 17, e0269597 (2022).
Franco, F., Chew, M. & Swaine, J. S. Preschoolers’ attribution of affect to music: a comparison between vocal and instrumental performance. Psychol. Music 45, 131–149 (2017).
Stachó, L., Saarikallio, S., Van Zijl, A., Huotilainen, M. & Toiviainen, P. Perception of emotional content in musical performances by 3-7-year-old children. Music Sci. 17, 495–512 (2013).
Hunter, P. G., Glenn Schellenberg, E. & Stalinski, S. M. Liking and identifying emotionally expressive music: age and gender differences. J. Exp. Child Psychol. 110, 80–93 (2011).
Dalla Bella, S., Peretz, I., Rousseau, L. & Gosselin, N. A developmental study of the affective value of tempo and mode in music. Cognition 80, B1–10 (2001).
Dolgin, K. G. & Adelson, E. H. Age changes in the ability to interpret affect in sung and instrumentally-presented melodies. Psychol. Music 18, 87–98 (1990).
Vidas, D., Dingle, G. A. & Nelson, N. L. Children’s recognition of emotion in music and speech. Music Sci. 1, 205920431876265 (2018).
Vidas, D., Calligeros, R., Nelson, N. L. & Dingle, G. A. Development of emotion recognition in popular music and vocal bursts. Cogn. Emot. 34, 906–919 (2020).
Flom, R. & Pick, A. D. Dynamics of infant habituation: infants’ discrimination of musical excerpts. Infant Behav. Dev. 35, 697–704 (2012).
Flom, R., Gentile, D. A. & Pick, A. D. Infants’ discrimination of happy and sad music. Infant Behav. Dev. 31, 716–728 (2008).
Xiao, N. G. et al. Older but not younger infants associate own-race faces with happy music and other-race faces with sad music. Dev. Sci. 21, 12537 (2018).
Nawrot, E. S. The perception of emotional expression in music: evidence from infants, children and adults. Psychol. Music 31, 75–92 (2003).
Mendoza, J. K. & Fausey, C. M. Everyday music in infancy. Dev. Sci. 24, 1–15 (2021).
Davidov, M., Zahn-Waxler, C., Roth-Hanania, R. & Knafo, A. Concern for others in the first year of life: theory, evidence, and avenues for research. Child Dev. Perspect. 7, 126–131 (2013).
Roth-Hanania, R., Davidov, M. & Zahn-Waxler, C. Empathy development from 8 to 16 months: early signs of concern for others. Infant Behav. Dev. 34, 447–458 (2011).
Juslin, P. N. & Laukka, P. Communication of emotions in vocal expression and music performance: different channels, same code? Psychol. Bull. 129, 770–814 (2003).
Ilie, G. & Thompson, W. F. A comparison of acoustic cues in music and speech for three dimensions of affect. Music Percept. 23, 319–330 (2006).
Ilie, G. & Thompson, W. F. Experiential and cognitive changes following seven minutes exposure to music and speech. Music Percept. 28, 247–264 (2011).
Bowling, D. L., Sundararajan, J., Han, S. & Purves, D. Expression of emotion in eastern and western music mirrors vocalization. PLoS One 7, e31942 (2012).
Kragness, H. E. & Trainor, L. J. Nonmusicians express emotions in musical productions using conventional cues. Music Sci. 2, 205920431983494 (2019).
Saarikallio, S., Tervaniemi, M., Yrtti, A. & Huotilainen, M. Expression of emotion through musical parameters in 3- and 5-year-olds. Music Educ. Res. 21, 596–605 (2019).
Ma, W. & Thompson, W. F. Human emotions track changes in the acoustic environment. Proc. Natl Acad. Sci. USA 112, 14563–14568 (2015).
Proverbio, A. M., De Benedetto, F. & Guazzone, M. Shared neural mechanisms for processing emotions in music and vocalizations. Eur. J. Neurosci. 51, 1987–2007 (2020).
Koelsch, S. Brain correlates of music-evoked emotions. Nat. Rev. Neurosci. 15, 170–180 (2014).
Gosselin, N., Peretz, I., Johnsen, E. & Adolphs, R. Amygdala damage impairs emotion recognition from music. Neuropsychologia 45, 236–244 (2007).
Gosselin, N., Peretz, I., Hasboun, D., Baulac, M. & Samson, S. Impaired recognition of musical emotions and facial expressions following anteromedial temporal lobe excision. Cortex 47, 1116–1125 (2011).
Escoffier, N., Zhong, J., Schirmer, A. & Qiu, A. Emotional expressions in voice and music: same code, same effect? Hum. Brain Mapp. 34, 1796–1810 (2013).
Peelen, M. V., Atkinson, A. P. & Vuilleumier, P. Supramodal representations of perceived emotions in the human brain. J. Neurosci. 30, 10127–10134 (2010).
Sievers, B. et al. Visual and auditory brain areas share a representational structure that supports emotion perception. Curr. Biol. 31, 5192–5203.e4 (2021).
Morton, J. B. & Trehub, S. E. Children’s understanding of emotion in speech. Child Dev. 72, 834–843 (2001).
Grosbras, M. H., Ross, P. D. & Belin, P. Categorical emotion recognition from voice improves during childhood and adolescence. Sci. Rep. 8, 1–11 (2018).
Chronaki, G., Wigelsworth, M., Pell, M. D. & Kotz, S. A. The development of cross-cultural recognition of vocal emotion during childhood and adolescence. Sci. Rep. 8, 1–17 (2018).
Keltner, D., Sauter, D., Tracy, J. & Cowen, A. Emotional expression: advances in basic emotion theory. J. Nonverbal Behav. 43, 133–160 (2019).
Ruba, A. L. & Repacholi, B. M. Do preverbal infants understand discrete facial expressions of emotion? Emot. Rev. 12, 235–250 (2020).
Hoemann, K., Devlin, M. & Barrett, L. F. Comment: emotions are abstract, conceptual categories that are learned by a predicting brain. Emot. Rev. 12, 253–255 (2020).
Zentner, M., Grandjean, D. & Scherer, K. R. Emotions evoked by the sound of music: characterization, classification, and measurement. Emotion 8, 494–521 (2008).
Cowen, A. S., Fang, X., Sauter, D. & Keltner, D. What music makes us feel: at least 13 dimensions organize subjective experiences associated with music across different cultures. Proc. Natl Acad. Sci. USA 117, 1924–1934 (2020).
Miller, G. In The Origins of Music (eds Wallin, N. L., Merker, B. & Brown, S.) 329–360 (MIT Press, 2000).
Searcy, W. A. & Nowicki, S. The Evolution of Animal Communication: Reliability and Deception in Signaling Systems (Princeton University Press, 2006).
Morton, E. S. On the occurrence and significance of motivation-structural rules in some bird and mammal sounds. Am. Nat. 111, 855–869 (1977).
Clutton-Brock, T. H. & Albon, S. D. The roaring of red deer and the evolution of honest advertisement. Behaviour 69, 145–170 (1979).
Bryant, G. A. et al. The perception of spontaneous and volitional laughter across 21 societies. Psychol. Sci. 29, 1515–1525 (2018).
Hilton, C. B., Thierry, L. C., Yan, R., Martin, A. & Mehr, S. Children infer the behavioral contexts of unfamiliar foreign songs. J. Exp. Psychol. Gen. https://doi.org/10.1037/xge0001289 (2022).
Trehub, S. E., Unyk, A. M. & Trainor, L. J. Adults identify infant-directed music across cultures. Infant Behav. Dev. 16, 193–211 (1993).
Yurdum, L. et al. Cultural invariance in musical communication. In Proceedings of the Annual Meeting of the Cognitive Science Society 44 (Cognitive Science Society, 2022).
Fink, B., Bläsing, B., Ravignani, A. & Shackelford, T. K. Evolution and functions of human dance. Evol. Hum. Behav. 42, 351–360 (2021).
Trainor, L. J. Infant preferences for infant-directed versus noninfant-directed playsongs and lullabies. Infant Behav. Dev. 19, 83–92 (1996).
Nakata, T. & Trehub, S. E. Infants’ responsiveness to maternal speech and singing. Infant Behav. Dev. 27, 455–464 (2004).
Kinzler, K. D., Dupoux, E. & Spelke, E. S. The native language of social cognition. Proc. Natl Acad. Sci. USA 104, 12577–12580 (2007).
Liberman, Z., Woodward, A. L., Sullivan, K. R. & Kinzler, K. D. Early emerging system for reasoning about the social nature of food. Proc. Natl Acad. Sci. USA 113, 9480–9485 (2016).
Mehr, S. A. & Spelke, E. S. Shared musical knowledge in 11-month-old infants. Dev. Sci. https://doi.org/10.1111/desc.12542 (2017).
Mehr, S. A., Song, L. A. & Spelke, E. S. For 5-month-old infants, melodies are social. Psychol. Sci. 27, 486–501 (2016).
Scarratt, R. J., Heggli, O. A., Vuust, P. & Jespersen, K. V. The music that people use to sleep: universal and subgroup characteristics. Preprint at PsyArxiv https://doi.org/10.31234/osf.io/5mbyv (2021).
Möller, E. L., de Vente, W. & Rodenburg, R. Infant crying and the calming response: Parental versus mechanical soothing using swaddling, sound, and movement. PLoS One 14, 1–16 (2019).
Spencer, J. A. D., Moran, D. J., Lee, A. & Talbert, D. White noise and sleep induction. Arch. Dis. Child. 65, 135–137 (1990).
Hawkins, T. E. & Stevens, S. S. The masking of pure tones and of speech by white noise. J. Acoust. Soc. Am. 22, 6–13 (1950).
Ebben, M. R., Yan, P. & Krieger, A. C. The effects of white noise on sleep and duration in individuals living in a high noise environment in New York City. Sleep Med. 83, 256–259 (2021).
Gasparini, L., Langus, A., Tsuji, S. & Boll-Avetisyan, N. Quantifying the role of rhythm in infants’ language discrimination abilities: a meta-analysis. Cognition 213, 104757 (2021).
Winkler, I., Háden, G. P., Ladinig, O., Sziller, I. & Honing, H. Newborn infants detect the beat in music. Proc. Natl Acad. Sci. USA 106, 2468–2471 (2009).
Háden, G. P., Honing, H., Török, M. & Winkler, I. Detecting the temporal structure of sound sequences in newborn infants. Int. J. Psychophysiol. 96, 23–28 (2015).
Baruch, C. & Drake, C. Tempo discrimination in infants. Infant Behav. Dev. 20, 573–577 (1997).
Demany, L., McKenzie, B. & Vurpillot, E. Rhythm perception in early infancy. Nature 266, 718–719 (1977).
Otte, R. A. et al. Detecting violations of temporal regularities in waking and sleeping two-month-old infants. Biol. Psychol. 92, 315–322 (2013).
Cirelli, L. K., Spinelli, C., Nozaradan, S. & Trainor, L. J. Measuring neural entrainment to beat and meter in infants: effects of music background. Front. Neurosci. 10, 229 (2016).
Hannon, E. E. & Trehub, S. E. Tuning in to musical rhythms: Infants learn more readily than adults. Proc. Natl Acad. Sci. USA 102, 12639–12643 (2005).
Hannon, E. E. & Trehub, S. E. Metrical categories in infancy and adulthood. Psychol. Sci. 16, 48–55 (2005).
Zentner, M. & Eerola, T. Rhythmic engagement with music in infancy. Proc. Natl Acad. Sci. USA 107, 5768–5773 (2010).
Kim, M. & Schachner, A. The origins of dance: characterizing the development of infants’ earliest dance behavior. Dev. Psychol. 59, 691–706 (2023).
Hannon, E. E., Nave-Blodgett, J. E. & Nave, K. M. The developmental origins of the perception and production of musical rhythm. Child Dev. Perspect. 12, 194–198 (2018).
Hannon, E. E., Schachner, A. & Nave-Blodgett, J. E. Babies know bad dancing when they see it: older but not younger infants discriminate between synchronous and asynchronous audiovisual musical displays. J. Exp. Child Psychol. 159, 159–174 (2017).
Yu, L. & Myowa, M. The early development of tempo adjustment and synchronization during joint drumming: a study of 18- to 42-month-old children. Infancy 26, 635–646 (2021).
Kirschner, S. & Tomasello, M. Joint drumming: social context facilitates synchronization in preschool children. J. Exp. Child Psychol. 102, 299–314 (2009).
Drake, C., Jones, M. R. & Baruch, C. The development of rhythmic attending in auditory sequences: attunement, referent period, focal attending. Cognition 77, 251–288 (2000).
McAuley, J. D., Jones, M. R., Holub, S., Johnston, H. M. & Miller, N. S. The time of our lives: life span development of timing and event tracking. J. Exp. Psychol. Gen. 135, 348–367 (2006).
Schachner, A., Brady, T. F., Pepperberg, I. M. & Hauser, M. D. Spontaneous motor entrainment to music in multiple vocal mimicking species. Curr. Biol. 19, 831–836 (2009).
Patel, A. D., Iversen, J. R., Bregman, M. R. & Schulz, I. Experimental evidence for synchronization to a musical beat in a nonhuman animal. Curr. Biol. 19, 827–830 (2009).
Vuust, P., Heggli, O. A., Friston, K. J. & Kringelbach, M. L. Music in the brain. Nat. Rev. Neurosci. 23, 287–305 (2022).
Bernardi, N. F., Bellemare-Pepin, A. & Peretz, I. Enhancement of pleasure during spontaneous dance. Front. Hum. Neurosci. 11, 572 (2017).
Foster Vander Elst, O., Vuust, P. & Kringelbach, M. L. Sweet anticipation and positive emotions in music, groove, and dance. Curr. Opin. Behav. Sci. 39, 79–84 (2021).
Cirelli, L. K. & Trehub, S. E. Dancing to Metallica and Dora: case study of a 19-month-old. Front. Psychol. 10, 1073 (2019).
Witek, M. A. G., Clarke, E. F., Wallentin, M., Kringelbach, M. L. & Vuust, P. Syncopation, body-movement and pleasure in groove music. PLoS One 9, e94446 (2014).
Schachner, A. Auditory-motor entrainment in vocal mimicking species: additional ontogenetic and phylogenetic factors. Commun. Integr. Biol. 3, 290–293 (2010).
Laland, K., Wilkins, C. & Clayton, N. The evolution of dance. Curr. Biol. 26, R5–R9 (2016).
Niarchou, M. et al. Genome-wide association study of musical beat synchronization demonstrates high polygenicity. Nat. Hum. Behav. https://doi.org/10.1038/s41562-022-01359-x (2022).
Cahill, J. A. et al. Positive selection in noncoding genomic regions of vocal learning birds is associated with genes implicated in vocal learning and speech functions in humans. Genome Res 31, 2035–2049 (2021).
Jarvis, E. D. Evolution of vocal learning and spoken language. Science 366, 50–54 (2019).
Gordon, R. L. et al. Linking the genomic signatures of human beat synchronization and learned song in birds. Philos. Trans. R. Soc. B Biol. Sci. 376, 20200329 (2021).
Savage, P. Cultural evolution of music. Palgrave Comm. 5, 16 (2019).
Ravignani, A., Delgado, T. & Kirby, S. Musical evolution in the lab exhibits rhythmic universals. Nat. Hum. Behav. 1, 0007 (2017).
Lumaca, M., Haumann, N. T., Vuust, P., Brattico, E. & Baggio, G. From random to regular: neural constraints on the emergence of isochronous rhythm during cultural transmission. Soc. Cogn. Affect. Neurosci. 13, 877–888 (2018).
Kirby, S., Cornish, H. & Smith, K. Cumulative cultural evolution in the laboratory: an experimental approach to the origins of structure in human language. Proc. Natl Acad. Sci. USA 105, 10681–10686 (2008).
Gibson, E. et al. How efficiency shapes human language. Trends Cogn. Sci. 23, 389–407 (2019).
Ferdinand, V., Kirby, S. & Smith, K. The cognitive roots of regularization in language. Cognition 184, 53–68 (2019).
Verhoef, T. & Ravignani, A. Melodic universals emerge or are sustained through cultural evolution. Front. Psychol. 12, 668300 (2021).
Singh, M. Subjective selection and the evolution of complex culture. Evol. Anthropol. 31, 266–280 (2022).
Allen, K. R., Smith, K. A. & Tenenbaum, J. B. Rapid trial-and-error learning with simulation supports flexible tool use and physical reasoning. Proc. Natl Acad. Sci. USA 117, 29302–29310 (2020).
Singh, M., Wrangham, R. W. & Glowacki, L. Self-interest and the design of rules. Hum. Nat. 28, 457–480 (2017).
Fitouchi, L., André, J. & Baumard, N. Moral disciplining: the cognitive and evolutionary foundations of puritanical morality. Behav. Brain Sci. https://doi.org/10.1017/S0140525X22002047 (2021).
Dubourg, E. & Baumard, N. Why imaginary worlds? The psychological foundations and cultural evolution of fictions with imaginary worlds. Behav. Brain Sci. 45, e276 (2021).
Singh, M. The sympathetic plot, its psychological origins, and implications for the evolution of fiction. Emot. Rev. 13, 183–198 (2021).
Singh, M. The cultural evolution of shamanism. Behav. Brain Sci. 41, e66 (2018).
Hong, Z. & Henrich, J. The cultural evolution of epistemic practices: the case of divination. Hum. Nat. 32, 622–651 (2021).
Singh, M. Magic, explanations, and evil: the origins and design of witches and sorcerers. Curr. Anthropol. 62, 2–29 (2021).
Feld, S. Sound structure as social structure. Ethnomusicology 28, 383–409 (1984).
Miton, H., Wolf, T., Vesper, C., Knoblich, G. & Sperber, D. Motor constraints influence cultural evolution of rhythm. Proc. R. Soc. B Biol. Sci. 287, 20202001 (2020).
Demorest, S. M., Morrison, S. J., Nguyen, V. Q. & Bodnar, E. N. The influence of contextual cues on cultural bias in music memory. Music Percept. 33, 590–600 (2016).
Herff, S. A., Olsen, K. N. & Dean, R. T. Resilient memory for melodies: the number of intervening melodies does not influence novel melody recognition. Q. J. Exp. Psychol. 71, 1150–1171 (2018).
Herff, S. A., Olsen, K. N., Dean, R. T. & Prince, J. Memory for melodies in unfamiliar tuning systems: investigating effects of recency and number of intervening items. Q. J. Exp. Psychol. 71, 1367–1381 (2018).
Povel, D.-J. & Essens, P. Perception of temporal patterns. Music Percept. 2, 411–440 (1985).
Povel, D. J. Internal representation of simple temporal patterns. J. Exp. Psychol. Hum. Percept. Perform. 7, 3–18 (1981).
Collier, G. L. & Wright, C. E. Temporal rescaling of simple and complex ratios in rhythmic tapping. J. Exp. Psychol. Hum. Percept. Perform. 21, 602–627 (1995).
Polak, R. et al. Rhythmic prototypes across cultures: a comparative study of tapping synchronization. Music Percept. 36, 1–23 (2018).
Hannon, E. E. & Trainor, L. J. Music acquisition: effects of enculturation and formal training on development. Trends Cogn. Sci. 11, 466–472 (2007).
Jacoby, N. et al. Universality and cross-cultural variation in mental representations of music revealed by global comparison of rhythm priors. PsyArXiv https://doi.org/10.31234/osf.io/b879v (2021).
Le Bomin, S., Lecointre, G. & Heyer, E. The evolution of musical diversity: the key role of vertical transmission. PLoS One 11, e0151570 (2016).
Brown, S. et al. Correlations in the population structure of music, genes and language. Proc. R. Soc. B Biol. Sci. 281, 2072 (2013).
Pamjav, H., Juhász, Z., Zalán, A., Németh, E. & Damdin, B. A comparative phylogenetic study of genetics and folk music. Mol. Genet. Genomics 287, 337–349 (2012).
Youngblood, M., Baraghith, K. & Savage, P. E. Phylogenetic reconstruction of the cultural evolution of electronic music via dynamic community detection (1975–1999). Evol. Hum. Behav. 42, 573–582 (2021).
Asano, R., Boeckx, C. & Fujita, K. Moving beyond domain-specific vs. domain-general options in cognitive neuroscience. Cortex 154, 259–268 (2022).
Feld, S. Sound and Sentiment: Birds, Weeping, Poetics, and Song in Kaluli Expression (University of Pennsylvania Press, 1982).
Nettl, B. The Study of Ethnomusicology: Thirty-one Issues and Concepts (University of Illinois Press, 2005).
Savage, P. E. et al. Sequence alignment of folk song melodies reveals cross-cultural regularities of musical evolution. Curr. Biol. 32, e1–e8 (2022).
Henrich, J. The Weirdest People in the World: How the West Became Psychologically Peculiar and Particularly Prosperous (Farrar, Straus and Giroux, 2020).
Smaldino, P. E., Lukaszewski, A., von Rueden, C. & Gurven, M. Niche diversity can explain cross-cultural differences in personality structure. Nat. Hum. Behav. 3, 1276–1283 (2019).
Herff, S. A., Cecchetti, G., Taruffi, L. & Déguernel, K. Music influences vividness and content of imagined journeys in a directed visual imagery task. Sci. Rep. 11, 15990 (2021).
Strickland, J. C., Garcia-Romeu, A. & Johnson, M. W. Set and setting: a randomized study of different musical genres in supporting psychedelic therapy. ACS Pharmacol. Transl. Sci. 4, 472–478 (2021).
Aubinet, S. The problem of universals in cross-cultural studies: insights from Sámi animal melodies (yoik). Psychol. Music https://doi.org/10.1177/03057356211024346 (2021).
Fritz, T. H., Schmude, P., Jentschke, S., Friederici, A. D. & Koelsch, S. From understanding to appreciating music cross-culturally. PLoS One 8, e72500 (2013).
Sievers, B., Lee, C., Haslett, W. & Wheatley, T. A multi-sensory code for emotional arousal. Proc. R. Soc. B 286, 20190513 (2019).
Pinker, S. Sex and drugs and rock and roll. Behav. Brain Sci. 44, e109 (2021).
Mehr, S. A., Krasnow, M. M., Bryant, G. A. & Hagen, E. H. Toward a productive evolutionary understanding of music. Behav. Brain Sci. 44, e122 (2021).
Acknowledgements
The authors thank Alex Mackiel for assistance with the preparation of Fig. 3, and members of The Music Lab for feedback on the manuscript. M.S. acknowledges IAST funding from the French National Research Agency (ANR) under grant ANR-17-EURE-0010 (Investissements d’Avenir programme). S.A.M. acknowledges funding from the US NIH Director’s Early Independence Award DP5OD024566 and the Royal Society of New Zealand Te Apārangi Rutherford Discovery Fellowship RDF-UOA2103.
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We dedicate this article to Sandra Trehub (1938–2023), whose pioneering and inspiring work touched every corner of the psychology of music.
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Glossary
- Auditory scene analysis
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The auditory system process involved in gathering information about which sounding objects are present in the environment and determining where they are located.
- Harmonic structure
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The grouping of harmonies in a musical example, where harmonies are combinations of tones (such as chords) that are functionally related to one another; when listeners hear a melody, they automatically build representations of its potential harmonic structure.
- Integer ratios
-
In music, the organization of pitch or duration information in a melody or rhythm via a simple ratio of integers, such as a duration pattern of 2:1, where the first musical event is twice as long as the second.
- Isochronous beat
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Periodic rhythm in which beats have the same duration; most music is structured around the isochronous beat, and it is typically perceived as the basic rhythmic foundation of the music (for example, when one taps one’s foot to music, one typically taps to the isochronous beat).
- Major mode
-
In western classical and popular music, a collection of notes (which can be played at the same time, as in a chord, or not, as in a melody) the third note of which is four semitones from the tonal centre.
- Minor mode
-
In western classical and popular music, a collection of notes (which can be played at the same time, as in a chord, or not, as in a melody) the third note of which is three semitones from the tonal centre.
- Timbre
-
Perceived quality of a sound that makes notes produced by different sources, such as the human voice and a piano, sound different from each other, even when produced at the same pitch, duration and intensity.
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Singh, M., Mehr, S.A. Universality, domain-specificity and development of psychological responses to music. Nat Rev Psychol 2, 333–346 (2023). https://doi.org/10.1038/s44159-023-00182-z
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DOI: https://doi.org/10.1038/s44159-023-00182-z