Social jetlag and sleep habits in children and adolescents: Associations with autonomy (bedtime setting and electronics curfew) and electronic media use before sleep

Social jetlag is used to describe the misalignment of social and biological time, demonstrated by a discrepancy in sleep timing and activity on “work” and “free” days (Wittmann et al. 2006). Sleep on free days is thought to better reflect an individual’s natural sleep timing, while sleep during the working week is constrained, reflecting external or social time (Vetter 2020). Social schedules may impact on an individual’s daily behaviour, so that they are active and asleep outside their circadian window (i.e. window of biological sleep timing provided by the circadian clock). For children and adolescents attending school, social jetlag is defined as the discrepancy in sleep/wake timing between school days and weekends. High social jetlag is demonstrated by a pattern that shows much variability between school day and weekend sleep. In adolescence, social jetlag has been found to be associated with irritable mood (Tamura et al. 2022), anxious symptoms (Mathew et al. 2019), decreased academic and cognitive performance (Díaz-Morales and Escribano 2015; Smarr and Schirmer 2018; Tamura et al. 2022), somatic complaints and attention problems (Zhu et al. 2023), and excessive alcohol consumption (Haynie et al. 2018). In addition, social jetlag has been identified as a risk factor for metabolic disorders and obesity (Roenneberg et al. 2012, 2019). These findings suggest it may be important to examine social jetlag, or irregular sleep timing – over and above other aspects of sleep, such as late bedtimes and short sleep duration – when considering possible challenges to a healthy lifestyle.

Social jetlag increases from childhood to adolescence, and is most acute during mid adolescence before declining (Randler et al. 2019; Roenneberg et al. 2012, 2019), corresponding with what is termed the biological “phase delay” that pushes bedtimes and waketimes later in puberty (Crowley et al. 2018). Individuals vary in how their circadian system synchronizes with zeitgebers (environmental time givers); for example, the 24-hour light-dark cycle. When viewed as a biological construct, these differences in “phase of entrainment” are known as chronotype (Ghotbi et al. 2020; Roenneberg et al. 2019). Adolescents tend to be later chronotypes than other age groups (Roenneberg et al. 2004) and may have school schedules that contradict their chronotype, with sleep timing constrained in part by early morning schedules (Carvalho-Mendes et al. 2020; Ziporyn et al. 2022). Accordingly, young people may struggle to sleep early enough on a school night and also struggle to wake up when required for the start of the school day. In contrast, with fewer demands of the social clock, individuals are more likely to sleep to their own timing on weekends, if no additional extra-curricular or work constraints are placed on them. Young people may “compensate” for insufficient sleep during the school week, with an extended sleep duration and later wake times at the weekends (Gradisar et al. 2011; Touitou 2013). Findings regarding gender differences in social jetlag are equivocal. No significant gender differences in social jetlag have been found in a cross-sectional sample from infancy to 25 y (Randler et al. 2019), but social jetlag has been found to be greater in school-aged boys than girls in some studies (Chandrakar 2017; Díaz-Morales and Escribano 2015) as well as in school-aged girls than boys in other studies (Shinto et al. 2022).

Given that the timing of sleep matters, it is important to consider whether changes to evening routines could reduce social jetlag. Parents and caregivers may be influential in adolescents’ sleep patterns, through setting bedtimes (Carskadon 2011) and supporting regular bedtimes and waketimes. One of the defining features of adolescence is the desire for, and acquisition of, greater autonomy (Blakemore 2019; Zimmer‐Gembeck and Collins 2006). This striving for behavioural autonomy may conflict with parental/household rules and have implications for sleep timing. As children move into adolescence, the proportion of parents setting bedtimes reduces (Carskadon 2011; Tashjian et al. 2019). A study in Australia found that 17.5% of adolescents, aged 13–18 y, reported a parent-set bedtime to be the main determinant of when they went to bed on a school night (Short et al. 2011).

Research around the influence of bedtime setting has largely focused on connections between who sets young people’s bedtimes, and their reported bedtimes, sleep duration and sleep quality (Adam et al. 2007; Bartel et al. 2015; Buxton et al. 2015; Gangwisch et al. 2010; Khor et al. 2021; Peltz et al. 2020; Pyper et al. 2017; Short et al. 2011, 2019; Tashjian et al. 2019). Parent-set bedtimes have been reported as a protective factor and found to relate to longer sleep duration (Bartel et al. 2015; Khor et al. 2021; Peltz et al. 2020). Parental rules around bedtimes have been found to relate to adolescents having earlier bedtimes and greater total sleep on school nights (Adam et al. 2007; Short et al. 2011, 2019; Tashjian et al. 2019) and at the weekend (Short et al. 2019; Tashjian et al. 2019) compared to when adolescents set their own bedtimes.

Most studies investigating parental rule setting for electronic devices and sleep have focused on the timing and duration of sleep rather than its effects in relation to social jetlag. A systematic review and meta-analysis concluded that earlier bedtimes and longer sleep duration were more likely when parental rules were present for electronic device use (Khor et al. 2021). However, enforcement of rules related to electronic media use before bedtime did not predict longer sleep duration in a sample of 14–17-year-olds in the US (Peltz et al. 2020). Not only frequency of use but timing may be influential for sleep; in other words, it is more likely to have a negative impact if screen use behaviour is before sleep rather than during the daytime. Nighttime social media use has been shown to be associated with later bedtimes and shorter sleep duration in a small sample of 12–18-year-olds in the UK (Scott and Woods 2018). The more frequently adolescents (mean age: 16.9 y) played video games during the week in the hour before going to bed with the intention to sleep, the later were their school day and weekend bedtimes (Pieters et al. 2014). A Swedish study investigated electronic media use and social jetlag with adolescents, and found that the frequency of nighttime texting was associated with social jetlag in 13–15-year-olds (Hena and Garmy 2020).

Discussions around bedtime and when to stop using electronic media at night are likely to be taking place in many households. Exploring the determinants of sleep timing could help establish promising areas for intervention. However, there is a dearth of research examining associations between social jetlag and rules around bedtime setting, rules around electronic media use, as well as the frequency of electronic media use before sleep. To our knowledge, it is yet to be investigated whether young people setting their own bedtime on school nights and/or at the weekend and having more control over their electronic media use is associated with social jetlag. This information could help inform family decisions regarding bedtime setting and electronic media use before sleep, with the potential to offer modifiable actions to lower social jetlag in young people. The aim of this study was to (1) establish the amount of social jetlag experienced by school-aged children and adolescents in a UK sample and whether this is associated with age and binary gender; (2) identify whether rules concerning bedtime and electronic media use are associated with social jetlag; and (3) explore whether the frequency of social media use and/or video gaming before sleep intention are associated with social jetlag in school-aged children and adolescents. We expected to find that social jetlag was positively associated with age, while no predictions were made regarding gender. Based on previous findings regarding sleep timing and sleep behaviours, specifically bedtimes and sleep duration, we predicted that rules around bedtime setting as well as household rules around electronic media use, would be associated with lower levels of social jetlag. Furthermore, we hypothesised that high frequency of social media use and video gaming before sleep would both be related to higher levels of social jetlag.

This study provides novel evidence on the amount of social jetlag experienced by school-aged children and adolescents in a large community sample in England, as well as insights into relations between social jetlag and rule-setting around bedtime and electronic media use as well as frequency of electronic media use before sleep. Social jetlag was common in young people aged 9–18 y, with an average social jetlag of 1.88 h (1 hr, 53 min). As expected, we found that social jetlag was positively associated with age. Based on visual exploration of social jetlag by age, social jetlag appears to have increased from childhood – specifically those in later primary school years – to peak at age 15, with an approximate mean difference in social jetlag of 35 min between these years. After this peak, social jetlag appears to decrease in the older age groups (16–18 y). This supports findings presented by Randler and colleagues suggesting that the ages of 16–17 y represent a “breakpoint” where sleep behaviour changes back towards less jetlagged behaviour (Randler et al. 2019). Social jetlag was associated with gender, so that being female, compared with being male, was associated with higher social jetlag. While females were found to have significantly greater social jetlag than males, our findings indicated only a small mean difference of 9 min between girls (1.95 h: 1 hr, 57 min) and boys (1.80 h: 1 hr, 48 min), suggesting that this difference may not be practically meaningful. The association found between social jetlag and gender with school-aged students is consistent with phase delay (when circadian timing shifts later) being puberty-related, and with evidence that girls begin to delay sleep timing one year earlier than boys and show maximum eveningness at a younger age (girls: 15–19.5 y; boys: 18–21 y) (Hagenauer and Lee 2013; Roenneberg et al. 2004). Therefore, girls in this sample may have been more likely to delay bedtimes at the weekend and to have done so at an earlier age, contributing to higher social jetlag. Furthermore, gender role expectations – for example, morning grooming routines or more household chores – may increase the likelihood that girls wake earlier than boys on weekdays (Fredriksen et al. 2004).

Regarding autonomy, we found that the presence of rules around bedtime setting at the weekend were associated with lower levels of social jetlag as predicted. In fact, whether a rule was in place at the weekend emerged as the strongest predictor of social jetlag. In the final model, when all other predictors were held constant, social jetlag increased by 0.52 h (31.2 min) if an individual set their own bedtime compared to someone whose bedtime was set by another. Given the absence of an early school start the next day, it is perhaps unsurprising that 72.7% of young people set their own bedtime at the weekend compared with 47.2% on a school night. Young people may stay up later and wake up later when the opportunity arises at the weekend, partly demonstrating delayed sleep-wake timing that reflects changes to the biological regulation of sleep during adolescence (Crowley et al. 2018; Gradisar et al. 2011). Reduced societal demands at the weekend, specifically relating to days when students are not required to get up in time for school, increase this likelihood, although some students might continue to have fixed early morning commitments on weekends, such as sporting activities, possibly explaining the handful who had negative social jetlag. Many students may be able to sleep at the weekend for a more desired amount of time rather than having their sleep restricted by the start of the school day. Our finding is in line with that of a study in Finland, where adolescents whose main reason for going to bed on weekends was parent-set bedtimes, went to bed earlier and had an earlier midpoint of sleep than other groups (Short et al. 2019). Insufficient sleep during the school week may mean that sleep duration is longer at the weekend and lie-ins commonplace (Owens et al. 2014), which could in turn contribute to greater social jetlag. However, it should be noted that social jetlag and associated outcomes are a consequence of constraints imposed by social clocks on work days – which we might extrapolate to school days for students – rather than sleeping in on free days in an attempt to catch-up on sleep (Roenneberg et al. 2019). This study did not include an item on whether any rules were in place regarding rise times at the weekend, or whether alarms were being used to wake up, but their absence may also potentially contribute to the amount of social jetlag reported. Our findings provide initial support for the beneficial role of parents/carers or other family members in setting bedtimes at the weekend to help reduce sleep irregularity and limit social jetlag. Although, it could be that monitoring weekend bedtimes might be challenging if, for example, those setting the time might go to bed earlier than the adolescent.

Contrary to our predictions, findings regarding school nights were in the opposite direction, and setting your own bedtime on a school night was associated with lower social jetlag than when bedtime was set by another. Considering the final model, social jetlag decreased by 0.09 h (5.4 min) if an individual set their own bedtime on a school night compared to someone whose bedtime was set by another on a school night. Although we acknowledge that the small association found in our study means it seems unlikely that whether you set your own bedtime or not on a school night would actually be impactful in everyday life, given the amount of social jetlag experienced, this warrants further discussion as it contrasts with findings over weekend bedtime setting. As a potential explanation, when a young person has to get up in time for school but does not have a parent-set bedtime on a school night – previously found to relate to later bedtimes (Short et al. 2011) – then a later bedtime might contribute to a later midpoint of sleep. Any discrepancy between midsleep on a school night and midsleep at the weekend could thereby be reduced, lessening social jetlag. Another possible explanation may be that those who naturally go to bed later at the weekend, could also be those who have bedtimes set by others on a school night to try to limit late bedtimes.

Students were asked whether they had a household rule or set time about when they were supposed to turn off or put away computers, phones or other electronics on school nights. Although we hypothesised that rules around electronic media use would be associated with lower levels of social jetlag, in the final model, a curfew regarding electronic media use did not significantly predict social jetlag. When considering possible explanations, it is plausible that even if a rule were present, this may not have been sufficiently early to impact on the young person’s sleep onset time or that they habitually adhered to this curfew. We did not ask about rules over electronic media at the weekend and it may be informative in future work to investigate whether their presence is associated with social jetlag, especially given our finding regarding bedtime setting at the weekend. It is unclear what the impact of limits on electronic device use might be at the weekend as this was not asked specifically. If young people are not set limits over device use at the weekend, it could be proposed that sleep onset and offset may be even later with a corresponding later midpoint of sleep and increased social jetlag.

Both frequency of social media use and frequency of video gaming before sleep intention were associated with social jetlag, and emerged as the most important predictors after rules on weekend bedtime setting. As predicted, high frequency of social media use and high frequency of video gaming in the hour before students intended to go to sleep were related to higher levels of social jetlag. This is in line with findings from an adult sample, where frequent (more than a few times a week) internet use in the hour before bed was associated with social jetlag in Australia (Lang et al. 2018). The measures included in our study focused on what happened in the hour before sleep rather than before bedtime. Young people might continue to use electronic media after they have gone to bed, and so asking about behaviour before sleep intention could be a more nuanced approach to sleep measurement than asking only about behaviour before going to bed, which may well be how “bedtime” is interpreted. For example, they could be going to bed to catch-up with friends and not be intending to sleep for a while. Although observational studies have demonstrated a robust inverse relationship between electronic media use and sleep outcomes, evidence on the proposed mechanisms underlying these associations is less clear (Hale et al. 2019). It is not known why those young people in our study who were using social media or gaming before sleep on a regular basis have greater social jetlag. It could be that they are individuals with later chronotypes, or perhaps the use of electronic media may support the “sleep displacement hypothesis” (Bauducco et al. 2024), whereby the time spent using technology replaces time that might have been spent sleeping with a delayed sleep onset at the weekend.

Social jetlag peaks at the age of 15, with a difference of approximately two hours between school days and weekends. Weekend bedtime setting, and frequency of social media use and video gaming before sleep, were most strongly associated with social jetlag. Encouragingly, for children and adolescents experiencing social jetlag, our findings suggest that family decisions on weekend bedtime setting as well as the young person’s electronic media use before sleep have the potential to contribute to reduced social jetlag and more regular school night/weekend sleep timing, with consequent benefits to young people.

The authors would like to thank all the students who took the time to participate in the OxWell Student Survey and the many staff members at all the participating schools. The authors thank many colleagues in local authorities and CCGs, including Donna Husband, Lajla Johansson, Giovanni Ferri, Chris Price, Jonathan Jones, and Janette Fulwood, for all their time and support in promoting the survey. The authors would also like to thank Pauline Foster and Elaine Purse at Foster and Brown Research Limited, which provides the infrastructure for the OxWell survey. The authors thank the members of the OxWell study team (in alphabetical order): Dr Holly Bear, University of Oxford; Dr Rohan Borschmann, The University of Melbourne; Dr Blossom Fernandes, London School of Hygiene and Tropical Medicine; Dr Galit Geulayov, University of Oxford; Dr Karen Mansfield, University of Oxford; Rasanat Fatima Nawaz, University of Cambridge; Dr Danielle Newby, University of Oxford; Dr Emma Soneson, University of Oxford; Dr Stephen Puntis, University of Oxford; and Dr Simon R White, University of Cambridge.

This research was funded by the National Institute for Health and Care Research Applied Research Collaboration Oxford and Thames Valley at Oxford Health NHS Foundation Trust (MF) and the Westminster Foundation, with support from Frimley Clinical Commissioning Group (CCG), Berkshire West CCG, Buckinghamshire Council, and Milton Keynes Council. The investigators acknowledge the philanthropic support of the donors to the University of Oxford’s COVID-19 Research Response Fund. GI and MF were supported by the NIHR Oxford Health Biomedical Research Centre. FW is supported by a Wellcome Trust Doctoral Fellowship [award number 102176/B/13/Z]. The funders played no role in the writing of the manuscript or the decision to submit it for publication. The views expressed in this publication are those of the authors and not necessarily those of the National Institute for Health and Care Research or the Department of Health and Social Care.

No potential conflict of interest was reported by the authors.

Fully deidentified extracts of the data can be provided to academic research collaborators upon reasonable request after a review process by the research team to ensure that uses of the data fall under the remit of the intended purposes set out in the privacy information and to prevent duplication of analyses. The data are not publicly available because of ethical and information governance restrictions. The full list of questions as well as other details are available on a project-specific OxWell Open Science Framework website along with the study protocol (https://osf.io/sekhr/↗). Full data dictionaries can be made available upon approval for access to data extracts.

Supplemental data for this article can be accessed online at https://doi.org/10.1080/07420528.2024.2444675↗