Antecedents and outcomes of social media fatigue

2.1 Social media fatigue

SM fatigue is a complex concept, having no single definition, and scholars have defined it in various ways. For example, Lee et al. (2016) termed social media fatigue as “a subjective and self-evaluated feeling of tiredness from social media usage”. In turn, Bright et al. (2015) identified this phenomenon as “social media users' aptitude to slow down social media usage when they feel overwhelmed with too many pieces of content, too many friends and contacts, too many sites, and too much time consumed keeping up with these contacts”.

According to Ravindran et al. (2014), SMF is a subjective, multidimensional user experience encompassing negative feelings such as tiredness, annoyance, anger, disappointment, etc. These emerging negative emotions are correlated with many aspects of SM use and interactions. Huge amounts of information may lead to information overload and evoke stress, frustration, dissatisfaction and finally, fatigue (Zhang et al., 2016; Dai et al., 2020; Whelan et al., 2020). SM fatigue means that too much information and various stimuli from SM have led to feelings of being overwhelmed (Lee et al., 2016). Although users may feel overwhelmed with SM content, the intensity of their feelings and how they respond to such content may vary (Ravindran et al., 2013). This is due to the fact that such feelings and responses are subjective. Moreover, each experience of SM may have a different influence on both the length and intensity of fatigue and therefore may also result in different implications of fatigue.

SM fatigue is multidimensional as the sensations involve cognitive, emotional, psychological and behavioral aspects. When SM fatigue occurs it will be reflected in three dimensions (Ravindran et al., 2013):

1. cognitive level: thinking, remembering and reasoning may be impacted when users are overly engaged or overwhelmed by responses or external demands, which is reflected in, e.g. escalating errors and mistakes or academic performance decrement,

2. emotional and psychological perspective: negative health effects may emerge (e.g. depression, anxiety, burnout or frustration, etc.) and

3. behavioral aspects: different human behavioral responses may occur (e.g. discontinuance of usage or interaction engagement decrement on social media).

This study aims to explore the last dimension, associated with SMF outcomes. There are several antecedents which will also be examined in the context of SMF. All of these will be discussed below.

2.2 Privacy concerns and fatigue

Nowadays, the issue of privacy online has become especially important for many users (Zhang et al., 2020a, b). Privacy concern (PC) mainly relates to users' concerns regarding data leakage when using SM. However, e.g. on Facebook, a lot of data can leak out without users being aware of it. According to Winder (2019), the data of 419m Facebook users were leaked by unsecured databases in 2019. Furthermore, the “like” button allows information to be collected regarding the internet browsing habits of individuals. Facebook users, in order to find friends on the site, can link their email to their Facebook account, in this way enabling Facebook to collect the email addresses of both users and non-users (Hill, 2017). These examples show that some data can be passed on without the explicit consent of users. Privacy awareness causes a mental burden leading to fatigue (Bright et al., 2015; Fan et al., 2020). Moreover, privacy concerns can result in distrust of SM use. Consequently, they can lead to less use of SM.

There is no clear position regarding the influence of users' privacy concerns on SMF in existing studies. The studies of Bright et al. (2015) and Fan et al. (2020) revealed that privacy concerns positively influence SMF. Whereas the study of Malik et al. (2020) showed that privacy concerns do not increase fatigue among SM users. Therefore, the following hypothesis should be tested:

2.3 Fear of missing out and fatigue

Fear of Missing Out (FoMO) is an overwhelming fear that arises with the awareness that one does not participate online in very rewarding experiences lived by others (Przybylski et al., 2013). The anxiety resulting from the loss of social interactions and potential experiences is perceived as a result of being disconnected from the network (Alt, 2017). The appearance of anxiety induces and intensifies behaviors that are dangerous to health, such as the compulsion to use SM platforms and remain online regardless of the consequences (Tomczyk and Selmanagic– Lizde, 2018).

Previous studies show that users with high FoMO are more prone to compulsive use of SM (Wolniewicz et al., 2018), and the emerging intensity of use is the strongest predictor of SM fatigue (Malik et al., 2020). Moreover, frequent and excessive involvement in SM will cause SM fatigue (Karapanos et al., 2016). Therefore, based on prior extended literature, the second hypothesis is that:

2.4 Self-disclosure and fatigue

Self-disclosure (SD) shall be understood as the online sharing of one's own personal information and opinions. According to Dhir et al. (2019), it is the intentional or unintentional disclosure of personal information on SM platforms for various reasons. In prior studies, for example, a desire for self-expression and societal validation (Bazarova and Choi, 2014) or the willingness to belong to a virtual community, and a finding a companion on Facebook (Hollenbaugh and Ferris, 2014) were the crucial factors that drive online self-disclosure. Online information may be released with a clear intention of showing it to a wide audience or without (e.g. mistakes or lack of awareness of the consequences). Online self-disclosure is a common practice among users across all SM platforms. Information spreads rapidly and reaches everywhere. Self-disclosure can have positive or negative implications. In the latter case, emotionally negative words can seriously affect users' psychological well-being, result in lower self-esteem and reduce their social support (Valkenburg et al., 2006). Therefore, the next hypothesis is as follows:

2.5 Time cost and fatigue

Nowadays, 3.96bn people use SM, which reflects more than half (51%) of the global population. The average user spends 144 min on SM sites every day, and the total number of global SM users has increased by over 10% during the last year (Digital Marketing, 2021). Taking into account the average time spent per day on SM, Facebook tops the list, with an average of 58 min, and Facebook users upload 300m photos daily and watch approximately 100 million hours of video content (Djordjevic, 2020).

The presented statistics prove that the time spent on SM is constantly growing, which requires a lot of effort from users because their management of SM costs both time and money. According to Jabeen et al. (2023), time cost was defined as “the users’ perception of the energy they expect to expend in collating, processing and responding to SM communication and information”. The time cost construct is very rarely present in prior studies. However, the study by Zhang et al. (2020) proved it is a factor triggering SMF. In turn, Zhang et al. (2020b) point out that SM users perceive an increasingly higher loss of time, due to the frequent use of SM, and their sense of guilt is an important factor leading to SMF. Having this in mind, we define this construct as the loss of time cost personally perceived by SM users, arising from SM use. Users' efforts to screen, filter and process massive amounts of information and the resulting time cost consciously incurred through SM use should be considered as an important factor contributing to SM fatigue. Hence, the following hypothesis:

2.6 Discontinuance of usage and fatigue

Prior literature suggests that discontinuance of usage (DoU) is defined as a cessation of use. According to Recker (2014), it measures the intent to quit use overall in the future, and constitutes a rational decision. However, Ravindran et al. (2014) took into account three types of behavioral effects on SM: short breaks in activities, control activities and suspension of usage behavior. A similar approach was adopted by Fan et al. (2020). They also considered the same three dimensions of discontinuous usage intention.

SM fatigue may result from the intensity of social interactions among users of the community (Malik et al., 2020), overloaded content available on social networks (Zhang et al., 2016; Xie and Tsai, 2021) or changes to the interface in the SM platform which are unwanted or considered unnecessary (Ravindran et al., 2013). The intensity of the fatigue experience could range from a mild or transient experience to a more intense one, which may eventually end in the decision of the user to quit the platform.

Previous studies have found that if users experience high-intensity fatigue, they are more likely to cease using SM platforms (Maier et al., 2015a; Xie and Tsai, 2021). When users feel inconvenienced or annoyed, they tend to reduce their participation and limit their social network activities (i.e. for a certain period) to avoid SMF (Zhu and Bao, 2018). Thus, in our study, the DoU construct is defined as the permanent cessation or suspension of activity for a certain period.

According to Turel (2015), the discontinuation of usage of any technology is especially relevant in circumstances considered inconvenient and problematic by users, such as when they are stressed. In such a situation, users might intend to stop using the SM platform to avoid the stressful situation by keeping away from SM (Beaudry and Pinsonneault, 2005). And consequently, this decision of the user to quit the platform could be a danger of loss of users for SM providers. Based on the above, the next hypothesis states:

2.7 Interaction engagement decrement and fatigue

Interaction is fundamental on SM platforms and involves a wide range of user activities such as: sharing and exchanging ideas, thoughts and feelings about user experiences on various topics, giving likes, publishing photos, videos, etc. This kind of interaction, enabling a social connection in the digital world, is a behavioral element of people's engagement on SM. Strong user interaction engagement means high and continuous activity on the SM platform.

According to Beaudry and Pinsonneault (2005), the emerging stress from SM use can result in attempts to exit a difficult situation to minimize its negative consequences and restore personal emotional stability. We assume that in addition to ceasing SM use (DoU construct), users could reduce their engagement in using the SM platform to protect themselves from strain, i.e. SMF. In this way, we intend to extend the existing body of SMF research by identifying Interaction Engagement Decrement (IED) as an adaptation strategy to SMF.

Based on the literature analysis, it can be said that the Interaction Engagement Decrement construct has not appeared in earlier studies. For this reason, new measuring scales have also been created for it (see: Table 2).

In this study, the Interaction Engagement Decrement construct is defined as decreasing user activity on the SM platform over time, involving a wide spectrum of user activities, for example: exchanging ideas, thoughts and feelings in posts, giving likes, publishing photos, videos, etc. In contrast, strong user interaction engagement means tremendous and continuous activity in the digital community space.

It is assumed that SMF could result in decreasing the intensity of social interactions among users of the SM community. In view of this, the next hypothesis is as follows:

3.1 Research model

Prior SMF studies are based on various theoretical frameworks to understand SMF, including SSO – the stressor-strain-outcome model, SOR – the stimulus-organism-response paradigm, SCT – the social cognitive theory model, LCM – the limited capacity model, and TTSC – the transactional theory of stress and coping. The present study utilizes the stressor-strain-outcome (SSO) framework (see: Koeske and Koeske, 1993) to explain how some negative manifestations, i.e. stressors (such as privacy concerns, FoMO, self-disclosure and time cost), can lead to other negative symptoms, such as SMF, and finally evoke some negative outcomes. The SSO model was chosen in this study because it is suitable and assists in exploring the stressors leading to SMF and in establishing causal relationships because of links between stressors and outcomes. Based on the literature review, it can be said that the SSO framework has been an effective tool for examining stress-related problems and their consequences (see: Table 1). The application of the SSO model enables the penetration of explanations which are essential for understanding the antecedents and outcomes of SMF.

Through the literature review, the conceptual model presented in Figure 1 was developed.

The proposed research model shows the hypothesized relationships that are, to the best of our knowledge, understudied in the extant literature. The research model, based on the SSO framework, offers six hypotheses about the research topic. Within the SSO framework, stressors refer to environmental stimuli which are perceived and interpreted by an individual as problematic and disruptive. In the current study's conceptual model, the stressors are various stimuli represented by SM usage behavior, namely, online privacy concerns, FoMO, self-disclosure and time cost. These four constructs for the stressor were selected based on relatively recent research on SMF. Their selection was motivated by the subjective experience and knowledge of the researcher. Strain refers to the psychological outcomes of stress for individuals and, in the research model, is evidenced by SM fatigue. The strain is a mediator between stressors and outcomes. Finally, DoU and IED on SM are the outcomes of strain, which comes down to a behavioral response to a stressful situation. Discussed above constructs were chosen for the study after a thorough analysis of the literature. For example, the first one (DoU) has appeared in a few studies, i.e. Zhang et al. (2016) for the Qzone platform or Xie and Tsai, 2021 for the Weibo platform – but we want to test it for Facebook. In contrast, another construct (IED) does not exist in the literature. Since it is believed that SMF could result in the dropping intensity of social interactions among SM users, it was decided to create and include this variable in the study.

The procedure to develop and verify the design for the newly proposed concept of Interaction engagement decrement (IED) is described in Sub-section 3.1.1. Whereas measures of all constructs for the study were presented in Sub-section 3.1.2. They create a base for the main survey to gather empirical evidence for the proposed research model.

3.2 Sample and data collection

An online questionnaire provided in English was used to gather empirical data from SM users. The online survey was created using the Google Forms service, and the data were collected in January/February 2021.

The environment chosen for the study consisted of a Facebook community. Facebook was chosen mainly due to its popularity, the volume of users and very broad reach. Facebook has a worldwide total of 2.74 billion active users every month (Facebook Investor Relations, 2020). According to the latest available statistics, in January 2021, 69.63% of the social network market share was owned by Facebook (GlobalStats, 2021). For many years, it has been the undisputed leader among SM platforms and this platform provides both an attractive and unique venue to study: (1) various business issues, e.g. through sentiment analysis from users' posts (Baj-Rogowska, 2017; Baj-Rogowska, 2020a), and (2) many social phenomena, i.e. SM fatigue (Bright et al., 2015; Cramer et al., 2016; Adhikari and Panda, 2019; Dhir et al., 2018, 2019).

Data were collected using a random sampling strategy, to allow the representativeness of the sample. The only criterion for taking part in the survey was the use of Facebook (including Messenger). This study applied a snowball sampling strategy to convey the questionnaire to the target audience. To begin with, the web link of the questionnaire was sent to the author's friends on Facebook, as well as being provided to teachers and students at a few universities in Poland. All of them were asked to invite their friends who were Facebook users to participate in the survey, and so on. During the procedure, no one was offered any incentive to take part in this study. Participation in the survey was confidential and anonymous.

At first, a pilot study was conducted, in which 12 students were invited to participate in the study. The survey was pre-tested on this small group to verify the credibility of the questionnaire regarding the clarity of the questions and whether this tool gathered the necessary information without omitting any essential aspects.

Ineligible responses (including any with omissions and those with identical answers for all questions) were discarded. 444 valid questionnaires were finally obtained.

The survey included six headline questions to describe the respondent profile (gender, age, education, occupation, length of use and average time spent on Facebook) and seven latent variables (each of which was in a separate section of the questionnaire). A demographic analysis of the sample is presented in Table 3.

There were 274 (61.7%) female and 170 (38.3%) male respondents. The most numerous group were respondents aged 18–25 (72.5%) and the smallest were those aged over 55 (3.2%). The largest group of the sample were students (68.9%).

SM was originally associated with just the younger generations, but now, all generations tend to use SM in their daily routines. Almost one-third of respondents (29.1%) spend on average between 30 min and 1 h on Facebook each day. Only a small group of respondents (6.3%) spend an average of over 3 h daily on Facebook.

3.3 Method of data analysis

The gathered data were empirically used to verify the proposed conceptual research model. Hypothesized relationships were assessed using the structural equation modeling (SEM) technique. This technique allows the statistical presentation of the causal structure of phenomena, where: (1) several variables can be analyzed concurrently, and (2) the analyzed variables can be latent, meaning that they are not directly measured (Baj-Rogowska, 2020b).

The basic stages, which are usually taken to perform SEM modeling are shown in Figure 2.

The SEM procedure is based on the indicator variables and conceptual hypothesized model of SM fatigue (Figure 1). We follow the stages (presented in Figure 2) which are described below:

• Stage 1: Exploratory Factor Analysis (EFA) is usually performed as a preliminary stage needed for analyzing the latent constructs and providing a preliminary insight into the relationships between the measured variables and the corresponding latent factors.

• Stage 2: Confirmatory Factor Analysis (CFA) is performed for the confirmation of the factor structures based on the EFA and in compliance with some theoretical knowledge. In other words, during CFA, the conceptual model is firstly defined due to some theory, and then the CFA statistics investigates how well the theoretical specification of the factors reflects the real data. The outcome of CFA is connected to the measurement part of the SEM model, which gives the loadings of the indicator variables on corresponding latent factors.

• Stage 3: In the SEM stage, the measurement part and structural part of the SEM model are derived, which able us to all the estimated interrelations between the examined variables. The important benefit of SEM modeling is also the ability to test and evaluate the models which contain a set of theoretical hypotheses.

• Stage 4: The quality of model fit to the real data is tested using the calculation of model fit indices. In case they indicate the poor model's fit values, some additional modifications to the model should be done. The type of indices and the most important fit indices and their acceptable threshold values are discussed in detail in (Dragan and Topolšek, 2014).

The SEM procedure provides the most efficient technique for a series of separate multiple regression equations estimated simultaneously. It is based on two basic components: (1) the structural model (is the path model) which relates to the dependencies between latent variables, and (2) the measurement model which describes the value of observable variables (indicators).

The statistical methods used to empirically verify the validity and reliability include variance analysis and — first and foremost — Exploratory Factor Analysis (EFA) and Confirmatory Factor Analysis (CFA). CFA begins with a theoretical model; otherwise, the approach is regarded as exploratory. These two approaches, in practice, complement each other. EFA is based on an initial model, similar to the process in CFA, and if the model assumptions are not supported by empirical verification, they are normally modified to gain a better fit. The value of many indicators (χ², statistics, TLI, Standardized RMR, RMSEA, etc.) should be measured to obtain the model assessment. Only by adopting such an approach can a decision be taken as to whether the model fits well enough or is insufficient.

The internal reliability of a scale is usually verified by computing Cronbach's alpha coefficient. According to Hair et al. (2010), the agreed minimum lower level for Cronbach's alpha coefficient is the value 0.70. Confirmatory factor analysis confirms (or rejects) the previously proposed hypotheses which specify dependencies between individual constructs and sets of items. Furthermore, it is also used to determine the suitability of measurement scales, regarding their validity and reliability. The approach for determining the validity of the model involves proving that the proposed model fits the data, and the statistical significance of factor loadings (statistical value |t| > 1.96).

Fornell and Larcker (1981) put forward the simplified approach of average variance extracted (AVE) to confirm the validity, which is computed based on the value of the estimated parameters of the model. AVE uses a value from the interval [0; 1]. If AVE >0.5, meaning that over 50% of the item's variability is explained by the variability of the latent construct, then validity is assumed to be confirmed.

There is a lot of software for structural equation modeling. We apply SPSS and Amos - its Add-on, which enables the design of the SEM model in a completely graphical framework.

4.1 Confirmatory factor analysis (CFA)

The CFA model, within the SEM framework, represents what has been referred to as a measurement model. CFA tested if the presumed model was confirmed by the empirical data. The obtained data were examined for reliability and validity by employing the confirmatory factor analysis. Convergent validity was confirmed in three ways: (1) all item loadings toward respective measures were higher than 0.50 (Anderson and Gerbing, 1988), (2) the composite reliability (CR) value of all constructs exceeded 0.70 (Clark and Watson, 1995; Fornell and Larcker, 1981) and (3) the value of the average variance extracted (AVE) exceeded 0.50 (Fornell and Larcker, 1981). The discriminant validity was confirmed by the fact that the square roots of all the AVE scores are significantly greater than any of the other correlation coefficients among all considered constructs in this study (Fornell and Larcker, 1981). The summary of the results is shown in Table 4. As suggested by Hair et al. (2010), the model fit indices were also in consonance with the recommended values (χ²/df = 2.27, CFI = 0.93, TLI = 0.91, RMSEA = 0.054).

We also conducted the heterotrait-monotrait ratio of correlations (HTMT) analysis (Henseler et al., 2015) to confirm the validity and reliability of the adopted scales in the current study (Table 5). HTMT is a measure of similarity between latent variables. If the HTMT value is visibly smaller than one, discriminant validity can be regarded as established.

The data were normally distributed because the absolute value of kurtosis and skewness for measurement items was under the threshold limit of 8 and 3, respectively. Moreover, a chi-square Q-Q plot was created to examine the dataset. It revealed the points in the Q-Q plot are approximately on the line which once again confirmed that the data are normally distributed. Due to this, is possible to conduct the SEM procedure.

4.2 Structural equation modeling (SEM)

The AMOS software was used to compute the path structure of the conceptual model. Since the data were normally distributed, we applied the estimation method - the normal theory maximum likelihood (ML), which requires the correct model and normal data as assumptions. Thus, the research model was verified by the usage of a maximum-likelihood estimation (MLE) based on the multivariate normality of observable variables. The applied approach took all paths into account at the same time, which is a strength of structural equation modeling. The t-student statistics were obtained, which allowed support for each hypothesis formulated in this study. The fit indices of the structural model of χ²/df = 2.7, CFI = 0.93, TLI = 0.91, RMSEA = 0.06 were in line with the recommended values (Hair et al., 2010). Standardized RMR = 0.0732 is a good fit as it should be <0.08. The Beta index shows the values of parameters among the constructs which represent regression coefficients. The results are presented in Table 6.

The obtained results show that privacy concerns (β = 0.27, p < 0.001) and time cost (β = 0.38, p < 0.001) positively influenced SMF. Additionally, SMF was positively correlated with DoU (β = 0.41, p < 0.001) and IED (β = 0.16, p < 0.01). The final path model of the study is presented in Figure 3. Most hypotheses, except for H2 (FoMO → SMF) and H3 (SD → SMF), were corroborated by the study results.

As presented in Table 5, and finally in Figure 2, not all assumed relationships between the constructs in this study are statistically significant (p ≤ 0.05). Thus, hypotheses H2 and H3 were rejected.

6.1 Theoretical implications

From a theoretical perspective, first of all, the proposed SSO framework is empirically verified and extended in this paper. The findings demonstrate that privacy concerns and time costs regarding aspects of SM can cause fatigue, which, in turn, indirectly influences users' intentions to withdraw from SM use in two dimensions. Users are willing to discontinue SM usage (β = 0.41) more often than to decrease the level of their interaction engagement (β = 0.16) on SM. However, this research proved that both of these consequences are the result of SM fatigue.

Secondly, this study introduced the concept of IED as a consequence of SM fatigue. In prior literature, the existence of this construct has been not found. The important theoretical contribution is the creation of measurement scales for the construct IED and testing them in this study with good results. To confirm the validity of these items, a confirmatory analysis was employed, which confirmed their usefulness. Consequently, this study extended the prior existing knowledge on the possible antecedents and outcomes of SMF.

Thirdly, our study proved that the relationship between certain chosen drivers and SMF is not consistent across scientific research. The examined stressors of the SSO model across empirical research on Polish users of Facebook showed that some findings are different from the conclusions of prior studies. Possible explanations for such differences might result from differences in (1) the tested SM platforms, and (2) the national cultures between Poland and other countries. Certainly, it should be examined in future research.

Fourthly, our research model may serve as a baseline for other interested scholars who intend to examine related variables and further explore the consequences arising from SMF in different cultural settings. Scholars could use the present study findings as a source to compare and develop their further research on SM fatigue. Our results contribute to the emerging body of research that examines factors connected with the SMF phenomenon.

6.2 Practical implications

In turn, the practical contribution of this study is that an understanding of the antecedents and outcomes of users' SM fatigue can help: (1) individuals to be aware of risks and adjust their activities in balance with their well-being, (2) SM managers to develop unique strategies to address the specific needs of SM users and (3) social scientists and educators.

From the user's perspective, an understanding of the stressors causing SMF could help them to (1) more consciously manage their time spent on SM, (2) raise awareness of the potential risks, and thus (3) avoid or reduce problems connected with SMF. An important initiative from users should be suggesting and reporting identified privacy gaps to SM providers. Moreover, knowing the factors that cause SMF (especially privacy-related), users should initiate SM discussions aimed at formulating rules for the ethical and safe use of SM platforms. Such an informal set of rules could limit the emergence of many negative incidents (e.g. spreading of fake news concerning selected users, cyberstalking and/or trolling) which strongly can be privacy-invasive for SM users. Eliminating at least part of such activities would reduce the generation of many unnecessary negative emotions contributed to SMF, and would ultimately mitigate the consequences of SMF and ensure the greater well-being of all users.

From the SM providers' point of view, they can redesign and develop their existing platforms by creating simple interfaces which allow users quick and clear access to information about how they are handling sensitive user data to mitigate user concerns related to online privacy. It is an important issue because high privacy concerns are strong antecedents of SMF. The present study revealed that respondents with high SM fatigue will be willing to decrease the level of their interaction engagement or discontinue the usage of SM. How strong SM fatigue was generated during SM usage, influences the users' behavior, and consequently, it reflects their approach to the services of providers. Due to this, thoughtful changes made by providers can not only keep users from leaving but can actually generate more interest in the platform.

In turn, from the last group's perspective (i.e. social scientists and educators), knowledge of the stressors causing SMF could help create educational and awareness campaigns to (1) raise the users' perception of potential privacy vulnerabilities (2) build conscious management of time spent on SM and (3) educate users, particularly the elderly who are more prone to privacy violations.

7.1 Study limitations and future work

Although this study states the above conclusions, and provides theoretical and practical contributions, its immanent limitations and opportunities for future research must be mentioned. Firstly, this study focuses on a discussion of the interactions between the stressors, strains and outcomes of users without full consideration of the impact of additional socio-demographic factors on SMF, i.e. gender, age, social environment or educational background. A more detailed and extended approach would make it possible to improve the perspective of the generalizability of the findings. Since prior studies have shown that SM usage may differ across age groups (Throuvala et al., 2019; Reer et al., 2019; Tandon et al., 2021), we encourage scholars to examine the moderating influence of socio-demographic factors, especially gender and age, for the explored relationships.

Secondly, the current study only focuses on one, yet very popular, SM platform, i.e. Facebook. For that reason, the findings might be constrained and not applicable to other SM platforms. In view of the variety of widely used SM platforms, such as Instagram, Twitter, You Tube, etc. the potential antecedents and outcomes of SMF may vary according to the features of each SM platform. Thus, to test this and increase the generalizability of the findings, future studies may collect data for other SM platforms, such as Twitter, Snapchat, Instagram, BeeReal and WhatsApp. Hence, we encourage scholars to verify the results of this study through other SM platforms.

Thirdly, it should be recognized that a certain limitation of our methodological approach is that it is a snowball sampling-driven study with a predominant student sample. Since this technique does not select units for inclusion in the sample based on random selection (unlike probability sampling), it is impossible to determine the possible sampling error and make generalizations from the sample to the population (Sharma, 2017). However, there was no other way of accessing the sample, thus making snowball sampling the only viable choice of sampling strategy. Leighton et al. (2021) demonstrated that data collection using snowball sampling via SM is an effective and efficient method to recruit study participants. They claim that this technique of sampling made possible an increased sample size and decreased time to completion. Moreover, the demographic limitation of the sample selected for this study could influence the results. Approximately 70% of the respondents selected were students. Using a more diverse sample might also produce distinct results.

In future research, firstly, we plan to replicate this model by analyzing users of different SM platforms (e.g. Twitter, Instagram, etc.) separately to check the repeatability of the findings. Secondly, extensions of this work in the future should consider other antecedents that evoke SM fatigue (e.g. the intensity of SM usage, technology accessibility, network size and social, information or communication overload) and a more extensive set of responses to this phenomenon. Thirdly, it would be worth organizing an international study that aims to compare the results through the context of cultural SM use. Finally, in future studies, we would like to examine age and gender moderate the linkage between chosen antecedents and SMF.