Abstract
Purpose
In today’s rapidly evolving work landscape, the design of office spaces is a crucial concern for organizations. Companies are redefining offices as collaboration hubs to entice employees back to in-person work. However, the understanding of how employees choose their workspaces, especially for collaborative activities, and how this should inform office design is lacking. Workers’ collaborative activity patterns can help better understand workspace choice behavior (WCB). In two studies, this paper aims to explore which characteristics of collaborative activities to consider when reshaping offices.
Design/methodology/approach
Data collected in a cross-sectional study design at a research institution (n = 285) and a university (n = 352) were used for confirmatory factor analyses and regression analysis.
Findings
The first study shows that collaborative activities can be classified into three distinct types: coordinative activities (planned and formal), deep collaboration (planned and complex) and spontaneous communication (informal and short encounters). The second study revalidates this classification and reveals patterns impacting WCB. Frequency and location preference of spontaneous communication and work environment satisfaction are strong predictors of on-site work. Personal characteristics like gender, age, managerial position or commute time are less consequential than assumed.
Practical implications
The results pinpoint guidelines for office designers and leaders in shaping effective workspaces and policies.
Originality/value
This paper provides new insights into classifying collaborative activities and personal characteristics, activity characteristics and environmental factors influencing WCB.
Keywords
Citation
Mateescu, M., Schulze, H. and Kauffeld, S. (2024), "Choosing where to work: an empirical study of collaborative activities’ impact on workspace choice behavior", Journal of Corporate Real Estate, Vol. ahead-of-print No. ahead-of-print. https://doi.org/10.1108/JCRE-05-2024-0017
Publisher
:Emerald Publishing Limited
Copyright © 2024, Magdalena Mateescu, Hartmut Schulze and Simone Kauffeld.
License
Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode
Introduction
In today's work environment, fostering productivity and creativity through well-designed office spaces is crucial, particularly for knowledge workers reliant on collaboration. Creating office spaces that accommodate employees’ needs is a critical concern for organizations (Hoendervanger et al., 2022; Wohlers and Hertel, 2018). Amid this, the post-pandemic normalization of remote work led companies to redefine offices as collaboration spaces to attract their employees back to the office (Appel-Meulenbroek et al., 2022; Ma and Cha, 2021; Gensler, 2020). Nevertheless, we lack a deep understanding of how employees choose their workspaces when collaborating. While previous studies have explored workspace choice behavior (WCB) (Appel-Meulenbroek et al., 2022; Tagliaro et al., 2022; Ma and Cha, 2021; Haynes, 2007b; Heerwagen et al., 2004), they primarily focused on individual characteristics like gender, role and commute time. So far, workers’ activity patterns have received limited consideration. The impact of collaborative activities’ types and characteristics on WCB has been overlooked.
Knowledge workers increasingly engage in collaborative activities (Tagliaro et al., 2022; Gensler, 2020), which in turn enhances team and organizational performance (Mathieu et al., 2017; Heerwagen et al., 2004; Olson, 2002). Collaboration is critical as it facilitates knowledge sharing within organizations (Heerwagen et al., 2004). Thus, creating office spaces that foster collaboration has become a priority for optimizing workforce potential. However, despite the recognized significance of collaboration, empirical studies on designing offices for collaborative activities are lacking.
Previous research differentiated between collaborative and individual activities (Tagliaro et al., 2022; Ma and Cha, 2021; Haynes, 2007a; Heerwagen et al., 2004). To create an auspicious office environment, we should go beyond this dichotomy and better understand collaborative activities, which are crucial for optimizing office design and performance (Wohlers and Hertel, 2017). Therefore, this article explores the characteristics of collaborative activities essential for office design.
To foster office spaces for collaborative work, we need to understand the employees’ reasons for working on-site. Choosing where to work is the first step toward an active task-environment crafting behavior, which has been linked to increased job satisfaction and performance (Hoendervanger et al., 2022; Bäcklander et al., 2021; Wohlers and Hertel, 2018). However, while studies have shown that workers prefer collaborating on-site and focused individual work at home (Appel-Meulenbroek et al., 2022), it remains uncertain whether this preference applies to all collaborative activities.
This article addresses two pivotal research questions (RQs) that result in two significant contributions. First, we address the following:
What dimensions of collaborative activities can be identified in the literature, and which models best fit these dimensions empirically?
By examining the literature on various collaborative activities and conducting two confirmatory factor analyses (CFAs), we contribute a theoretical and empirical basis to differentiate among three distinct categories of collaborative activities based on their frequency and preferred location. Second, the article tackles the following:
How do collaborative activity patterns influence WCB?
By exploring collaborative activities' frequency and location preferences, alongside other influencing variables like personal characteristics and environmental factors, we provide insights into office design strategies, thus enabling organizations to create environments catering to diverse collaborative activity needs. To pursue these RQs, we conducted two studies at a research institution and a university undergoing workspace redesign. The diverse work profiles and redesign efforts provided the opportunity to answer our research questions.
Toward a classification of collaborative activities
The focus on collaboration has surged, driven by its role in enhancing team and organizational performance, facilitating knowledge work, and managing complex tasks. Team and organizational performance improve with effective collaboration (Olson, 2002). As tasks become more complex and urgent, interest in collaboration has increased alongside expectations for higher productivity (Mathieu et al., 2017). Recent studies have found that workers spend nearly equal time on collaborative and individual activities, with some variation for different roles, e.g. management (Tagliaro et al., 2022; Gensler, 2020). Consequently, the focus on designing offices that nurture collaboration has grown.
Research on office environments considers different aspects of activities, sometimes called work behaviors or activity patterns, which can be classified along several dimensions: nature of work (individual vs collaborative), plannability (planned vs unplanned), formality (formal vs informal), complexity, duration and location (Steffen and Schulze, 2020; Appel-Meulenbroek et al., 2015; Maarleveld and Been, 2011; Tabak, 2008); see Table 1 for a systematic overview.
The focus on individual and group activities has overshadowed other dimensions (Tagliaro et al., 2022; van den Berg et al., 2020; Soriano et al., 2020; Haynes, 2007b; Heerwagen et al., 2004; Olson, 2002). Unfortunately, this dimension is oversimplified as merely a choice between working alone or with others with researchers focusing on either the need to work alone (Olson, 2002) or with others (Heerwagen et al., 2004). Even more, individual and group activities are seen as conflicting, with employees navigating the tradeoff between focusing and socializing (Reder and Schwab, 1990).
The planned character of activities refers to their planned (scheduled) versus unplanned (opportunistic) character (Appel-Meulenbroek et al., 2022; Hoendervanger et al., 2022; Heerwagen et al., 2004; Hrastinski, 2010; Kraut et al., 1990; Fish et al., 1990). When discussing planned activities, it is crucial to differentiate between unplanned yet intentional interactions, as 72% of unplanned meetings are intentional (Appel-Meulenbroek et al., 2017).
Formality of activities is defined by their structured, ruled-governed and planned nature, contrasting with informality characterized by spontaneity, lack of planning and fluidity (Appel-Meulenbroek et al., 2015; Budie et al., 2019; Hrastinski, 2010; Olson, 2002). While informal activities include both work and private communication, work-related discussions are predominant (Kraut et al., 1990).
Complexity, the cognitive and coordinative effort required to complete an activity successfully, has been considered by previous research (Maher and von Hippel, 2005; Soriano et al., 2020). Complex tasks require increased concentration (Bedny et al., 2012), highlighting the need to consider this in office design (Appel-Meulenbroek et al., 2022; Hoendervanger et al., 2022). Complex tasks have occasionally been opposed to communication. However, communicative tasks, especially creative ones, can be cognitively demanding.
Activity duration varies from prolonged periods, like problem-solving workshops, to shorter instances, like brief conversations (Reder and Schwab, 1990; Kraut et al., 1990; Heerwagen et al., 2004). The environmental design can impact social interactions’ length. On average, interactions in closed offices are longer compared to bullpen or pod workspaces (Becker and Sims, 2001). Duration varies with interaction spontaneity; planned encounters last longer than spontaneous ones (Kraut et al., 1990).
Location refers to where the activity is performed, typically distinguishing between office-based and home-based work. Working from home is specific to the knowledge-intensive sector (Fawcett and Song, 2009), which has higher remote work rates, primarily attributed to location-independent tasks (Felstead, 2022; Adrjan et al., 2021) and better digital preparedness (Adrjan et al., 2021). In flexible office studies, research typically concentrates on location choice: one’s workspace on-site or elsewhere. Individual workspace are considered the primary “spatial tool for work”, meanwhile collaborative spaces play a secondary role in the office as employees across the USA spend 80% of time at individual workspace (Olson, 2002). Yet, the lack of collaborative spaces might be responsible for using personal workspace as primary location for social interaction (Olson, 2002).
Despite the importance of collaboration, a systematic empirical classification of collaborative activities is lacking hindering the development of offices conducive to collaboration. To address this, we propose a classification of collaborative activities along the discussed dimensions structured to create mutually exclusive and exhaustive categories (Table 2). Similarly to Robillard and Robillard (2000), we identify three collaborative activities categories: Coordinative activities, characterized by their planned and formal nature, medium to long durations and moderate complexity, support processes among team members to run smoothly. Deep collaboration activities are planned and formal but differentiated by complexity and creative demands. They comprise problem-solving to generate innovative ideas or develop new products or solutions. Spontaneous communicative activities, like impromptu and casual conversations, are unplanned, informal, short and of lower complexity.
Collaborative activities can be considered through a dual lens, focusing on frequency and preferred location. A high frequency of certain activities might require dedicated spaces to support quick interactions. Similarly, the preference for performing certain collaborative activities on-site might require specific office designs. Therefore, we claim that collaborative activities are multidimensional and propose a structured classification that accounts for this multidimensionality:
Collaborative activities can be empirically classified into three distinct types (coordinated, deep collaboration, and spontaneous) based on both their frequency (low to high) and preferred location (on-site vs at home), resulting in six unique factors.
Workspaces choice behavior
While it is uncertain which employees prefer to work remote and which on-site (Appel-Meulenbroek et al., 2022), face-to-face collaboration is consistently prioritized even as workers value working from home. Several pre-pandemic studies reported the prevalence of face-to-face interaction (Gensler, 2020; Tagliaro et al., 2022; Reder and Schwab, 1990). Post-pandemic studies indicate minimal changes in preferences, as workers prefer meeting, collaborating and socializing on-site (JLL, 2022a; JLL, 2022b). Most workers (70%) prefer the office for collaboration, while only 24% prefer collaborating from home (JLL, 2022a). Simultaneously, researchers question whether collaboration necessitates in-person office meetings (Tagliaro et al., 2022). Amid this, the office landscape changes in its core purpose. Previously focused on individual activities, offices are now often redefined as spaces for collaboration (JLL, 2022b).
The arguments for collaborating in the office are compelling. Yet research on workers’ workspace choices is still in its infancy (Appel-Meulenbroek et al., 2022). Therefore, it is crucial to understand how different aspects of collaborative activities, like frequency and preferred location, interact with workers’ workspace choices. Surprisingly, no previous studies have explored the impact of collaboration frequency and preferred location on workers’ WCB. This paper aims to fill this research gap by examining the relationship between the frequency and preferred location of collaborative activities and WCB. We reviewed previous literature on factors influencing workers' choice and identified three categories: personal characteristics, activity characteristics and environmental factors.
Personal characteristics
Personal characteristics, encompassing gender, commute time, job function and preferences toward work location, received substantial attention. The relationship between gender and WCB has yielded inconsistent results. Appel-Meulenbroek et al. (2022) found that the home-workers segment contained relatively more females, whereas Tagliaro et al. (2022) observed that females spent less time on remote work, despite both studies noting females' tendency towards administrative tasks and individual work. These discrepancies may stem from different study contexts and methodologies. In Appel-Meulenbroek et al.’s (2022) study, the female workers had a longer commute, and the preference was based on choice rather than time spent in the office. Meanwhile, Tagliaro et al. (2022) report that organizational context limited administrative remote work opportunities, which might explain females' lower remote work engagement.
Other personal characteristics have consistent findings. Workers with shorter commutes are more inclined to work on-site (Appel-Meulenbroek et al., 2022). Different job functions vary in mobile work engagement (Tagliaro et al., 2022), and organizational roles are closely associated with undertaken tasks (Tagliaro et al., 2022; Olson, 2002). Specifically, managers engage in more frequent communication activities (Olson, 2002, #61530), while administrative personnel focus more on individual work (Tagliaro et al., 2022). Thus, we hypothesize:
Personal characteristics (gender, managerial function, age, commute time) influence the WCB.
Preferences, immediate antecedents of behavior (Tversky and Kahneman, 1981), can predict behavior in office context (Appel-Meulenbroek et al., 2022; Rolfö et al., 2018). At the same time, workers choose their work environment to benefit their activity (Bäcklander et al., 2021; Wohlers and Hertel, 2017) with a preference for on-site collaboration (Appel-Meulenbroek et al., 2015). Therefore, the location preference for collaborative activities could explain how long employees work on-site (i.e. WCB here defined as the choice between working in the office or at home). If employees prefer to collaborate in the office, they are likely to spend more time there. Therefore, we hypothesize:
The preference toward the location of collaborative activities influences the WCB.
Preferences for work locations are not solely personal; task demands might influence their emergence. While personal traits like introversion may drive the preference for quiet settings, the nature of the work itself – like work requiring deep focus – might be critical for defining tasks’ ideal environment.
Activity characteristics
The activity characteristics have been less researched in relation to WCB (Appel-Meulenbroek et al., 2022). Little is known about how activity frequency affects WCB, which depends on the workspace preferences and planned activities (Appel-Meulenbroek et al., 2022). However, collaborative work is expected to be performed more on-site than individual work (Appel-Meulenbroek et al., 2022). Therefore, we hypothesize:
The frequency of the collaborative activities influences the preference toward the location of the collaborative activities.
Environmental factors
Environmental factors, like environment, equipment and the weekday, are better researched and shown to impact WCB. WCB is affected by the fit between environment and task requirements (Appel-Meulenbroek et al., 2022; Coradi et al., 2015). Space availability and adequate equipment at home (Bockstahler et al., 2022; Wütschert et al., 2022) influence WCB similarly to crowdedness, availability of concentration and meetings spaces (Appel-Meulenbroek et al., 2022; Bockstahler et al., 2022) and poor equipment at home (Bockstahler et al., 2022). Additionally, weekdays affect WCB, with Mondays and Fridays less favored for on-site work (Bockstahler et al., 2022). Generally, the work environment satisfaction influences WCB (Bockstahler et al., 2022). Following the propositions of the Supply-Needs and the Person-Environment fit frameworks (Wohlers and Hertel, 2017; Wohlers and Hertel, 2018), we expect that the level of satisfaction with the on-site work environment influences workers’ choice behavior:
The work environment satisfaction influences the WCB.
Overview of the studies
We conducted two studies to examine our hypothesis. Both studies took place in the context of workspace redesign at a Swiss research institution (Study 1) and a university (Study 2). Study 1, conducted in 2021, explored whether collaborative activities could be classified empirically based on their frequency and location preference (on-site or at home) based on CFA. Study 2, carried out in 2022, replicated the CFA and investigated the drivers of WCB.
Statistical analysis
All continuous predictors were scaled and centered before the analysis. The CFA was performed using the full maximum-likelihood estimation (MLR) in lavaan (Rosseel, 2012). In both studies, the data were not multivariate normal. Therefore, a robust estimator MLR was used (Korkmaz et al., 2014). The models’ fit was evaluated based on following indices: 2 log likelihood chi-square value (χ2), comparative fit index (CFI), root mean square error of approximation (RMSEA), standardized root mean square residual (SRMR) and Akaike information criterion (AIC).
The regression analysis was based on apa Tables (Stanley and Stanley, 2022). Missing data were imputed using the norm.predict method (Van Buuren and Groothuis-Oudshoorn, 2011). Due to concerns about the linearity between performance and hybrid work, we checked the distribution of fitted and residual data (see Appendix Figure A1). Despite some outliers, the regression variables follow a linear trend.
Participants
Study 1: Of the 406 survey participants employed at a Swiss research institution, 285 German-speaking employees were included in the CFA. The participants had an average age of 45 years (SD = 10, ranging from 21 to 70 years old), comprising 62 females, 221 males and two other gender categories.
Study 2: A total of 352 employees of a Swiss University (48 years on average, SD = 10, ranging from 19 to 65 years old; 255 female, 92 male and five other) participated in the survey conducted in the context of an office redesign research project. A hybrid working policy was in place at the time of the study. Participants spend about 68% of their working time on-site and the other 32% working from home or elsewhere. Working alone is most frequent (41%), followed by collaborative work (30%); with large variability of WCB shown by standard deviations. The office environment had few retreats for spontaneous exchanges or phone calls. Employees with a work quota of 80% or more had an assigned workplace while those with 50% worked mainly in a desk-sharing zone. Offices were predominately for groups of 4 to 12 people. Individual offices were seldom and usually reserved for higher management.
The participants in both studies had heterogeneous jobs ranging from research to administrative. Participation in both studies was voluntary, and the participants were informed about the study’s content and scope.
Measures
The items describing collaborative activities' frequency and preferred location were adapted from (Steffen and Schulze, 2020); see Tables 2 and 4. Examples of items include “Meeting for two (e.g. project discussions, […])” for coordination; “Intensive collaboration (e.g. writing a report together, preparing and evaluating experiments) for deep collaboration; and “Spontaneous and informal communication/exchange both work-related and private (e.g. short exchanges […])” for spontaneous communication.
These items were measured on two different scales. First, the participants were asked to report the frequency with which they performed the collaborative activities (How often did they perform the following activities in the last three months?) on a scale from 1 = never to 5 = very often. After that, the participants were asked to report their location preferences (To what extent would you like to carry out the […] activities on-site at […] or other locations (e.g. at home) if you were free to choose?) on a scale from 1 = 100% at home to 11 = 100% on-site. Different answer formats and scale types (5-Lickert scale for frequency and 11-Likert scale for location preference) were used to minimize common methods bias (Podsakoff et al., 2012).
WCB was measured as time spent in different working locations based on items from the Fourth European Working Conditions Survey (Parent-Thirion et al., 2007). To measure WCB, the participants were asked to report the percentage of time they typically spent at different locations on-site (individual desk, meeting room, classroom, library, other) and off-site (working from home, coworking space outside the organization, other places outside the organization): What percentage of time have you typically spent during a work week at which location?
Work environment satisfaction (WES) was measured using the question, Overall, how satisfied are you with your working environment at your company’s location? (Gerdenitsch et al., 2018) on a scale from 1 = very unsatisfied to 7 = very satisfied. Following(Hoendervanger et al., 2019), we argue that this is acceptable because “workplace satisfaction is a sufficiently narrow and unambiguous construct.”
Results
Classification of collaborative activities
To evaluate H1, we conducted a CFA on 12 items in both studies, see Table 4.We compared two models: The first model comprised two factors: frequency and preferred collaborative activities location. The second model had six factors: frequency of coordinative activities, frequency of deep collaboration, frequency of spontaneous communication, preferred location of coordinative activities, preferred location of deep collaboration and preferred location of spontaneous communication.
Results from both studies show that the six-factor model (Model 2) provided a better fit than the two-factor model (Model 1) (Table 3). In Study 1, Model 2 (χ2(39) = 98.60, p > 0.05;CFI = 0.95; TLI = 0.92, RMSEA = 0.07, SRMR = 0.05) approximates the data better than Model 1 (χ2(6)=67.78, p < 0.01). In Study 2, we see similar results; Model 2 (χ2(39) = 93.90, p > 0.05; CFI = 0.98; TLI = 0.96, RMSEA = 0.06 [0.04, 0.08]; SRMR = 0.03) approximates the data better than Model 1 (χ2(6) = 14.35, p < 0.01). Therefore, the six-factor model best approximates the structure of collaborative activities.
The frequency of collaboration scales had poorer validity and reliability than location preferences, likely because of the reduced response scales levels (Table 4). Study 2 has a better fit probably due to the larger sample size. Smaller range scales reduce the true variance and covariance among items, affecting the validity and reliability; therefore, for further usage of the scale for smaller sample sizes, we recommend using a larger range of answers for collaborative activities frequency.
In both studies, Model 2 met the standards of convergent validity for all factors regarding collaboration place. All loadings were above 0.50, considered acceptable in exploratory research or with complex constructs (Hair et al., 2013). In Study 2, the construct validity measured as average variance extracted (AVE) was greater than 0.40 (Shrestha, 2021; Hair et al., 2021) for Model 2. For Study 1, the AVE for Factor 3: Frequency of Spontaneous Communication was slightly below the standard threshold at 0.39. Despite the slightly lower AVE, all items related to this factor have significant loadings, and the composite reliability exceeds the acceptable threshold.
The reliability measured as composite construct reliability (CR) and ω-measure showed similar patterns for Factor 3 in Study 1. For Model 2 in Study 2, composite construct reliability (CR) was greater than the threshold of 0.60 (Shrestha, 2021; Hair et al., 2021; Nájera Catalán, 2019; Raykov and Shrout, 2002) and ω was over the threshold of 0.65 (Nájera Catalán, 2019).
Given the significant factor loadings of the items for both studies and the strong theoretical framework, Factor 3's AVE slightly missing the conventional threshold in Study 1 is acceptable. In Study 2, Model 2 meets all validity and reliability measures. Thus, the data provide sound measurements of the measured constructs supporting H1: Collaborative activities can be empirically classified into three distinct types based on both their frequency and preferred location.
Workspaces choice behavior (WCB)
Examining the study variables in Table 5, we observe that spontaneous collaboration is the most frequent type of collaborative activity but not the preferred one to perform on-site. Employees prefer on-site work for deep collaboration. Further, the WCB shows positive correlations with most variables, especially WES and on-site preferences and activities’ frequency, except for coordinative activities. The frequencies of collaborative activities (coordinative, deep collaboration, spontaneous communication) are positively associated with the preference to perform them on-site, which is nominally relatively high. On average, workers spend almost 67% of their time on site. The preference to work on-site positively correlates to the WES for all activity types. WES shows mixed correlations to collaboration frequency: negative with deep collaboration, positive with spontaneous communication and no correlation with coordinative activities, hinting at distinct requirements of these activities.
Regression analysis was performed to test H1 to H5 (Table 6). Personal characteristics like gender, managerial function, age and commute time yielded no significant results. Therefore, we found no evidence that personal characteristics (gender, managerial function, age and commute time) influence WCB.
The path coefficients between preference toward the location of collaborative workspace activities and WCB were statistically significant and positive for coordinative activities (b = 0.21, p < 0.01) and spontaneous communication activities (b = 0.16, p < 0.01) but not for deep collaboration. Employees who preferred on-site coordinative and spontaneous communication activities tend to spend more time on-site. Notably, the preference toward the location of deep collaboration and WCB was significant for zero-order correlations. Therefore, the data partially suggest that preference toward the location of collaborative workspace activities influences the WCB.
The path coefficients between collaborative activities’ frequency and WCB are significant only for the frequency of spontaneous communication (b = 0.18, p < 0.01). In contrast, the frequency of coordinative and deep collaborative activities does not bear influence on the time spent on-site, despite the significant zero-order correlation with the frequency of the deep collaboration. Therefore, it follows that only frequency of spontaneous communication influences the WCB.
The WES was positively related to the WCB (b = 0.12, p < 0.01). WES leads employees to spend more time in the office. Therefore, we conclude that the WES influences WCB.
Discussion
In this article, we explored which characteristics of collaborative activities should be considered when redesigning or redefining future offices. For this, we theoretically identified and empirically validated three distinct types of collaborative activities: coordinative activities (planned and formal), deep collaboration (planned and complex) and spontaneous communication (informal and brief). These categories differ in frequency of occurrence and location preference. The empirical validation of the classification is a methodological strength of this article.
The second aim was to determine how the collaborative activities, alongside other factors, influence WCB. We expected WCB to be driven by personal characteristics, collaborative activity patterns, and WES. Unlike prior research suggesting user characteristics (Appel-Meulenbroek et al., 2022; Tagliaro et al., 2022) and roles (Tagliaro et al., 2022; Gensler, 2020) affect WCB, our study found no influence from age, gender, management position or commute time. Yet, not all personal characteristics were irrelevant. Among the analyzed predictors of WCB, location preference emerged as a pivotal predictor of time spent on-site, surpassing other factors. The preference for on-site coordinative and spontaneous activities drives employees to spend more time in the office. This suggests that location preferences rather than demographics have a greater influence on WCB.
The results reveal that activity patterns (frequency), and personal characteristics (preferred location) influence the time spent on-site. Notably, frequent spontaneous communication correlates with an increased on-site presence. Conversely, more frequent coordination and deep collaboration activities do not necessarilly predict on-site presence. Despite a higher preferences for on-site work during deep collaboration, this does not lead to increased on-site presence. This might be explained by the dissatisfaction with the work environment as employees frequently engaging in deep collaboration were less satisfied.
Nevertheless, differentiating between types of collaborative activities helps advance the discussion on office design beyond the dichotomy of individual vs collaborative activities. Indeed, the results show that the issue extends beyond merely whether workers collaborate. The kind of collaboration matters too. The results show that frequent spontaneous communication was more prevalent for people working longer hours in the office, while frequent coordination and deep collaboration were not. Consistent with previous findings, our findings show that frequent spontaneous communication increases on-site presence (Appel-Meulenbroek et al., 2022), while coordinative and deep collaboration do not. This stresses the importance of spontaneous communication which has been previously overlooked (Meinecke and Handke, 2022).
The results show that work environment satisfaction (WES) directly affects time on-site, aligning with previous studies (Appel-Meulenbroek et al., 2022; Bockstahler et al., 2022; Coradi et al., 2015). Employees frequently engaging in deep collaboration were more dissatisfied with the workspace. Therefore, WES must be considered within the broader context of the preference for on-site work and the office space suitability for collaboration.
We make two significant contributions to the design of collaborative work in general, especially in the context of office design. First, we empirically validate the proposed classification of collaborative activities. As noted, various authors have theoretically discussed the relevance of different collaborative activity types to office design (Steffen and Schulze, 2020; Appel-Meulenbroek et al., 2015; Maarleveld and Been, 2011; Robillard and Robillard, 2000), yet an empirical validation was missing. This article fills this gap by showing that collaborative activities can be theoretically derived and are empirically stable.
A noteworthy contribution of this classification is the distinction between coordinative and deep collaboration activities. Despite the widely discussed necessity of deep work for individual activities (Newport, 2016), deep collaboration was overshadowed by the emphasis on focused individual activities. Previous research, with some exceptions, has primarily overlooked this distinction (Robillard and Robillard, 2000). Yet, some results show the need for differentiated collaborative spaces. For example, workers frequently engaging in deep collaboration were less satisfied with the work environment. Given the effect of team communication on performance (Maarleveld and Been, 2011), office designs tailored to the specific needs of the deep collaboration activities could boost this relationship. By distinguishing between these forms of collaborative activities, we contribute to the dialogue on enhancing office design to support collaboration.
Second, this study expands previous research on determinants of WCB, which focused primarily on personal characteristics and environmental factors (Appel-Meulenbroek et al., 2022; Tagliaro et al., 2022; Olson, 2002) by considering the role of collaborative activities’ characteristics. The latter have proven more impactful on WCB than personal characteristics and environmental factors.
Practical implications
The findings have practical implications for office designers and organizational leaders. By understanding the patterns of collaborative activities, organizations can design workspaces that cater to the employees’ unique needs and thus foster effective collaboration. The study deepens the understanding of the WCB's determinants and informs decisions regarding remote work policies.
Office design should support collaborative and individual work. Office spaces as organizational resources can potentially changing communication patterns (Rashid et al., 2006). Yet, while efforts have been made to enhance comfort and safety in the workplace, knowledge about how office design influences collaboration is still in its infancy (Elsbach and Bechky, 2007). We inform a differentiated design of physical environments for collaboration. For once, the strong preference for collaborating on-site suggests that despite the change in remote work patterns and technological advances, employees still value physical proximity, especially for deep and spontaneous collaboration.
Employees engaging more often in deep collaboration are less satisfied with the environment. While the study does not pinpoint the cause, the lack of adequate spaces for deep collaboration might be a mitigating factor. Collaborative spaces are often limited to sedentary meeting rooms, which might suit coordination but not deep collaboration. Collaborative settings need redesigning. Non-sedentary settings lead to better information elaboration and better group performance (Knight and Baer, 2014). Given the importance of collaborative problem-solving, organizations need dedicated spaces with flexible furniture arrangements and technologies to facilitate the exchange of ideas and promote innovative thinking.
Before dramatically redesigning offices, we must consider whether transforming the office into collaborative spaces benefits all employees (Appel-Meulenbroek et al., 2022). The participants in the second study spent about half their time engaged in individual activities (41%), more than the total time spent working from home or elsewhere (32%). This indicates that employees worked on individual tasks on-site. Therefore, offices need to support both collaborative and individual work. This is critical, as distractions increase exhaustion and are associated with health risks (Appel-Meulenbroek et al., 2020). Moreover, designing the workspace to accommodate individual work enhances individual and team performance (Olson, 2002; Maarleveld and Been, 2011).
Implications for attracting workers back to the office. Our findings assist managers create more compelling policies for returning to the office. Changing the office to support deep collaboration and spontaneous communication could incentivize for working on-site. Remote work policies should be guided by collaboration types requiring face-to-face interaction. The of the tasks and employees’ preferences should be considered when evaluating the feasibility of remote work for different collaborative activities and the appropriate balance between on-site and remote collaboration.
Limitations and future directions
This study has several limitations. The findings are based on a specific sample and context, which may not be generalizable to other industries or organizations. Replication studies across different settings are needed. The study uses a cross-sectional design, capturing data at a specific point in time; longitudinal studies could reveal changes in workspace preferences over time. Data relie on self-reported measures subject to biases, which we mitigated by reducing the common method bias (Podsakoff et al., 2012). Future research should use objective measures. The study examines personal characteristics, activity characteristics and WES to explain WCB but does not consider factors like policies or resource availability like digital tools. Further research could explore collaborative technology’s role impact on WCB.
Conclusion
Differentiating between various types of collaboration contributes to the discussion around WCB, offering valuable insights for improving office design to support collaboration. The results show that some patterns of collaborative activity but not all impact WCB. The spontaneous communication’s frequency and location preference and work environment satisfaction are among the strongest predictors of on-site work. Personal characteristics like gender, age, managerial position and commute time do not affect WCB. Considering these results, organizations can tailor office spaces to accommodate better the needs of collaborative activities. Despite limitations, the findings provide valuable insights into collaboration preferences and workspace choice.
Figures
Figure A1.
Assumption check for the performed regression analysis
Summary of consulted taxonomic literature
| Authors | Underlying dimension | Taxonomic categories |
|---|---|---|
| Appel-Meulenbroek et al. (2014) | Individual vs group work, Formal vs informal settings |
Behind the computer, writing, reading, on the phone, archiving, in a meeting, informal talk, presenting, lunch, toilet visit, coffee break |
| Appel-Meulenbroek et al. (2015) | Formal vs informal settings | Work-related activity, informal meeting, formal meeting, telephone/video, informal activity |
| Appel-Meulenbroek et al. (2022) | Planned vs unplanned activities, Individual (concentrated) vs communicative |
Communication-scenario, concentration-scenario, 50 / 50-scenario |
| Brown (2008) | Planned vs unplanned activities | Meetings planned and scheduled in advance, on-demand meetings between a few individuals, chance meetings |
| Budie et al. (2019) | Concentration vs nonconcentration, Formal vs informal |
Individual concentration work, individual non-concentrated work, formal communication, informal communication, phone calls |
| Fish et al. (1990) | Formal vs informal communication, Planned vs unplanned activities |
Formal vs informal communication, planned vs unplanned activities |
| Hoendervanger et al. (2022) | Individual vs group work, Planned vs unplanned activities, Formal vs informal settings, Task complexity |
Individual high-concentration work, individual low-concentration work, planned face-to-face communication, non-planned face-to-face communication, communication through phone or video, taking a break |
| Hrastinski (2010) | Formal vs informal communication, Planned vs unplanned activities |
Formal face-to-face meetings, ad hoc face-to-face meetings |
| Maarleveld and Been (2011) | Individual vs group work, Planned vs unplanned activities, Formal vs informal settings, Task complexity |
General desk work, desk work concentration, desk work interaction, planned meetings, unplanned meetings, telephone use, reading, document management |
| Maher and von Hippel (2005) | Task complexity | Tasks were rated regarding concentration, distractibility, and difficulty |
| Öhrn et al. (2021) | Individual vs group work, Task complexity, Planned vs unplanned activities |
Individual work tasks requiring concentration, teamwork, spontaneous meetings |
| Robillard and Robillard (2000) | Individual vs group work, Task complexity, Planned vs unplanned activities |
Mandatory collaborative activities, called collaborative activities, ad hoc collaborative activities, individual activities |
| Steffen and Schulze (2020) | Individual vs collaborative work, Planned vs unplanned activities, Formal vs informal settings, Duration |
Alone: concentrated/focused work; routine work at the computer; creative work; phone calls/video calls, With others: informal communication; co-working; formal (planned) meetings; workshop meetings |
| van den Berg et al. (2020) | Individual vs collaborative work, Formal vs informal interactions |
Individual concentration work; informal interactions; formal interactions |
| Tagliaro et al. (2022) | Location Individual vs collaborative work |
Mobile work, individual work, teamwork, inter-team work, intrateam work |
Source: Authors' own work
Integrated categories of collaborative activities
| Type of collaborative activities | Relevant characteristics | Examples of constructed items | |||
|---|---|---|---|---|---|
| Planned | Formal | Complex | Long | ||
| Coordinative activities | + | + | – | (+) | Meeting for two (e.g. project discussions, …) Meeting with 3–7 people (e.g., project discussions …) |
| Deep collaboration activities | + | + | + | (+) | Intensive collaboration (e.g. writing a report together …) Shorter working meetings/collaboration for joint creative or substantive work |
| Spontaneous communicative | (–) | – | – | (–) | Spontaneous and informal communication/exchange, both work-related and private (e.g. short exchanges …) Short-term, usually short, goal-oriented exchange (e.g. quick exchange meetings … convened at short notice) |
Source: Authors' own work
Overall fitness of the tested models
| Study 1 | Study 2 | |||
|---|---|---|---|---|
| Criteria | Model 1: Two factors | Model 2: Six factors | Model 1: Two factors | Model 2: Six factors |
| χ2 | χ2(53) = 168.76 | χ2(39) = 98.60 | χ2(53) = 344.35 | χ2(39) = 93.90 |
| CFI | 0.90 | 0.95 | 0.85 | 0.98 |
| TLI | 0.88 | 0.92 | 0.81 | 0.96 |
| RMSEA | 0.08 [0.07, 0.10] | 0.07 [0.05, 0.09] | 0.12 [0.11, 0.14] | 0.06 [0.04, 0.08] |
| SRMR | 0.08 | 0.05 | 0.07 | 0.03 |
Source: Authors' own work
Convergent validity, reliability (AVE, CR)
| Factor/Item | Study 1; Model 2 | Study 2; Model 2 | ||||||
|---|---|---|---|---|---|---|---|---|
| Loadings | AVE | CR | ω | Loadings | AVE | CR | ω | |
| Frequency of activities1: How often do you typically perform the following activities in your everyday work? | ||||||||
| Factor 1: Frequency of coordinative activities=∼ | 0.47 | 0.63 | 0.63 | 0.53 | 0.69 | 0.70 | ||
| Meeting for two (e.g. project discussions, internal discussions/meetings, working with partners and customers, phone calls) | 0.78 | 0.73 | ||||||
| Meeting with 3–7 people (e.g. project discussions, internal discussions/meetings, working with partners and customers, phone calls) | 0.59 | 0.73 | ||||||
| Factor 2: Frequency of deep collaboration=∼ | 0.44 | 0.61 | 0.62 | 0.53 | 0.69 | 0.66 | ||
| Intensive cooperation | 0.64 | 0.67 | ||||||
| Shorter working meetings for joint creative or content work | 0.67 | 0.78 | ||||||
| Factor 3: Frequency of spontaneous communication=∼ | 0.39 | 0.55 | 0.55 | 0.65 | 0.79 | 0.78 | ||
| Spontaneous and informal communication /exchange, both work-related and private | 0.75 | 0.86 | ||||||
| Short-term, usually short, goal-oriented exchange | 0.48 | 0.75 | ||||||
| Place preference2:To what extent would you like to carry out the communication and coordination activities on-site at … or other locations (e.g. home office) if you were free to choose? | ||||||||
| Factor 4: Place preference coordinative activities=∼ | 0.72 | 0.84 | 0.83 | 0.69 | 0.80 | 0.81 | ||
| Meeting for two (e.g. project discussions, internal discussions/meetings, working with partners and customers, phone calls) | 0.86 | 0.82 | ||||||
| Meeting with 3–7 people (e.g. project discussions, internal discussions/meetings, working with partners and customers, phone calls) | 0.83 | 0.83 | ||||||
| Factor 5: Place preference deep collaboration=∼ | 0.57 | 0.73 | 0.73 | 0.68 | 0.91 | 0.81 | ||
| Intensive collaboration (e.g., writing a report together, preparing and evaluating experiments, etc.) | 0.80 | 0.79 | ||||||
| Shorter working meetings/collaboration for joint creative or substantive work | 0.71 | 0.85 | ||||||
| Factor 6: Place preference spontaneous communication=∼ | 0.64 | 0.78 | 0.78 | 0.66 | 0.81 | 0.79 | ||
| Spontaneous and informal communication / exchange, both work-related and private | 0.83 | 0.81 | ||||||
| Short-term, usually short, goal-oriented exchange | 0.78 | 0.81 | ||||||
1Frequency of collaborative activities was measured on a scale from 1 = never to 5 = very often; 2preferences for on-site collaboration was measured on a scale from 1 = 0% on-site to 11 = 100% on-site. M and SD are used to represent mean and standard deviation. Values in square brackets indicate the 95% confidence interval for each correlation. The confidence interval is a plausible range of population correlations.
*indicates p < 0.05.
**p < 0.01
Source: Authors' own work
Means, standard deviations and correlations with confidence intervals
| Variable | M | SD | 1 | 2 | 3 | 4 | 5 | 6 | 7 |
|---|---|---|---|---|---|---|---|---|---|
| 1. Frequency coordinative activities 1 | 3.58 | 0.69 | |||||||
| 2 Frequency deep collaboration | 3.44 | 0.79 | 0.54** | ||||||
| 3. Frequency spontaneous communication 1 | 3.62 | 0.88 | 0.38** | 0.43** | |||||
| 4. Location coordinative activities 2 | 7.82 | 2.59 | 0.17** | 0.29** | 0.29** | ||||
| 5. Location deep collaboration 2 | 8.10 | 2.56 | 0.17** | 0.36** | 0.26** | 0.70** | |||
| 6. Location spontaneous communication 2 | 7.92 | 2.75 | 0.16** | 0.24** | 0.40** | 0.62** | 0.61** | ||
| 7. Satisfaction work environemnt 3 | 5.06 | 1.40 | −0.07 | −0.12* | 0.13* | 0.16** | 0.15** | 0.16** | |
| 8. Current WCB 4 | 67.66 | 22.39 | 0.07 | 0.14** | 0.31** | 0.40** | 0.36** | 0.39** | 0.21** |
Notes: 1Frequency of collaborative activities: 1 = never to 5 = very often; 2preferenced location of on-site collaboration: 1 = 0% on-site to 11 = 100% on-site; 3satisfaction with workspace environment was measured on a scale from 1 = very unsatisfied to 7 = very satisfied 4current WCB: 0% to 100%. M and SD represent mean and standard deviation
*indicates p < 0.05;
**indicates p < 0.01
Source: Authors' own work
Regression results using WCB (time on site) as criterion
| Predictor | b | b 95% CI [LL, UL] |
beta | beta 95% CI [LL, UL] |
r | Fit |
|---|---|---|---|---|---|---|
| (Intercept) | 0.02 | [−0.17, 0.21] | ||||
| Personal characteristics | ||||||
| Gender (women) | −0.02 | [−0.24, 0.19] | −0.01 | [−0.11, 0.08] | −0.03 | |
| Management (yes) | −0.01 | [−0.26, 0.24] | −0.00 | [−0.10, 0.09] | 0.00 | |
| Age | 0.00 | [−0.09, 0.10] | 0.00 | [−0.09, 0.10] | 0.04 | |
| Commute time | −0.04 | [−0.13, 0.06] | −0.04 | [−0.13, 0.06] | −0.09 | |
| Location preference coordinative activities | 0.21** | [0.07, 0.35] | 0.21 | [0.07, 0.35] | 0.40** | |
| Location preference deep collaboration | 0.04 | [−0.10, 0.19] | 0.04 | [−0.10, 0.19] | 0.34** | |
| Location preference spontaneous communication | 0.16* | [0.02, 0.29] | 0.16 | [0.02, 0.29] | 0.39** | |
| Activity characteristics | ||||||
| Frequency coordinative activities | −0.05 | [−0.17, 0.06] | −0.05 | [−0.17, 0.06] | 0.07 | |
| Frequency deep collaboration | −0.01 | [−0.13, 0.12] | −0.01 | [−0.13, 0.12] | 0.14** | |
| Frequency spontaneous communication | 0.18** | [0.06, 0.29] | 0.18 | [0.06, 0.29] | 0.31** | |
| Environmental factors | ||||||
| Work environment satisfaction (WES) | 0.12* | [0.02, 0.22] | 0.12 | [0.02, 0.22] | 0.21** | |
| R 2 = 0.24** 95% CI[0.14,0.29] |
||||||
A significant b-weight indicates the beta-weight and semi-partial correlation are significant. b represents unstandardized regression weights. Beta indicates the standardized regression weights. r represents the zero-order correlation. LL and UL indicate the lower and upper limits of a confidence interval, respectively.
*indicates p < 0.05.
**p < 0.01
Source: Authors' own work
Appendix
References
Adrjan, P. et al. (2021), Will It Stay or Will It Go? Analysing Developments in Telework during COVID-19 Using Online Job Postings Data, OECD, Paris.
Appel-Meulenbroek, R. et al. (2014), “Corporate real estate management with the implementation of a modern work environment that supports employees and their activities: an analysis of different preferences in 5 European countries”, Proceedings of the 21st Congress of the European Real Estate Society (ERES 2014).
Appel-Meulenbroek, R. et al. (2015), “To use or not to use: which type of property should you choose”, Journal of Property Investment and Finance, Vol. 33 No. 4, pp. 320-336.
Appel-Meulenbroek, R., de Vries, B. and Weggeman, M. (2017), “Knowledge sharing behavior: the role of spatial design in buildings”, Environment and Behavior, Vol. 49 No. 8, pp. 874-903.
Appel-Meulenbroek, R., et al. (2020), “Impact of activity-based workplaces on burnout and engagement dimensions”, Journal of Corporate Real Estate, Vol. 22 No. 4, pp. 279-296.
Appel-Meulenbroek, R., et al. (2022), “How to attract employees back to the office? A stated choice study on hybrid working preferences”, Journal of Environmental Psychology, Vol. 81, p. 101784.
Bäcklander, G., et al. (2021), “Development and validation of a multi-dimensional measure of activity-based working behaviors”, Frontiers in Psychology, Vol. 12, p. 655881.
Becker, F. and Sims, W. (2001), Offices That Work: Balancing Communication, Flexibility and Cost, International Workplace Studies Program,
Bedny, G.Z., Karwowski, W. and Bedny, I.S. (2012), “Complexity evaluation of computer-based tasks”, International Journal of Human-Computer Interaction, Vol. 28 No. 4, pp. 236-257.
Bockstahler, M., Jurecic, M. and Rief, S. (2022), “Working from home experience”, An Empirical Study from the User Perspective during the Corona Pandemic, Vol. 66.
Brown, G.M. (2008), “Proximity and collaboration: measuring workplace configuration”, Journal of Corporate Real Estate, Vol. 10, pp. 5-26.
Budie, B., et al. (2019), “Employee satisfaction with the physical work environment: the importance of a need-based approach”, International Journal of Strategic Property Management, Vol. 23 No. 1, pp. 36-49.
Coradi, A., Heinzen, M. and Boutellier, R. (2015), “Designing workspaces for cross-functional knowledge-sharing in R &D: the ‘co-location pilot’ of Novartis”, Journal of Knowledge Management, Vol. 19 No. 2, pp. 236-256.
Elsbach, K.D. and Bechky, B.A. (2007), “It’s more than a desk: working smarter through leveraged office design”, California Management Review, Vol. 49 No. 2, pp. 80-101.
Fawcett, W. and Song, J.-Y. (2009), “Modelling the use of space and time in the knowledge economy”, Building Research and Information, Vol. 37 No. 3, pp. 312-324.
Felstead, A. (2022), Remote Working: A Research Overview, Routledge, London.
Fish, R.S., Kraut, R.E. and Chalfonte, B.L. (1990), “The VideoWindow system in informal communication”, Proceedings of the 1990 ACM conference on Computer-supported cooperative work, pp. 1-11.
Gensler (2020), “UK workspace survey 2020”.
Gerdenitsch, C., Korunka, C. and Hertel, G. (2018), “Need–supply fit in an activity-based flexible office: a longitudinal study during relocation”, Environment and Behavior, Vol. 50 No. 3, pp. 273-297.
Hair, J.F., et al. (2013), Multivariate Data Analysis, Pearson Education, Upper Saddle River, NJ.
Hair, J.F., et al. (2021), Partial Least Squares Structural Equation Modeling (PLS-SEM) Using R, Springer International Publishing, Cham.
Haynes, B.P. (2007a), “Office productivity: a theoretical framework”, Journal of Corporate Real Estate, Vol. 9 No. 2, pp. 97-110.
Haynes, B.P. (2007b), “The impact of the behavioural environment on office productivity”, Journal of Facilities Management, Vol. 5 No. 3, pp. 158-171.
Heerwagen, J.H., et al. (2004), “Collaborative knowledge work environments”, Building Research and Information, Vol. 32 No. 6, pp. 510-528.
Hoendervanger, J.G., et al. (2019), “Perceived fit in activity-based work environments and its impact on satisfaction and performance”, Journal of Environmental Psychology, Vol. 65, p. 101339.
Hoendervanger, J.G., et al. (2022), “Perceived fit and user behavior in activity-based work environments”, Environment and Behavior, Vol. 54 No. 1, pp. 143-169.
Hrastinski, S. (2010), “The informal and formal dimensions of computer-mediated communication: a model”, International Journal of Networking and Virtual Organisations, Vol. 7 No. 1, pp. 23-38.
JLL (2022a), “Reimagining human experience”.
JLL (2022b), “The future of work survey 2022”.
Knight, A.P. and Baer, M. (2014), “Get up, stand Up”, Social Psychological and Personality Science, Vol. 5 No. 8, pp. 910-917.
Korkmaz, S., Goksuluk, D. and Zararsiz, G. (2014), “MVN: an R package for assessing multivariate normality”, The R Journal, Vol. 6 No. 2, p. 151.
Kraut, R.E., et al. (1990), “Informal communication in organizations: form, function, and technology”, Human Reactions to Technology: the Claremont Symposium on Applies Social Psychology, p. 199.
Ma, J.H. and Cha, S.H. (2021), “A user-specific activity pattern generation framework for evidence-based ABW planning”, Building and Environment, Vol. 189, p. 107519.
Maarleveld, M. and Been, I.D. (2011), “The influence of the workplace on perceived productivity”, 10th EuroFM Research Symposium.
Maher, A. and von Hippel, C. (2005), “Individual differences in employee reactions to open-plan offices”, Journal of Environmental Psychology, Vol. 25 No. 2, pp. 219-229.
Mathieu, J.E., et al. (2017), “A century of work teams in the journal of applied psychology”, Journal of Applied Psychology, Vol. 102 No. 3, p. 452.
Meinecke, A.L. and Handke, L. (2022), “The meeting after the meeting: a conceptualization and process model”, Organizational Psychology Review, Vol. 13 No. 4.
Nájera Catalán, H.E. (2019), “Reliability, population classification and weighting in multidimensional poverty measurement: a monte carlo study”, Social Indicators Research, Vol. 142 No. 3, pp. 887-910.
Newport, C. (2016), Deep Work: Rules for Focused Success in a Distracted World, Hachette UK.
Öhrn, M., et al. (2021), “Productivity, satisfaction, work environment and health after relocation to an activity-based flex office-the active office design study”, International Journal of Environmental Research and Public Health, Vol. 18 No. 14, p. 7640.
Olson, J. (2002), “Research about office workplace activities important to US businesses‐and how to support them”, Journal of Facilities Management, Vol. 1 No. 1, pp. 31-47.
Parent-Thirion, A., et al. (2007), “Fourth European working conditions survey”.
Podsakoff, P.M., MacKenzie, S.B. and Podsakoff, N.P. (2012), “Sources of method bias in social science research and recommendations on how to control it”, Annual Review of Psychology, Vol. 63 No. 1, pp. 539-569.
Rashid, M., et al. (2006), “Spatial layout and face-to-Face interaction in offices—a study of the mechanisms of spatial effects on face-to-face interaction”, Environment and Planning B: Planning and Design, Vol. 33 No. 6, pp. 825-844.
Raykov, T. and Shrout, P.E. (2002), “Reliability of scales with general structure: point and interval estimation using a structural equation modeling approach”, Structural Equation Modeling: A Multidisciplinary Journal, Vol. 9 No. 2, pp. 195-212.
Reder, S. and Schwab, R.G. (1990), “The temporal structure of cooperative activity”, Proceedings of the 1990 ACM Conference on Computer-Supported Cooperative Work, pp. 303-316.
Robillard, P.N. and Robillard, M.P. (2000), “Types of collaborative work in software engineering”, Journal of Systems and Software, Vol. 53 No. 3, pp. 219-224.
Rolfö, L. et al. (2018), “Predictors of preference for the activity-based flexible office”, Human Systems Engineering and Design: Advances in Intelligent Systems and Computing, (Ed, al., T.A.E.) Springer, Cham, pp. 547-553.
Rosseel, Y. (2012), “Lavaan: an R package for structural equation modeling”, Journal of Statistical Software, Vol. 48 No. 2, pp. 1-36.
Shrestha, N. (2021), “Factor analysis as a tool for survey analysis”, American Journal of Applied Mathematics and Statistics, Vol. 9 No. 1, pp. 4-11.
Soriano, A., et al. (2020), “The role of employees’ work patterns and office type fit (and misfit) in the relationships between employee well-being and performance”, Environment and Behavior, Vol. 52 No. 2, pp. 111-138.
Stanley, D. and Stanley, M.D. (2022), “Package ‘apaTables”.
Steffen, M. and Schulze, H. (2020), “Workspace-Related needs of knowledge workers–based on their work activity profile. Future workspaces”, Conference Proceedings of the 2nd TWR Conference 2020, p. 108.
Tabak, V. (2008), “User simulation of space utilisation: system for office building usage simulation”, Phd Thesis thesis, Technische Universiteit Eindhoven.
Tagliaro, C., Zhou, Y. and Hua, Y. (2022), “Work activity pattern and collaboration network: new drivers for workplace space planning and design”, Journal of Interior Design, Vol. 47 No. 3, pp. 29-46.
Tversky, A. and Kahneman, D. (1981), “The framing of decisions and the psychology of choice”, Science, Vol. 211 No. 4481, pp. 453-458.
Van Buuren, S. and Groothuis-Oudshoorn, K. (2011), “Mice: multivariate imputation by chained equations in R”, Journal of Statistical Software, Vol. 45 No. 3, pp. 1-67.
van den Berg, J., et al. (2020), “Knowledge workers’ stated preferences for important characteristics of activity-based workspaces”, Building Research and Information, Vol. 48 No. 7, pp. 703-718.
Wohlers, C. and Hertel, G. (2017), “Choosing where to work at work – towards a theoretical model of benefits and risks of activity-based flexible offices”, Ergonomics, Vol. 60 No. 4, pp. 467-486.
Wohlers, C. and Hertel, G. (2018), “Longitudinal effects of Activity-Based flexible office design on teamwork”, Frontiers in Psychology, Vol. 9.
Wütschert, M.S., et al. (2022), “A systematic review of working conditions and occupational health in home office”, Work, Vol. 72 No. 3, pp. 839-852.
Corresponding author
About the authors
Magdalena Mateescu is a researcher at the Institute for Research and Development of Collaborative Processes, School of Applied Psychology, University of Applied Sciences and Arts Northwestern Switzerland, and a PhD candidate at the Department of Industrial, Organizational and Social Psychology, Institute of Psychology, Technische Universität Braunschweig. Her research explores the effects of office design and digital media on collaborative processes and outcomes.
Hartmut Schulze serves as a Full Professor at Institute for Research and Development of Collaborative Processes, School of Applied Psychology, University of Applied Sciences and Arts of Northwestern Switzerland FHNW. His research focuses on applied research projects in areas like office design and hybrid work, collaborative processes and social robotics.
Simone Kauffeld holds a position as a full professor for Work, Organizational and Social Psychology at the Technical University Braunschweig. In her research, Simone Kauffeld focuses on the topics of competences, team and leadership, career and coaching and organization and work design.