Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-24T17:57:33.982Z Has data issue: false hasContentIssue false

Team effectiveness model for science (TEMS): Using a mutual learning shared mindset to design, develop, and sustain science teams

Published online by Cambridge University Press:  21 July 2021

Roger M. Schwarz
Affiliation:
Roger Schwarz & Associates, Inc., Chapel Hill, NC, USA
L. Michelle Bennett*
Affiliation:
Center for Research Strategy, National Cancer Institute, National Institutes of Health, Bethesda, MD, USA
*
Address for correspondence: L. Michelle Bennett, PhD, Center for Research Strategy, National Cancer Institute, National Institutes of Health, 9000 Rockville Pike, Bethesda, MD 20892, USA. Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

In this paper, we introduce the Team Effectiveness Model for Science (TEMS) and describe a multiphase set of interventions for forming a new team or developing an existing team. TEMS uses a shared mutual learning mindset as the model’s central and guiding element. It shows how team mindset leads to behavior and to results and how this affects the characteristics of effective team functioning. TEMS addresses two related questions: What are the variables that contribute to effective teams? and How do the variables need to be designed to make their relevant contributions? Team models often answer the first question without fully answering the second. By addressing three gaps, TEMS contributes to enhancing science team effectiveness. Gap 1 is the absence of explicit core values, assumptions, and norms that serve as the foundation for developing and maintaining science team effectiveness. Gap 2 is the absence of a process for integrating the science and relationship aspects of a science team. Gap 3 is the absence of team processes and structures that are derived from the team’s values, assumptions, and norms. Using TEMS to design new or intervene with existing teams focuses on shifting mindset, developing behavioral skills, and designing processes and structures congruent with the new mindset.

Type
Special Communications
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - SA
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike licence (http://creativecommons.org/licenses/by-nc-sa/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is included and the original work is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use.
Copyright
© National Institutes of Health and Roger Schwarz & Associates, Inc., 2021

Introduction

The nature of scientific problems that researchers are addressing increasingly requires assembling scientists with diverse backgrounds and employing cross-disciplinary approaches to innovatively answer them [Reference Stokols, Misra, Moser, Hall and Taylor1, Reference Thompson Klein2]. Many researchers in the Science of Team Science community have identified salient characteristics that facilitate and/or hinder science team effectiveness [Reference Gray3Reference Bennett and Gadlin5].

In this paper, we introduce the Team Effectiveness Model for Science (TEMS). TEMS is a normative model that integrates each of our separate works [Reference Bennett and Gadlin5Reference Bennett, Marchand and Gadlin8]. The TEMS uses the mutual learning (ML) shared mindset as the model’s central and guiding element. It shows how team mindset leads to behavior and to results and how this affects the characteristics of effective team functioning.

At its essence, TEMS seeks to answer two related questions: (1) what are the variables that contribute to effective teams? and (2) how do each of these variables need to be designed to ensure that each one makes its relevant contribution? Team models often answer the first question without fully answering the second question. Consequently, teams that rely on such models may understand what they need to create, such as a shared vision, mutual trust, or strategies to effectively manage conflict, but do not learn how. For example, managing scientific as well as relationship conflict productively is a key variable in team effectiveness, and a model needs to make explicit the specific values, assumptions, and behaviors that constitute the process for achieving the desired results [Reference Bennett and Gadlin5, Reference Schwarz7].

By answering these two questions, the TEMS model addresses three gaps in the research on science teams in a way that enhance science team effectiveness, including productivity. Gap 1 is the absence of an explicit set of core values, assumptions, and specific norms derived from the values and assumptions that serve as the foundation for developing and maintaining science team effectiveness. Gap 2 is the absence of a process for integrating the science and relationship aspects of a science team. Gap 3 is the absence of team processes and structures that are derived from the team’s values, assumptions, and norms. Gaps 2 and 3 are often result from Gap 1.

Gap 1: The Absence of an Explicit Set of Core Values and Assumptions, and Specific Norms Derived from the Values and Assumptions, for Developing and Maintaining Science Team Effectiveness

Effective teams operate from a shared mindset: a set of core values and assumptions that team members hold and that guide their behavior [Reference Schwarz6, Reference Schwarz7]. Research has identified the value of shared cognitive constructs [Reference Turner, Chen and Danks9] and identified values, attitudes, beliefs, habits of mind such as open-mindedness, curiosity, self-reflectiveness, and non-defensiveness [Reference Stokols10, Reference Argyris and Schön11] that are central to team effectiveness.

Missing is a coherent set of shared values and assumptions that frame how members think about themselves and others when they are engaged in the conduct of science or intrapersonal reflection with or about others and that serve as a team operating system, ensuring that all team functioning is congruent with this mindset. This includes an explicit set of behaviors that are derived from the values and assumptions that: (1) serve as team norms; (2) produce effective behavior under challenging conditions; (3) are specific enough to answer the central question “Exactly what do I say and/or do in this situation”; and (4) can be reliably measured.

Addressing Gap 1

Mutual learning and unilateral control

The TEMS addresses this gap through the ML approach. ML comprises a set of core values and assumptions (what we refer to as mindset) and a set of specific behaviors derived from them that, together, cultivate effective human working relationships (Table 1) [Reference Schwarz6, Reference Schwarz7]. ML is a way of thinking and acting that enables learning with and from others, particularly in challenging situations such as scientific disagreement or difficult interpersonal discussions. The ML core values are used with the behaviors to inherently take full advantage of differences and to create integrative solutions. This is the essence of team science.

Table 1. Mutual learning and unilateral control mindsets and norms [25]

The unilateral control (UC) approach is the contrast of ML (Table 1). UC is rooted in trying to control the outcomes of interactions with others. Under conditions of UC, little learning can occur with and from others because people approach interactions with the mindset “I understand, if you disagree, you don’t. I’m right, if you disagree, you’re wrong. I will win.” This mindset is extremely common when stakes are high, people have strong and different views, and feel threatened in some way. UC makes it difficult for scientists to jointly and productively reflect on their differences and develop integrative solutions that increase team effectiveness. ML addresses this core challenge. Both models are based on the work of Argyris and Schön [Reference Argyris and Schön11Reference Argyris13] and further developed by Argyris and others [Reference Schwarz6, Reference Schwarz7, Reference Argyris, Putnam and Smith14Reference Schwarz16].

Espoused mindset and mindset-in-use

In considering whether and how shared mindset contributes to team effectiveness, it is essential to distinguish between mindset-in-use and espoused mindset [Reference Argyris and Schön11Reference Argyris13]. Mindset-in-use is the set of core shared core values and assumptions that actually guides a team’s thinking, language and behavior, and design. Espoused mindset is the set of values and assumptions the team espouses, which may or may not match the mindset-in-use [Reference Argyris and Schön11Reference Argyris13]. It is common for teams to espouse a ML mindset and have a UC mindset-in-use, especially under challenging conditions.

We think of a team’s mindset-in-use as its shared operating system and the basis for designing and running the applications it needs to accomplish its work including the science and relationship norms, processes, and structures. By definition, a team can only design and, in keeping with the analogy, “run applications” that are compatible with its operating system; in practitioner parlance, how we think is how we lead. For example, imagine that a team espouses the value of curiosity, but when anyone speaks up during team meetings and questions results or interpretations, they are told they “Are wrong” or “Don’t get it.” Here, the espoused value is incongruent with the value-in-use and the behaviors that follow from it. However, when the reaction to questioning results or interpretations is one of curiosity, a desire to understand what leads the person to see it differently and belief that the person has pure motives in raising the topic, then the espoused value, the values-in-use, and the behaviors are congruent.

In general, individuals and teams are unaware of their mindset-in-use, the gaps between it and their espoused mindset, and its effects. That is, until they learn to observe and analyze them. Given that behavior is derived from mindset-in-use, the lack of self-awareness and congruence leads teams to behave in ways that reduce their effectiveness, while not understanding how they are contributing to the reduced effectiveness.

In the TEMS, the team explicitly agrees to use the ML mindset to guide its work together including in establishing the values and assumptions for the conduct of the team science and for building and sustaining the team relationships. This is in contrast to many team cultures which often develop through a combination of implicit and explicit processes.

Mutual learning norms

Team norms are expectations that team members have for each other about how they should act. In the TEMS, the team agrees to use the eight ML behaviors as team norms (see Table 1; see [Reference Schwarz6, Reference Schwarz7] for a more extensive descriptions of the ML behaviors), which put the ML values and assumptions into action.

Because the behaviors are universal, they apply regardless of whether the team is engaged in discussing scientific results, interpretation of data, and what conclusions can be drawn, or whether the team is managing conflict about sharing credit, who should present at the international meeting, or not meeting expectations. Neither the content of a conversation nor the relative authority and technical expertise of members affect how ML is used. The norms increase the team’s ability to solve problems, make decisions, and manage conflict, rather than providing procedural guidance (e.g., start on time and end on time). The team norms are specific enough to enable team members to reliably assess whether they are being used, or not. This differs from team relationship norms such as “treat others with respect,” which are often a mix of values and behaviors, and where the meaning of “respect” may differ among members.

Finally, the mindset and eight behaviors are designed to be self-correcting. By being transparent and curious, and by sharing all relevant information, explaining reasoning and intent, testing assumptions, and focusing on interests, doing all of these jointly, a team increases the probability of detecting and correcting deficiencies in its own effectiveness.

Gap 2: The Absence of a Process for Integrating the Science and Relationship Aspects of a Science Team

The research literature explores how team functioning can increase integrative capacity that improves scientific productivity [Reference Salazar, Lant, Fiore and Salas4]. The methods recommended for collaboration often involve developing a set of agreements regarding numerous issues but without a meta-level set of values and assumptions to ensure that these collaborative solutions are internally consistent and guided by some more foundational agreed upon principles [Reference Bennett and Gadlin5, Reference Bennett, Marchand and Gadlin8, Reference Bennett and Gadlin17].

We use the term team science mindset and norms to refer to the set of values and assumptions that guide the team’s conduct of scientific work and the behavioral expectations regarding that work. Similarly, we use the term team relationship mindset and norms to refer to the set of values and assumptions that guide the team’s relationships and the behavioral expectations regarding the building and sustaining of those relationships.

Addressing Gap 2

The TEMS addresses Gap 2 in three ways. First, it defines three interrelated facets of team results: scientific productivity, working relationships, and individual well-being, with each comprising a number of elements (see Table 2). While the purpose of research teams is to solve a complex problem, the TEMS holds that a team’s scientific productivity cannot be sustainable without creating and maintaining effective working relationships and well-being [Reference Fiore18]. Second, the TEMS explicitly states that for a team to achieve and maintain all three results, it needs to pay continual attention to each.

Table 2. Team effectiveness model for science (TEMS) results

Third, by having agreed to treat the ML mindset as the team’s operating system and the eight behaviors as norms derived from the mindset, the team is well prepared to develop mindsets and norms for the science and relationship aspects that are congruent with, and more contextually specific than, those of ML and that contribute to each of the three results.

This component of the TEMS model cannot be over emphasized. It represents the step where science teams use their ML values, assumptions, and norms to articulate their science and relationship values and assumptions as well as design the norms that derive from them. Essentially, ML provides the fundamental framework of values and assumptions, which, together with the science and relationship values and assumptions, define what kind of culture the team wants to create. Similarly, ML provides the fundamental norms that together with the more focused science and relationship norms, identify how to create the culture.

Integrating science and relationships involves using ML to managing differences within and between them [Reference Bennett and Gadlin17]. It also facilitates integration both within and between the epistemic and social modes of a team [Reference O’Rourke, Crowley, Laursen, Robinson, Vasko, Hall, Vogel and Croyle19]. Together, these include the values and norms, the use of language and communication competence, and create shared meaning, which have been identified as central for integration. Adapting Repko and Szostak [Reference Repko and Szostak20], we define integration as a process by which different values and assumptions, norms, processes and structures, data, tools, methods, and/or theories are synthesized, connected, and/or blended.

Gap 3: Absence of Team Processes and Structures That Emanate from the Team’s Values, Assumptions, and Norms as the Building Blocks

Many team models identify processes and structures that are necessary for team effectiveness. These often include processes for problem-solving, decision-making and conflict management and structures for allocating roles and accountability. Missing from this topic is the premise that “how we think is how we design.” Just as our behavior is a function of our mindset-in-use, so are the team structures and processes they design [Reference Wageman and Gordon21]. Winston Churchill’s statement, “We shape our buildings, and afterwards our buildings shape us,” holds true for teams [22]. Awareness of the values and assumptions that teams embed in their processes and structures, enables design or redesign that facilitates effectiveness.

Addressing Gap 3

The TEMS addresses this gap by making explicit that values, assumptions, and norms are the basic elements of process and structure and by describing how values, assumptions, and norms become embedded in the design of science and relationship processes and structures, which together we refer to as team processes and structures. Science processes and structures address the conduct of science in general as well as the conduct of science for the specific problem the team is exploring. The processes and structures focus on the scientific productivity team result (see Table 3). Relationship processes and structures address universal needs that arise when team members work interdependently. These processes and structures focus on the working relationships and individual well-being team results. Intentional design of science and relationship processes and structures assure that they (1) are congruent with the team’s explicitly agreed to ML, science, and relationship values and assumptions; (2) complement each other; and that (3) together, they facilitate the three team effectiveness results.

Table 3. Team structures, processes, and context

We define a team process as a repeated series of actions involving team members that leads to some result. Science processes may have relationship processes embedded in them because science processes sometimes specify how individuals who are working together in a process communicate, coordinate, and manage conflict that may arise.

Team structures are the relatively stable cycle of events that result from a pattern of repeated interactions among team members [Reference Allport23]. Like process, science structures may have relationship structures embedded in them.

Context represents the structures, processes, and other elements that exist in the team’s environment that have a significant effect on the team and that the team, in some cases, may be able to influence (see Table 3). For science, examples include the promotion and reward system in which they operate [Reference McHale, Ranwala, DiazGranados, Bagshaw, Schienke and Blank24], obtaining needed reagents and equipment, and access to state-of-the-art technologies. For a team whose members represent different organizations, their team functioning context reflects potential influences from all their organizations.

Mutual learning as a reflective, self-correcting process

The TEMS includes a reflective loop to improve team effectiveness. Because this process uses the ML mindset and norms, science teams have the skills to engage in this process at any time in their normal course of work, creating a psychologically safe environment in which to productively address important and challenging issues. As Fig. 1 indicates, any element of the model is relevant and appropriate for reflection and redesign.

Fig. 1. Team effectiveness model for science (TEMS).

Using TEMS to Create a New Team or Develop an Existing Team

In this section, we describe a four-phase intervention, built on TEMS and ML, for forming a new team or improving an existing one. The same set of interventions is used for both new and existing teams, but the order and timing of the interventions may differ. These differences are noted below.

The intervention phases match the steps in the TEMS model (Fig. 1): (1) training to establish individual and shared ML mindsets and skillsets; (2) team developmental facilitation and individual coaching to broaden and deepen ML skillset and mindset, including self-reflection and redesign; (3) team effectiveness consultation to design mindset, norms, structures, and processes for team science and team relationships; and (4) team effectiveness evaluation for feedback and comprehensive reflection and redesign.

The scope of this paper prevents describing in detail the nature of these interventions. Creating a ML team almost always represents a culture change from UC and, by definition, requires changing a team’s shared mindset. Because shared mindsets usually function outside of the awareness of those who hold them, it is very difficult for a team to shift its shared mindset without outside support, to help a team learn to reflect on, analyze, and shift their mindset in real time. The primary focus of these interventions is not increasing knowledge, but rather shifting mindset, developing behavioral skills, and designing processes and structures congruent with ML.

Intervention Phase 1: Training to Develop Individual and Shared Mutual Learning Mindsets and Skillsets

Training enables the team members to (1) identify the UC and ML approaches in real time in themselves and their teammates; (2) begin changing their individual and shared mindsets; (3) begin producing ML behaviors individually and as a team; and (4) begin providing feedback to their teammates in real time to improve individual and team functioning. The team achieves these results through rigorous practice on their real work challenges and feedback from their peers and workshop instructors. A workshop provides the team with enough knowledge and experience to make a relatively informed choice about whether ML is a good fit and worth their commitment.

Intervention Phase 2: Team Developmental Facilitation and Individual Coaching

Team developmental facilitation and individual coaching enable the team and its members to broaden and deepen the ML skillset and mindset. These two interventions occur in parallel and may continue through or restart in later phases depending on the team’s needs.

Team developmental facilitation

Developmental facilitation enables the team to immediately apply and strengthen the ML mindset and skillset to their regular team meetings. Unlike basic facilitation, in which the facilitator’s goal is to lend their expertise to help the team through a particular meeting, in developmental facilitation, the facilitator’s goal is to help the team develop its own expertise and reduce its dependence on help from outside the team [Reference Schwarz7].

In developmental facilitation, a facilitator observes and intervenes with the team during its regularly scheduled meetings as it is solving problems and making decisions on important and challenging issues. Over a series of meetings, the team becomes increasingly self-sufficient at using ML to manage its own process effectively. The team is able to jointly design and move through an agreed-upon agenda efficiently, stay on track, identify untested assumptions and inferences, address differences openly and productively, and solve problems and make decisions that the full team is committed to implementing.

Continual reflection and redesign

Developmental facilitation strengthens the team’s ability to continually reflect on its functioning in real time, redesign the team, and enable it to achieve and maintain the three team effectiveness results. Reflection in real time is a central aspect of ML. Team members develop this skill during phase one, begin to apply it to real-time team issues during their interactions in phase two, and continue to do so throughout the life of the team. This process, which can address any elements of the team, is illustrated by the feedback loops on the right side of Fig. 1.

Individual coaching

Individual coaching provides team members help applying ML to achieve more effective results regarding their particular work challenges. Working with a coach, the team member sets goals, has specific follow-up actions and supports team members in developing skills and mindset to effectively raise issues in the team that were previously undiscussable.

Intervention Phase 3: Team Effectiveness Design

Design consulting empowers the team to design or redesign its team science and team relationships mindsets, norms, structures, and processes. For example, the team agrees on its mission, the tasks on which it will work interdependently as a team, how they will be accountable to each other, how they will manage meetings, and how various kinds of decisions will be made and by whom. All science and relationship processes and structures are designed to be congruent with ML values and assumptions. All interactions employ and strengthen the ML mindset and skillset developed in Phase 1.

Intervention Phase 4: Team Effectiveness Evaluation and Feedback

A team effectiveness evaluation measures each element of the full TEMS model including ML, science, and relationship: (1) mindsets (i.e., values and assumptions); (2) behaviors; (3) structures and processes; (4) context; and (5) each element of the three team results. It enables a team to identify and discuss whether and how each of the elements of the team is contributing to or hindering the team’s overall effectiveness. A survey is conducted a number of months after the team has implemented its agreements from the team effectiveness design session. And, re-evaluation at future time points can help the team assess its progress.

Summary

The TEMS model increases science team effectiveness, including maximally benefiting from disciplinary diversity, by placing the ML shared team mindset and norms as a central and guiding element that integrates the design and functioning of a science team. Creating a team using TEMS requires a multiphase set of interventions to develop the shared ML team mindset and skillset, to design the team science and team relationships mindset and norms, and to design the team structures and processes, all of which contribute to scientific productivity, stronger working relationships, and improved individual well-being.

Disclosures

The authors have no conflicts of interest to declare.

References

Stokols, D, Misra, S, Moser, RP, Hall, KL, Taylor, BK. The ecology of team science: understanding contextual influences on transdisciplinary collaboration. American Journal of Preventive Medicine 2008; 35: S96S115.CrossRefGoogle ScholarPubMed
Thompson Klein, J. Interdisciplinarity: History, Theory and Practice. Detroit MI: Wayne State University Press, 1996.Google Scholar
Gray, B. Enhancing transdisciplinary research through collaborative leadership. American Journal of Preventive Medicine 2008; 35: S124S132.CrossRefGoogle ScholarPubMed
Salazar, MR, Lant, TK, Fiore, SM, Salas, E. Facilitating innovation in diverse science teams through integrative capacity. Small Group Research 2012; 20: 132.Google Scholar
Bennett, LM, Gadlin, H. Collaboration and team science: from theory to practice. Journal of Investigative Medicine 2012; 60: 768775.CrossRefGoogle ScholarPubMed
Schwarz, R. Smart Leaders Smarter Teams: How You and Your Team Get Unstuck to Get Results. San Francisco, CA: Jossey-Bass, 2013.Google Scholar
Schwarz, R. The Skilled Facilitator: A Comprehensive Resource for Consultants, Facilitators, Coaches, and Trainers. 3rd ed. New York, NY: John Wiley & Sons, Ltd, 2017.Google Scholar
Bennett, LM, Marchand, C, Gadlin, H. Collaboration and Team Science: A Field Guide. Bethesda, MD: National Institutes of Health, 2018.Google Scholar
Turner, JR, Chen, Q, Danks, S. Team shared cognitive constructs: a meta-analysis exploring the effects of shared cognitive constructs on team performance. Performance Improvement Quarterly 2014; 27: 83117.CrossRefGoogle Scholar
Stokols, D. Training the next generation of transdisciplinarians – SAGE research methods. In: O’Rourke MO, et al., eds. Enhancing Communication & Collaboration in Interdisciplinary Research. 1st ed. Los Angeles CA: Sage Publications; 2014. 56–81.Google Scholar
Argyris, C, Schön, DA. Theory in Practice: Increasing Professional Effectiveness. 1st ed. San Francisco: Jossey-Bass Publishers, 1974.Google Scholar
Argyris, C, Schön, DA. Organizational Learning: A Theory of Action Perspective. Addison-Wesley Pub. Co., 1978.Google Scholar
Argyris, C. Reasoning, Learning, and Action: Individual and Organizational. 1st ed. San Francisco: Jossey-Bass, 1982.Google Scholar
Argyris, C, Putnam, R, Smith, DM. Action Science: Concepts, Methods, and Skills for Research and Intervention. 1st ed. San Francisco: Jossey-Bass, 1985.Google Scholar
Putnam, R, Smith, DM, MacArthur, P. In: Action Design Workshop Notebook. Action Design; 1992.Google Scholar
Schwarz, RM. The Skilled Facilitator: Practical Wisdom for Developing Effective Groups. San Francisco: Jossey-Bass, 1994.Google Scholar
Bennett, LM, Gadlin, H. Conflict prevention and management in science teams. In Hall KL, Vogel AL, Croyle RT, eds. Strategies for Team Science Success: Handbook of Evidence-Based Principles for Cross-Disciplinary Science and Practical Lessons Learned from Health Researchers. 1st ed. Switzerland: Springer International Publishing; 2019. 295–302.Google Scholar
Fiore, SM. Interdisciplinarity as teamwork: how the science of teams can inform team science. Small Group Research 2008; 39: 251277.CrossRefGoogle Scholar
O’Rourke, M, Crowley, S, Laursen, , Robinson, B, Vasko, SE. Disciplinary diversity in teams: integrative approaches from unidisciplinarity to transdisciplinarity. In: Hall, KL, Vogel, AL, Croyle, RT, eds. Strategies for Team Science Success: Handbook of Evidence-Based Principles for Cross-Disciplinary Science and Practical Lessons Learned from Health Researchers. 1st ed. Switzerland: Springer International Publishing; 2019. 21–46.Google Scholar
Repko, AF, Szostak, R. Interdisciplinary Research: Process and Theory. Thousand Oaks, CA: Sage, 2020.Google Scholar
Wageman, R, Gordon, FM. As the twig is bent: how group values shape emergent task interdependence in groups. Organization Science 2005; 16: 687700.CrossRefGoogle Scholar
International Churchill Society. Famous Quotes and Stories [Internet], 2021. (https://winstonchurchill.org/resources/quotes/famous-quotations-and-stories/)Google Scholar
Allport, FH. A theory of enestruence (event-structure): report of progress. American Psychologist 1967; 22: 124.CrossRefGoogle ScholarPubMed
McHale, SM, Ranwala, D, DiazGranados, D, Bagshaw, D, Schienke, E, Blank, AE. Promotion and tenure policies for team science at colleges/schools of medicine. Journal of Clinical and Translational Science 2019; 3: 245252.CrossRefGoogle ScholarPubMed
The unilateral control and mutual learning models presented here draw on several works. Argyris and Schön [11 above], developed the initial models and labeled them Model I and Model II, respectively. Robert Putnam, Diana Mclain Smith, and Phil Mcarthur, adapted the models and named them unilateral control and mutual learning. The unilateral control values and assumptions and the mutual learning assumptions are from the latter’s work, 1997. (www.actiondesign)Google Scholar
Figure 0

Table 1. Mutual learning and unilateral control mindsets and norms [25]

Figure 1

Table 2. Team effectiveness model for science (TEMS) results

Figure 2

Table 3. Team structures, processes, and context

Figure 3

Fig. 1. Team effectiveness model for science (TEMS).