Challenges and Interpersonal Dynamics During a Two-Person Lunar Analogue Arctic Mission PDF

Summary

This research article discusses the challenges and interpersonal dynamics experienced by a two-person team during a three-month lunar analogue Arctic mission. The study, designed as an analog for NASA's Artemis missions, uses integrated methods to examine these dynamic interactions, focusing on physical and psychosocial challenges, and highlighting the importance of positive relationships for resilience and performance.

Full Transcript

TYPE Original Research
PUBLISHED 30 August 2023
DOI 10.3389/fspas.2023.1184547

Challenges and interpersonal
OPEN ACCESS dynamics during a two-person
EDITED BY
Shanique G. Brown,
Wayne State University, United States
lunar analogue Arctic mission
REVIEWED BY
Chester’s Spell, Pedro Marques-Quinteiro 1*, Andres Käosaar 2,
Rutgers, The State University of New
Jersey, United States
Paola Barros Delben 3, Anders Kjærgaard 4 and Gloria R. Leon 5
Keri L. Heitner, 1
School of Economic Sciences and Organizations, Universidade Lusófona, Lisboa, Portugal, 2TRACE Lab,
Saybrook University, United States University of Central Florida, Orlando, FL, United States, 3Human Factors Lab, Universidade Federal de
*CORRESPONDENCE Santa Catarina, Florianópolis, Brazil, 4Department of Military Psychology, Veteran Centre, Ringsted,
Pedro Marques-Quinteiro, Denmark, 5Department of Psychology, University of Minnesota, Minneapolis, MN, United States
pedro.marques.quinteiro@
ulusofona.pt

RECEIVED 11 March 2023
ACCEPTED 10 August 2023 Introduction: This case study was designed as an analog for aspects of NASA’s
PUBLISHED 30 August 2023
planned Artemis missions to the lunar surface. The specific aims were to examine
CITATION emerged mission challenges and dyadic affective and process dynamics over the
Marques-Quinteiro P, Käosaar A,
Delben PB, Kjærgaard A and Leon GR course of a three-month lunar habitat analog Arctic mission.
(2023), Challenges and interpersonal
dynamics during a two-person lunar Methods: Participants were two men who also had key roles in designing the
analogue Arctic mission. habitat. Pre- and post- expedition interviews were conducted and daily satellite
Front. Astron. Space Sci. 10:1184547. phone messages to mission control over the three-month mission were assessed.
doi: 10.3389/fspas.2023.1184547
An integrated mixed methods approach was used to analyze challenges, group
COPYRIGHT
affect, and group processes, with the goal of furthering the understanding of
© 2023 Marques-Quinteiro, Käosaar,
Delben, Kjærgaard and Leon. This is an coping and psychosocial work experiences in challenging conditions.
open-access article distributed under the
terms of the Creative Commons Results: The findings indicated that different challenges took distinct temporal
Attribution License (CC BY). The use, trajectories across mission phases; based on the relational themes, several
distribution or reproduction in other challenges were identified, primarily physical challenges related to the
forums is permitted, provided the original
author(s) and the copyright owner(s) are experience of coping in an ICE environment, and psychosocial challenges
credited and that the original publication associated with the preparation and execution of mission tasks. Physical
in this journal is cited, in accordance with challenges, positive tone, and action processes were the themes most
accepted academic practice. No use,
distribution or reproduction is permitted connected to each other. To deal with these challenges, the team adapted by
which does not comply with these terms. more frequently engaging in action and transition processes. The specific training
for the mission the participants engaged in, and prior knowledge about each other
enabled team members to deal with mission exigencies while maintaining a
positive outlook.

Discussion: Fostering strong positive relationships was an important mechanism
to build resilience and effective performance while under ongoing, extreme
conditions.

KEYWORDS

teamwork, challenges, lunar, analogue missions, Artic

1 Introduction
Teamwork in isolated, confined, and extreme environments has provided humankind
with unprecedent achievements like reaching the bottom of Mariana’s trench, climbing to
the summit of Everest, and walking on the surface of the Moon. However, the adversity that
characterizes these and other environments poses great challenges to human collaboration
and survival, including the ability to successfully cope and adapt in the face of uncertainty

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(e.g., Bell et al., 2015; Salas et al., 2015). Hence, the extent to which and vice versa, creating a new team-level dynamic system of
humans will become an interplanetary species capable of thriving in human adaptation (Blight and Norris, 2018). Thus, for
a planet with environmental and socio-political conditions that are understanding the mechanisms of adaptation to adversity in ICE
more extreme than Earth conditions, poses unanswered questions environments, a multilevel level approach that focuses both on
and challenges. individual and collective processes needs to be applied.
Psychological research in the polar regions has been carried out Based on the notion of individuals nested in teams, existing team
for more than half-a-century, providing important contributions for adaptation models focus simultaneously on individual- and team-
identifying the drivers of optimal individual and team performance level attributes that enhance adaptation effectiveness–i.e., the extent
in isolated, confined, and extreme environments on Earth and in to which adaptation leads to positive outcomes for individuals and
space (Love and Bleacher, 2013; Tafforin, 2015; Landon et al., 2018; teams, including task related and team related outcomes such as goal
Nicolas et al., 2021; Palinkas and Suedfeld, 2021). Isolated, confined, accomplishment and cohesion (Burke et al., 2006; Christian et al.,
and extreme (ICE) environments provide a natural, living laboratory 2017; Palinkas and Suedfeld, 2021). For example, Blight and Norris
to conduct social sciences research because the contextual features of (2018) introduced a temporally dynamic model of Adaptive Team
these environments make human behaviors more salient and Performance in which individual characteristics (e.g., knowledge
potentially more observable; this facilitates the identification of and abilities) become a team-level variable through emergence and
human and social phenomenon that would be otherwise job design characteristics. Shared mental models, team situation
unobservable (e.g., psychological hibernation Sandal et al., 2018). awareness, and psychological safety were introduced as the three
Research in ICE environments also has the potential to enhance most influential emergent states affecting the adaptation cycle. Later,
existing knowledge about individual and group dynamics during Maynard et al. (2015) introduced a Team Adaptation Nomological
short and long duration space missions (e.g., Leon et al., 2011; Love Network including individual-, team-, and organizational-level
and Bleacher, 2013; Tafforin, 2015; Peuker and Faller, 2021; Palinkas factors feeding into team adaptation processes mediated by
and Suedfeld, 2021; Käosaar et al., 2022). Further, the COVID-19 communication, coordination, cognition, and empowerment.
pandemic has shown how the lessons learned from social sciences These factors indicate the efficacy of team adaptive outcomes,
studies in ICE environments can aid in the development and i.e., team performance, decision effectiveness, affective reactions,
implementation of biological and psychosociological protocols to and creativity.
preserve physical and mental health amidst isolation and Recently, several authors highlighted the importance of
confinement amongst general population (Nash et al., 2022; Van considering the nature of the adaptation triggers, or challenges,
Cutsem et al., 2022). for understanding the factors that predict the success of team
Although there are elements of the space environment that processes and emergent states in driving team adaptation (e.g.,
cannot be reproduced on Earth (e.g., microgravity, exposure to space Maynard et al., 2015). Salas (2017), for example, theorized on how
radiation, distance from Earth), the small number of astronauts the timing of adaptation triggers (i.e., events that once perceived,
available to study, even with the aggregation of data from multiple lead teams to modify their team processes) within the team’s
space missions, encourage the pursuit of research in analogue lifecycle; the duration of the adaptation processes, and the
contexts such as the polar regions (Bruguera et al., 2021). frequency of occurrence of the trigger(s) determine how well
Longitudinal studies of team functioning during polar teams adapt. Alliger et al. (2015) also laid out a set of common
expeditions and confined polar work settings have highlighted team challenges that may disrupt a team’s performance (e.g., time
the importance of appropriate communication, adequate pressure, challenging conditions, and unclear team roles),
decision-making, and conflict resolution to foster positive team emphasizing the importance of considering triggers as part of
outcomes related to effective task performance, team cohesion, the system of teams dealing with adversities.
and satisfaction (Kjærgaard et al., 2013; Corneliussen et al., 2017; Sandal et al. (2006) designated four main categories of inputs
Blackadder-Weinstein et al., 2019). Agreement on the daily affecting adaptation in ICE environments: physical conditions
objectives of the endeavor and congruence between personal and (e.g., temperature and weather conditions), habitability and life
team goals are also factors that have a significant influence on support (e.g., space and noise), crew characteristics (e.g.,
optimal team performance (Kjærgaard et al., 2013; Kjærgaard et al., heterogeneity and member attributes), and mission attributes
2015; Blackadder-Weinstein et al., 2019; Kjærgaard et al., 2022). (e.g., workload and duration). Because of its relevance to ICE
In contrast to analogue studies conducted in confined laboratory environments, and the limited number of empirical studies that
settings, lunar or Mars analogue case studies and research with a explicitly address the role these challenges on individual and team
larger number of participants, carried out in extreme ICE adaptation, the current study assessed how these four main
environments, provide prime conditions to learn how individuals, categories of adaptation challenges proposed by Sandal et al.
dyadic teams and larger groups adapt to realistic extreme and (2006) influence the adaptation dynamics of a two-person
potentially dangerous mission challenges. Although human lunar analogue Arctic mission over the course of a 3-month
adaption takes place on the individual-level, most individuals, period.
especially in extreme contexts, are nested in teams (Golden et al., However, one of the less studied phenomena related to team
2018; Käosaar et al., 2022)—i.e., two or more individuals who adaptation is group affect (Maynard et al., 2015), defined as an
dynamically interact to adapt to the changes in their emergent state of a group driven by both top-down and bottom-up
environment (Mathieu et al., 2019). Therefore, the behaviors, processes influencing affective states such as emotions and moods
affect, and eventual adaptation of the individual is highly (Barsade and Knight, 2015). In the context of team adaptation,
dependent on the respective reactions of their team members, group affect may act as an input (Rico et al., 2020), a boundary

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condition to team adaptation processes, and even function as an Research question 3. What is the relationship between challenges
outcome of team adaptation (Maynard et al., 2015). Existing and affective and behavioral responses over the course of the
research has found significant relationships between affective mission?
states and performance (Barsade and Gibson, 2007), team
efficacy (Kaplan et al., 2013), and reaction to stimuli (SAGA,
2023). Nonetheless, current empirical findings remain insufficient 2 Materials and methods
to make precise statements about causality. The extent to which
individuals and teams engage in collective group processes to adapt 2.1 Mission description
to triggers or challenges during missions in ICE environments likely
will have a positive effect on the individual and on collective affective Data collection was carried out over the course of SAGA’s Space
reactions, with immediate implications for the improvement of the Arctic Moon analogue experiment in NW Greenland, where the
overall team environment (Barsade and Gibson, 2007; Maynard LUNARK habitat was deployed and assembled (see Figure 1). The
et al., 2015). This process, in turn, should minimize team related overriding goal of this case study mission was to serve as an analogue
conflict and other challenges, and therefore enable further for aspects of the planned NASA Artemis missions to the Moon
adaptation (Bell et al., 2019; Larson et al., 2019; Zhang et al., 2021). (Artemis, 2023). The SAGA group designed a prototype lunar habitat
The successful modification of different individual and collective to house a two-person team in an ICE environment as an analogue for
processes has been positively associated with adaptation. Individual the planned Artemis III mission during which a two-person astronaut
psychological adaption, group dynamics, performance, error team will live on the lunar surface for a short period of time. The
management, safety, and individual health and wellbeing, and the specific aims of the case study LUNARK mission were to study the
interplay of these processes, have been identified as determining psychological adaptation of a dyadic team living and working over a 3-
team adaptation outcomes (Sandal et al., 2006; Golden et al., 2018). month period inside a structure specifically designed as a lunar
Situation assessment, plan formulation and execution (Delben et al., habitat. A second aim was to test the adequacy of the habitat,
2020), together with interpersonal processes, coordination, and including infrastructure, materials, habitability, and technology
cognition (Maynard et al., 2015), have been identified as the under extreme environmental conditions (https://saga.dk).
processes driving team adaptation performance. Relevant team The habitat was in NW Greenland near the uninhabited
processes that contribute to adaptation include action settlement of Moriusaq. This Arctic region presents some of
processes–task execution behaviors such as performance Earth’s harshest conditions for life during the winter season
monitoring and backup behaviors; transition processes–task when the mission took place, with challenges such as −40°C
organization behaviors such as mission analysis and goal (104°F) temperatures, hurricane-like wind speeds, extended
specification; and interpersonal processes–which enable positive darkness period, solitude, and the constant threat of polar bears
team member interactions through conflict and affect (SAGA, 2023). The mission lasted for approximately 90 days, during
management (Maynard et al., 2015). Over the last 2 decades, which participants were isolated from the outside world. Three
research findings have demonstrated positive impacts that each critical phases of the mission were designated, each lasting 4 weeks:
of these processes have on teamwork outcomes (e.g., LePine Phase 1—habitat assembly; Phase 2—sunlight; Phase 3—long night
et al., 2008), while also demonstrating that team process (see Figure 2). During Phase 1, team members lived inside a metal
categories have distinct and unique effects on performance container where all relevant equipment, tools, and supplies were
(Mathieu et al., 2019). However, research on team adaptation stored. The objective was to complete the deployment of the
processes in ICE environments, particularly as stated by Maynard LUNARK habitat. The container also served as a storage facility
et al. (2015), remains sparse. during Phases 2 and 3. The second and third phases differed
Therefore, consistent with recent calls for additional studies on primarily in terms of activities during the presence vs. absence of
the temporal and contextual dynamics of teamwork in ICE sunlight. During Phase 2, the team performed several walks around
environments (e.g., Golden et al., 2018; Käosaar et al., 2022), the the habitat to explore the region; during Phase 3, the team did not
current study adopted a temporal, integrative mixed-methods carry out any recreational activities outside of the habitat, although
approach (Paoletti et al., 2021) to characterize the ongoing they still performed daily tasks such as walking to the container for
dynamics of team adaptation processes and affective states of a supplies, chopping ice blocks to melt for water, or repairing any
two-person team as their mission evolved. This study used external equipment. In Phases 2 and 3, the team’s primary tasks
qualitative longitudinal data supplemented by interviews to included the recording of video material to produce a documentary,
investigate the relationships between the environmental and task implement multiple research protocols, maintain the habitat, and
conditions, i.e., challenges, team affect and other adaptation-related text daily messages via satellite to mission control in Denmark.
processes, to shed light on the dynamic process of team adaptation
in an extreme environment. The following research questions were
assessed: 2.2 The LUNARK habitat

Research question 1. What were the challenges that arose during The LUNARK habitat is an origami-like foldable structure made
the mission and how often did they occur? of lightweight solar panels. The habitat was designed and constructed
in Denmark, then loaded into a shipping container and transported
Research question 2. What were the affective and behavioral by ship to the mission site in Greenland. After the habitat was
responses to those challenges and how often did they occur? offloaded, both team members, without any external help, assembled

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FIGURE 1
Image (A) shows the habitat. Image (B) is a top-down schematic of the habitat interior (SAGA, 2023). Image source [SAGA Space Architects],
reproduced with permission.

FIGURE 2
Photos showing the three phases of the mission (SAGA, 2023). Photo (A) regards Phase 1—Habitat assembly. Photo (B) regards Phase 2—Sunlight.
Photo (C) regards Phase 3—Long night. Image source [SAGA Space Architects], reproduced with permission.

the habitat and made it fully operational (Figures 1, 2). The habitat 2.3 Participants and activities
consists of two interior levels. The lower level is divided into two
workspaces, one for each team member, a small galley, and an airlock Participants were self-selected two male Danish architects, ages
with a toilet. The space in the main room floor is 3.57 m2, with two 26 and 24. Both were part of the SAGA Space Architects company.
desks, storage shelves and a 3D printer; the airlock space is 0.80 m2. They had been working together on the development of the habitat
The interior was constructed with materials and surfaces consisting and the mission preparation for over 2 years, and were highly
of natural Earth colors and textures, while the interior contact committed to developing and launching the mission. They also had
surfaces were either textiles, or painted or natural wood. The some practice experience in short duration isolation in a desert
walls were covered with furniture textiles. The upper level had setting. Much like what happens at the International Space Station,
two separate sleep areas and a dynamic circadian rhythm lighting and unlike other polar facilities where the crew is often divided into
system. One sleep pod is 1.53 m2, the other 1.38 m2, providing the scientists who implement research protocols and staff who engage
greatest privacy within the habitat. The acoustically insulated in maintenance and repair, during the LUNARK mission the two
dividing walls and padded exterior walls promoted a feeling of team members were responsible for conducting the research as
protection and safety, according to the habitat designers. The well as maintaining the habitat. They were fully autonomous on-
habitat was specifically designed for this lunar analogue mission, site and had no face-to-face interaction with other humans over
with applications of the design and technology for other structures in the course of the mission. The only exception was a 1-h encounter
ICE environments. with a local resident who brought them via a small boat a needed

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TABLE 1 Coding scheme and frequency.

Category Frequency

Sub-code Pre-mission Phase 1 Phase 2 Phase 3 Post-mission Total Pre/actual
interview interview ratioa
Affective tone Russell (2003) Negative 6 4 11 8 31 60 -

Positive 11 19 35 16 17 98 -

Challenges Sandal et al. (2006) Team 0 1 1 0 5 7 n/a

Habitat 0 1 7 9 6 23 n/a

Health 3 3 5 7 6 24 1.49

Mission 8 7 6 3 19 43 3.73

Physical 2 19 16 12 10 59 0.32

Team processes Maynard et al. Interpersonal 7 0 8 2 11 28 -
(2015)
Action 4 18 17 8 12 59 -

Transition 8 8 4 5 7 32 -

Total 49 80 110 70 124 433 -
a
To compare the proportions between expected challenges and experienced challenges, proportions of total challenges expected/experienced per challenge were calculated. For the ratio,
proportion of expected challenges was divided by the proportion of the same experienced challenge. One equals an exact match between expectations and actual experiences; values < 1 indicate
that the team experienced more of the challenge than expected; values > 1, challenge less than expected. There were no related expectations for Team and Habitat challenges.

piece of equipment. The team engaged in daily phone contact with quantitative elements to analyze and interpret data in a way
mission control in Denmark. The rationale for the choice of a two- that generates results otherwise inaccessible (Paoletti et al.,
person team was its comparability with the number of crew 2021). Examples of integrated mixed methods approaches
members that will live on the lunar surface during the planned include interaction analysis, content analysis, and cluster
Artemis III mission. analysis (Paoletti et al., 2021). In the current study, the focus
was on content and cluster analyses. Content analysis allows the
categorization of large amounts of data in a systematized fashion
2.4 Measures using codes and subcodes generated from existing theory, prior to
performing the coding itself. Cluster analysis enables the grouping
The data analyzed in this study consisted primarily of single of relevant factors by degree of proximity or similarity.
daily short text message sent by the two team members via satellite MAXQDA20 Pro (MAXQDA20 2020) was used to perform
phone, and pre and post mission interviews. The messages data coding and analysis of the daily messages. The data were
contained words, icons, and emoticons to summarize the most analyzed following a two-step approach. First, a focus on the
relevant events, experiences, thoughts, or feelings experienced by overall mission to answer the study’s first two research
the team each day. As an additional data source, a detailed analysis questions related to challenges and affective and behavioral
was carried out of pre-expedition and follow-up semi-structured responses. Next, a focus on the three stages of the mission to
interviews conducted for a separate concurrent LUNARK research answer the study’s third question regarding the frequency of these
project (Kjærgaard et al., 2022). The pre-expedition interview was responses by phases of the mission, and possible relationships
conducted 1 week before the mission, the post-expedition interview, according to phase.
1-week post-mission. The team members were interviewed together The analysis of the daily satellite messages was performed by
and provided a more detailed understanding of the challenges and the first and second authors of this study, taking a two-step
associated affect and processes experienced by the team members. approach. First, each author went through all the daily satellite
messages separately, using the code system shown in Table 1.
Second, the two authors met to discuss the codes they had
2.5 Coding and analytical procedure assigned to different messages, share their individual
interpretations, and reach a consensus. The pre-mission and
An integrated mixed methods approach was adopted in this post-mission interviews were coded by the second author and
case study, defined as an interconnected mix of quantitative and three research assistants, using the same codebook that was used
qualitative characteristics. Beyond classic approaches such as for coding the daily messages (see Table 1). Once the research
triangulation of multiple data sources (e.g., archival data, assistants were familiar with the coding scheme, the pre and
surveys, and interviews), where a qualitative approach is used post-expedition interviews were divided into two parts; the
to support quantitative ones (and vice versa), adopting an second author coded the full interviews, and each assistant
integrated mixed methods approach combines qualitative and coded a third of each interview. As with the daily satellite

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FIGURE 3
Code relations table showing the co-occurrences between pairs of codes. White coloring indicates no co-occurrences; blue coloring indicates
occasional co-occurrences; grey coloring indicates frequent co-occurrences; red coloring indicates highly frequent co-occurrences. “T” stands for tone,
“C” stands for challenges, and “P” stands for processes.

FIGURE 4
Code map showing the association between codes based on frequency of co-occurrences. Thicker lines indicate more co-occurrences between
two codes. Bigger font sizes indicate higher code frequency. Code colors highlight clustering (distance matrix) in such a way that two or more codes with
the same color were assigned to the same cluster. Capital “C” stands for challenges. Capital “T” stands for tone. Capital “P” stands for processes (SAGA,
2023).

messages, agreement meetings were held for each interview to 3 Results
reach full consensus about the codes. In addition, besides
content analyzing our data and in line with the integrative This section allowed for answering Research questions 1 and
mixed methods approached, frequency analysis (Table 1), co- 2 and is organized into six themes: anticipated challenges (Pre-
occurrence tables (Figure 3) and relational graphs (Figure 4) Mission); challenges the team encountered (Challenges); emotional
were generated to visualize the relations between codes using responses to those challenges (Group affect); behavioral responses to
MAXQDA20 Pro. This enabled obtaining additional detailed those challenges (Group processes); integration of challenges, affect,
information about the association between codes and how their and processes (Integration) themes; findings from post-expedition
occurrence changed across mission phases. interview (Post-Mission).

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3.1 Pre-mission wrote on Day 66: “Temperatures are falling fast now, without
sunlight. Today we had -21 C [-6°F], but the windchill effect is
Team members were excited, enthusiastic, and optimistic about -28 C [-18°F]. One month left, it will only get colder.” While
the mission. “It is been a theoretical project for almost 2 years from physical challenges were common, habitat (n = 17), mission (n =
the very early stages. And now we finally... see real physical things 16) and health (n = 15) were less so. Habitat challenges included
and prove that it is going to happen” (P1). Team members mentioned vibrations within the habitat and noise during storms; the
that prior to the LUNARK mission, they had engaged in two short confinement of the habitat (Day 65: “When one works out, the
isolation experiences (2 weeks and 4 weeks) living in a tent in the other sits in his sleeping pod”), and other aspects related to the
desert to gain a better understanding of the exigencies of isolation in hardships of living in a remote and small space (Day 16: “Started
a harsh environment. While this was primarily a solo endeavor, for a melting ice for water. We each use 7.5 L a day here. That’s much less
short period there was an overlap where the two lived together in the than the 105 L an average person uses in DK [Denmark]. Not
tent. From these experiences, both felt they had learned a great deal showering helps”). The challenges associated with mission tasks
about how to adapt to an ICE environment. They also indicated that were primarily related to several problems with the mechanical/
they believed themselves to be resilient enough to be willing to technological part of the habitat and general maintenance work, e.g.,
accept that they can get tired of each other, but still “have mutual on Day 32 the team reported: “Oh and Technology has not been with
respect, and respect each other’s privacy” (P2). us today, lots of challenges.” On one occasion, the team also realized
During the pre-mission interview, team members also they forgot one important piece of equipment, which eventually
acknowledged how they had learned to deal with conflict with ended up being delivered to them by a local (Day 27: “we’d forgotten
each other over the time they had been working together prior to the pump for our algae reactor in DK. Now it finally came. It was a
the mission. P2 stated that they just need to relax a bit to reduce long journey by ship, planes and finally in the boat of an Inuit
tension when in a state of conflict with each other. On the other hunter.”). Interestingly, the highest discrepancy between expected
hand, they also indicated that although they felt prepared, the challenges and actual challenges was for mission challenges, as
LUNARK mission had a lot more at stake than any of their shown in Table 1.
previous experiences: “The weight on our shoulders is definitely Finally, themes associated with health challenges were primarily
more extreme... but it is also more exciting” (P1). P2 stated “We associated with fatigue (Day 12: “Our bodies are getting more tired”)
had to do a crowdfunding campaign... and that means that all our and being ill–both crewmembers fell ill over the course of the
family and friends and people... have invested a little bit in the mission, one team member for a few days. The crew reported
mission. So, it is kind of... we owe it to them”. Furthermore, they very few team challenges that arose because of low morale (Day
indicated that although they knew that missions in ICE environment 37: “Messy surroundings area a symptom of low morale”) and the fact
are dangerous, they did not feel like daredevils—they had gone that some things are difficult to execute as a two-person team–Day 6:
through extensive training about how to handle a rifle, “It was heavy, only two people.”
administering first aid, communications, and other training
procedures, and that training made them feel more confident. 3.2.2 Group affect
Finally, at this early stage, before the mission began, the To capture affective tone, two codes were used following
participants anticipated they would mainly face sleeping Russell (2003): positive tone (n = 55), and b) negative tone (n =
problems and small habitability issues (e.g., leaks in the habitat). 21). Positive tone was the predominant affective state for this
Of interest, P1 indicated that as a coping mechanism, it was mission. The reports reflecting positive tone were primarily
important to have no specific expectations about potential indicative of a prevalent positivity; the team viewed even the
stressors: “I think it is hard to predict really, I try not to really challenges through this lens. For example, on Day 67 there was a
have too much of... an idea in my mind of how it is going to be. problem with a toilet tank due to extremely cold weather. The
Because then you get disappointed”. team reported: “When [P1] found out he looked at me and said:
Urine big trouble.” The way the team member communicated
the problem reflected coping by means of humor, and thus
3.2 Mission maintains a positive attitude. A similar humor theme occurred
in the Day 55 report: “The neighbors did not even complain
3.2.1 Challenges about the music [of yesterday’s party],” or on Day 68: “Oh and
Five different themes were used to capture data associated with today’s update: Still very cold here.”
challenges from the daily messages sent during the mission: 1) Team Many of the reports related to positive tone were also associated
(e.g., low morale amongst the team), 2) mission (challenges with friends and family when, e.g., the team opened care packages
associated with tasks and workload), 3) health (challenges that their loved ones had sent with them to boost morale (Day 59:
associated with physical health), 4) physical (challenges “Words cannot describe how moved and grateful we are”). Finally,
associated with physical environment), and 5) habitability there were several references to salutogenesis, which might help
(challenges associated with the habitat). These challenges were explain the prevalence of positive tone over negative tone. This
previously identified by Sandal et al. (2006). suggests that despite the harshness of the environment and the
As detailed in Table 1, the most prevalent challenge theme general ICE context, the team was resilient in dealing with these
extracted was physical challenges (n = 47). The main specific stressors and tended to enjoy the context (Day 60: “Tomorrow is the
stressors related to physical challenges were the cold, storms, and last day the Sun comes above the horizon. But the days have never
the lack of sunlight from the mid-point of the mission. As the team been more beautiful”).

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The main themes stemming from negative tone were related to two codes occur together. Through classic multidimensional scaling,
missing friends and family, and the feeling of missing out on relational maps in MAXQDA20 display the frequency of occurrence
experiencing life with them, illustrated by this report on Day 68: for each theme, combined with the frequency of co-occurrences in
“Marius from the SAGA team became a dad recently! What else are the text. The closer two themes are on the relational map and the
we missing?.” Another prevalent theme was related to the polar night thicker the line that connects them, the more related they are
that began on Day 61: “We’re entering the dark period of the mission. (Artemis, 2023).
It is both scary and exciting.” Amongst other less frequent themes, The most frequent theme to co-occur with other themes was
the acknowledgement of being in a remote location was captured on positive affective tone, which co-occurred with health challenges
Day 50: “Here, even a small accident is no joke. Who’s gonna help?.” (Day 12: “Our bodies are getting more tired every day [health
The team also reported some form of “ICE blues” or thoughts of challenge]... But morale is top [positive tone]”); physical
home near the end of the mission; Day 84: “As architects we think a challenges (Day 61: “We’re entering the dark period of the
lot about what makes a home, a home. One thing that’s clear now mission [physical challenge]. It is both scary and exciting [positive
more than ever: it is the people;” Day 85: “We’ve been here for such a tone]”); and habitat challenges (D58: “Woke up to a freezing Hab
long time that the outside world seems like a dream. A good dream [habitability challenge]. Never has the bed felt more comfy [positive
that we long to return to.” tone]”). Positive affective tone also co-occurred with action
processes (Day 28: “We are happy to say that the habitat is
3.2.3 Group processes finally alive [positive tone]. Electronics are working well, heating
To capture relevant group processes, Maynard et al. (2015) was and toilet too, not much left [action processes]”). Apart from the co-
followed; three main codes were identified: interpersonal processes occurrence with positive tone, physical challenges also co-occurred
(n = 10), action processes (n = 43), and transition processes (n = 17). also with action processes (Day 69: “We’re going through the hab
The interpersonal processes referred to the activities carried out looking for cold spots and adding extra Armaflex insulation where we
together related to having fun and therefore were mainly oriented can [action processes]. The inside-outside temperature difference is
towards building shared motivation (Day 62 they wrote: “We now 50C [90°F]! [physical challenge]”); and transition processes (Day
celebrated Halloween and our first day of darkness”), boosting 21: “Minus 8C [18°F] today [physical challenge]. Stepping up to
morale and strengthening the social ties between team members warmer gloves from Ewool so our fingers do not go numb when
(Day 55: “Had a slow day on top of last night’s party. Which btw was working outside”). Of interest, team challenges and interpersonal
great. Everyone was dancing.”). Action processes were related to processes were the furthest distance from the denser map region on
tasks and activities focused on the mission, including assembling the right, as well as amongst each other. This finding seems related to
and maintaining the habitat (Day 15: “8 of 15 trusty Spirafix ground the scarce references to any team challenges occurring during the
anchors installed. Each anchor takes up to 3 h for us to hammer into mission as transmitted in the daily-satellite messages by the team.
the freezing ground.”) and conducting research (Day 63: “Testing A close inspection of the map depicted in Figure 4 shows a
some new colors on our circadian lights. We’re both the lab rats and strong association between physical challenges, positive emotions,
the researchers in this experiment. It creates some bias, but also and action processes. This reflects the finding that team members
opportunities!”). The transition processes were primarily oriented often saw the physical challenges of their mission from a positive
towards organizing work and activities and were the most critical outlook. Also, action processes are related to the execution of
during initiating and transition periods of the team mission, e.g., mission plans, including implementing experiments within and
arriving at the site of the mission (Day 3: “We surveyed the area and outside the habitat, hiking and doing documentation. These
found a potential location for the hab! Gentle breeze makes it feel activities provide numerous opportunities to experience positive
colder despite only -1C [34°F]. The Sun skips the horizon.”); the emotions, especially those related to the feeling of awe viewing the
transition from emergency shelter to the habitat (Day 31: (P2) l did landscape, and the achievement of mission-related goals.
not leave the hab at all. Everything appears to be working. We’re
focusing on getting on track with research and documentation.”), and
end of the mission (Day 87: “We have not taken a real shower in 3.3 Follow-up interview: Post-mission
3 months. The list of things we are looking forward to is long.”).
The primary challenge from Phase 1 mentioned in the post-
3.2.4 Visualizing relationships among themes mission interview was the fact that setting up the habitat lasted
To understand the connections between the challenges 30 days instead of 6 days as planned. This time delay had three main
encountered by the team and the affective and process-related effects: intense chronic stress because of uncertainty whether they
reactions to those challenges during the mission, a relational map would eventually be able to set up the habitat and continue with the
of the codes was generated (Figure 3). In MAXQDA20, this is mission; sustained workload over the period of setting up the
achieved by estimating a similarity matrix between codes, which is habitat; time pressure stemming from the lost days. The latter
then converted into a distance matrix (Figure 4). For the conversion, affected the entire mission regarding other projects and goals
the column sums are calculated first, so each code is checked to see that the team had to accomplish, e.g., installing and testing the
how often it occurs together with any other code. The maximum of solar panels because at a specific point in the mission, there would
these column sums is determined and defined as the maximum not be any more sunlight. As P2 explained: “The biggest pressure...
possible similarity. In each cell, the similarity of two codes is was not so much that... it had to be 6 days. It was more that... we
subtracted from this maximum. If 0 is obtained, this means that had done so much work in the past 2 years–how much of the value
two codes always happen together. The greater the distance, the less disappeared by not being there for the 20 extra days... I was stressed

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Marques-Quinteiro et al. 10.3389/fspas.2023.1184547

about the idea of losing that value of the mission.” The main reason the primary outcome of these stressors was mediocre energy levels.
for the delay was the challenging weather conditions and fatigue However, they also indicated that toward the end of the mission, the
resulting from the workload—“It is hard to explain exactly why effect of the end approaching had an opposite effect on each of
things were going so slow... We were fatigued. And the cold and them–for P1, more energy “just from the knowledge of the mission
harsh climate just slows things down. Because we could unfold the being over soon;” on the other hand, P2 said: “I felt that [motivation]
habitat in... 2 days... in the workshop”. Both team members dropping and my commitment to the expedition decreased a bit. I
indicated that acceptance was the primary way to deal with the started to let go in the last week” (P2).
immense stress and pressure from this situation. In addition, Team members stated that looking back, they were surprised
maintaining high moral and humor, being optimistic and trying how well the mission proceeded, how normal they felt throughout
to deal with the situation in a rationale way were mentioned “just the mission, and the fact that they were able to deal with each other
make sure that I put as much work as I can into every day without... so well over the entire time. Moreover, they found that their ability
doing anything stupid or exerting myself too much” (P1). to work together increased over the mission, since “we kind of ironed
The single most stressful event that team members indicated out wrinkles... So, I felt coming out of the expedition, we are working
from Phase 2 was discovering large polar bear footprints outside of even better together”. They also indicated that this process of ‘ironing
their habitat. They spent a large portion of the day searching the area out the wrinkles’ was quite intentional–e.g., one evening they threw a
for the bear, rifles in hand, to be sure that the bear was not in the area party and drank alcohol; they found that this was quite effective in
so they could work outdoors in peace and safety—“And we were reducing stress/tension.
between the building, and you were wondering what was behind the
corner... That was the most stressful part” (P2). Regarding coping
with this stressor, P2 stated: “There was not that much to do... You 4 Discussion
kind of just had to deal with it,” and then added: “That was the only
moment in the entire expedition where I was thinking–I wish I was This investigation adopted an integrated mixed method
not here right now”. approach to characterize the challenges, group affect, and
For Phase 2, the main stressors mentioned by P2 were the adaptation processes experienced by a two-man team during a 3-
indoor climate and the effect it had on his sleep. Experiencing a month lunar analogue mission high above the Arctic circle in
first strong storm was highly stressful because they did not know Greenland. The research questions included the quantification of
how durable their habitat was. In addition, the low the challenges that occurred, how often they occurred, the affective
communication bandwidth the team had for contacting and and behavioral responses to those challenges, and the relationship
getting information from mission support personnel was a between challenges and affective and behavioral responses over the
chronic stressor for the team throughout the mission. For P1, course of the mission.
sleep problems were a major stressor; despite tinkering with Our findings from this case study indicated that the expectations
different habits (e.g., not drinking coffee) and trying to both team members had about the mission did not fully align with
understand the issue, he felt that sleep problems clearly how events proceeded. Different challenges took distinct temporal
affected his performance. Both team members also mentioned trajectories across the mission phases; physical and habitat
several smaller stressors (e.g., lack of privacy, hearing the other challenges were the most frequent and in which changes across
person snore during night), but indicated that instead of letting mission phases were highly significant. One of the biggest challenges
the small irritations affect them, they kept a positive attitude and mentioned was the extended time and exhausting nature of
worked actively on not getting irritated. This suggests why there assembling the habitat because of the extreme environmental
were so few references to team challenges throughout the conditions in which they were immersed. The team did not
mission, and why humor often showed in the team satellite expect this, as they were not aware of the extent to which cold
messages when they made references to challenges that were temperatures can damage electronic devices. Because of these initial
affecting mission performance and team wellbeing. It also is challenges, they had to exert much greater effort to successfully
consistent with the positive relationship between interpersonal accomplish their tasks. When they finally entered the habitat, they
processes and team challenges, reinforcing the idea expressed were more physically tired than they expected; in addition, they both
here that team members actively adopted humor as a potent were experiencing a high level of stress since they were 3-weeks
affect management strategy to resolve tension and preserve a behind schedule, given all the technical and scientific activities that
positive relationship with each other. were planned for the mission.
For Phase 3, the biggest stressor indicated was the time pressure The team adapted to these challenges by more frequently
resulting from the approaching end of the mission. They explained engaging in action and transition processes–they changed how
that they had lots of documentation (e.g., pictures and films) they coordinated tasks, monitored their own performance, and
planned, a film project they had promised to carry out, and frequently provided back-up and support to each other. Team
procedures they wanted to test out about the habitat; however, at members adjusted mission plans across mission stages and
the same time, they had to continuously fix and maintain the habitat. therefore exhibited high adaptability across the mission (Anglin
Dealing with the stressors related to low bandwidth communication and Kring, 2016). One important factor that may have contributed
such as receiving instructions very slowly, along with perceptions of to this adaptability was that both team members were prepared to
time pressure, feelings of stress became more pronounced. These experience the unexpected, and continuously adapt (LePine, 2003;
factors may have had an influence on the continuous increase in Maynard et al., 2015). The challenges associated with the
health challenges towards the end of the mission. In the team’s view, deployment to the Arctic site and the longer than expected time

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to prepare the habitat supports comments by Harris et al. (2023) despite quite significant and some occasional setbacks (e.g., five
regarding the challenges construction teams deployed to the lunar times longer habitat assembly phase than expected; polar bear visit;
surface will face. sleep problems; disagreements about work schedules and
The study findings also demonstrated that the relationship allocations; illness) the team adapted to the challenges and
between physical and habitat challenges, and action and successfully completed the mission.
transition processes, were central to the mission dynamics, as
highlighted in the code map (Figure 4). This is consistent with
the teamwork literature indicating that action and transition 4.1 Limitations and future directions
processes are particularly important to address regarding task-
related problems such as continuing changes in task and Conducting teamwork in ICE environments is methodologically
environmental conditions (e.g., Mathieu et al., 2019; Connaboy challenging, primarily because study participants are not always
et al., 2020; Schmutz et al., 2022). Our findings confirmed accessible or cooperative; gathering enough data to perform sound
previous studies showing that teams engaged in interpersonal statistical analysis is contingent on technology and participants’
processes more frequently when there also were team challenges motivation and the location of research sites (Palinkas and Suedfeld,
(e.g., Maynard et al., 2015). Other research in ICE environments has 2021). As a result, researchers may need to compromise
shown that effective team performance is associated with team methodological rigor in the face of the operational constraints of
members engaging in interpersonal interactions focused on the mission and the research environment (Bell et al., 2019).
building motivation, providing emotional support, and Although in the current study these challenges were dealt with
importantly, managing and resolving conflict (e.g., Sandal et al., by adopting an integrated mix-method, multi-source approach, this
2006; Golden et al., 2018). Positive and satisfying interpersonal study is not without limitations. The main data analysis was
interactions can then facilitate the process of solving team performed using the daily satellite messages sent by the team.
challenges, preserving group cohesion, and enhancing positive This enabled the collection of nearly 90 daily messages that were
affect (Atlis et al., 2004; Kjærgaard et al., 2013; Corneliussen content analyzed; however, the number of words in each message
et al., 2017; Bell et al., 2019). was short (±20 words on average). This precluded performing an in-
Fostering strong positive relationships is an important depth examination of daily information, as well as carrying out
mechanism to build resilience and effective performance quantitative analyses that would consider the nested structure of our
while living and working in an ICE environment (Kahn and data, since our sample size was N = 1 team (e.g., multilevel analysis;
Leon, 1994). Team members thoroughly engaged in pleasant Schmutz et al., 2022). Ideally, future studies in similar conditions
activities that fostered working together cooperatively and would benefit from larger sample sizes, as well as enrich temporal
enabled their relationship to recover and improve after a data collection by adding at least one specific time per week during
conflict episode. They maintained a positive mental attitude, which participants could provide longer mission logs.
learned from their experiences when there were differences of Further, the N of 2 in our case study was deliberately chosen
opinion, moved on, and continued working together to as an analogue for the two-person astronaut crew planned to live
accomplish the required tasks. This ability to maintain a and work on the lunar surface for a short duration during the
positive working relationship was achieved in part because Artemis III mission. (The Artemis III mission plans to have two
the teammates were a consolidated team before their astronauts deployed on the surface of the Moon while two other
departure to Greenland, as highlighted through their pre- astronauts will orbit the Moon during this time period).
mission interview (e.g., Mathieu et al., 2019). They began Analogue research supported by national space agencies have
planning and working on the LUNARK project together well typically consisted of a relatively small number of
before the mission commenced, had similar expectations about participants—crews of 4–6 individuals, to be consistent with
the process of the mission, including how their relationship the crew numbers currently on the International Space Station
would unfold, and were highly motivated for success. These or planned for future space missions (e.g., the HERA, HI-SEAS
factors point to the strong commitment they had towards each and NASA-Roscosmos SIRIUS missions; Marcinkowski et al.,
other as a team and the project, including several clearly shared 2021; Anderson et al., 2016; https://www.nasa.gov). Therefore,
goals. The teammates also had well-defined boundaries, since following the Artemis III analogue, there were only two
they knew they could only count on each other while in participants in this study, which precluded the evaluation of
Greenland, even though each team member had the relevant social processes such as the role that diversity faultlines
necessary knowledge, skills, and abilities to perform the that might have had an influence on in shaping the formation of
individual and collective tasks. This competence was subgroups (Lau and Murnighan, 1998), and the emergence of
achieved through multiple training activities in which they group conflict during missions (e.g., Burke and Feitosa, 2015;
engaged in. Finally, the team was cohesive; both team Larson et al., 2019; Marcinkowski et al., 2021). In sum, despite
members agreed that they would work together to manage the uniqueness of the research context and the analogue mission
the tensions that could arise between them. In so doing, the in which the participants were involved, this study had one
team established an informal team-charter that clarified goals, single team as the sample. Therefore, the aggregation of data
roles, norms, and expectations (Mathieu and Rapp, 2009). from a large number of N of 2 studies that follow the paradigm of
Overall, our findings demonstrated that the team achieved its the current study is required in order for the findings obtained to
main performance goals, i.e., evaluate the functioning of the habitat, be generalized to future missions and to other ICE
carry out other tasks, and complete a 3-month mission. Indeed, environments.

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Marques-Quinteiro et al. 10.3389/fspas.2023.1184547

5 Conclusion publication of any potentially identifiable images or data included
in this article.
Effective teamwork during long-duration space missions is
paramount for the success of future space exploration as well as
the performance of activities in ICE environments on Earth. As an Author contributions
example, the fact that the assembly of the habitat was slower than
expected raises the issue of whether some type of delay could happen PM-Q, AKä, and PD wrote the manuscript; PM-Q and AKä
during a future space mission, and how the crew would deal with this conducted the data analyses; AKj conducted and compiled the
delay. Hence, this study provides an in-depth account of how interviews; GL provided revisions to the paper. All authors
different challenges emerged across mission stages, and the contributed to the article and approved the submitted version.
behavioral and affective responses to those challenges that
enabled individuals and crews to adapt successfully. The findings
of this study therefore are relevant not only for personnel on space Acknowledgments
missions (e.g., astronauts; mission control managers), but also for
polar expeditioners, submarine crews, mountaineers and other The research team thanks SAGA Space Architects for
teams functioning in ICE environments. Adaptation is not only supporting data collection during their mission in Greenland and
one’s ability to cope and accept their environment, but rather the the research assistants at UCF, Laura Toro, Sarah Thomas, Sesha
motivation and capacity to anticipate and positively react to the Kohl-Fink, and Enzan Azari.
challenges that otherwise would negatively impact mission success.

Conflict of interest
Data availability statement
The authors declare that the research was conducted in the
The raw data supporting the conclusion of this article will be absence of any commercial or financial relationships that could be
made available by the authors, without undue reservation. construed as a potential conflict of interest.

Ethics statement Publisher’s note
Ethical review and approval was not required for the study on All claims expressed in this article are solely those of the authors and
human participants in accordance with the local legislation and do not necessarily represent those of their affiliated organizations, or
institutional requirements. The patients/participants provided their those of the publisher, the editors and the reviewers. Any product that
written informed consent to participate in this study. Written may be evaluated in this article, or claim that may be made by its
informed consent was obtained from the individual(s) for the manufacturer, is not guaranteed or endorsed by the publisher.

References
Alliger, G. M., Cerasoli, C. P., Tannenbaum, S. I., and Vessey, W. B. (2015). Team Blackadder-Weinstein, J., Leon, G. R., Norris, R. C., Venables, N. C., and Smith, M.
resilience: how teams flourish under pressure. Organ. Dyn. 44 (3), 176–184. doi:10.1016/ (2019). Individual attributes, values, and goals of an all-military women Antarctic
j.orgdyn.2015.05.003 expedition. Aerosp. Med. Hum. Perform. 90 (1), 18–25. doi:10.3357/amhp.5248.2019
Anderson, A. P., Fellows, A. M., Binsted, K. A., Hegel, M. T., and Buckey, J. C. (2016). Blight, S., and Norris, K. (2018). Positive psychological outcomes following Antarctic
Autonomous, computer-based behavioral health countermeasure evaluation at HI- deployment. Polar J. 8 (2), 351–363. doi:10.1080/2154896X.2018.1541552
SEAS Mars analog. Aerosp. Med. Hum. Perform. 87 (11), 912–920. doi:10.3357/AMHP.
Bruguera, M. B., Fink, A., Schröder, V., Bermudez, S. L., Dessy, E., van den Berg, F. P.,
4676.2016
et al. (2021). Assessment of the effects of isolation, confinement, and hypoxia on
Anglin, K. M., and Kring, J. P. (2016). Lessons from a space analog on adaptation for spaceflight piloting performance for future space missions-The SIMSKILL experiment
long-duration exploration missions. Aerosp. Med. Hum. Perform. 87 (4), 406–410. in Antarctica. Acta Astronaut. 179, 471–483. doi:10.1016/j.actaastro.2020.11.019
doi:10.3357/AMHP.4489.2016
Burke, C. S., and Feitosa, J. (2015). Team culture issues for long-duration exploration
Artemis (2023). National aeronautics and space administration. Available at: https:// missions. Houston, TX: Johnson Space Center.
www.nasa.gov/specials/artemis/ (Accessed July 23, 2023).
Burke, C. S., Stagl, K. C., Salas, E., Pierce, L., and Kendall, D. (2006). Understanding
Atlis, M. M., Leon, G. R., Sandal, G. M., and Infante, M. G. (2004). Decision processes team adaptation: A conceptual analysis and model. J. Appl. Psychol. 91 (6), 1189–1207.
and interactions during a two-woman traverse of Antarctica. Environ. Behav. 36 (3), doi:10.1037/0021-9010.91.6.1189
402–423. doi:10.1177/0013916503262217
Christian, J. S., Christian, M. S., Pearsall, M. J., and Long, E. C. (2017). Team
Barsade, S. G., and Gibson, D. E. (2007). Why does affect matter in organizations? adaptation in context: An integrated conceptual model and meta-analytic review.
Acad. Manag. Perspect. 21 (1), 36–59. doi:10.5465/amp.2007.24286163 Organ. Behav. Hum. Decis. 140, 62–89. doi:10.1016/j.obhdp.2017.01.003
Barsade, S. G., and Knight, A. P. (2015). Group affect. Annu. Rev. Organ. Psychol. Connaboy, C., Sinnott, A. M., LaGoy, A. D., Krajewski, K. T., Johnson, C. D., Pepping,
Organ. Behav. 2 (1), 21–46. doi:10.1146/annurev-orgpsych-032414-111316 G. J., et al. (2020). Cognitive performance during prolonged periods in isolated,
confined, and extreme environments. Acta Astronaut. 177, 545–551. doi:10.1016/j.
Bell, S. T., Brown, S. G., Abben, D. R., and Outland, N. B. (2015). Team composition
actaastro.2020.08.018
issues for future space exploration: a review and directions for future research.
Aerosp. Med. Hum. Perform. 86 (6), 548–556. doi:10.3357/AMHP.4195.2015 Corneliussen, J. G., Leon, G. R., Kjærgaard, A., Fink, B. A., and Venables, N. C. (2017).
Individual traits, personal values, and conflict resolution in an isolated, confined,
Bell, S. T., Brown, S. G., and Mitchell, T. (2019). What we know about team dynamics
extreme environment. Aerosp. Med. Hum. Perform. 88 (6), 535–543. doi:10.3357/
for long-distance space missions: a systematic review of analog research. Front. Psychol.
AMHP.4785.2017
10, 811. doi:10.3389/fpsyg.2019.00811

Frontiers in Astronomy and Space Sciences 11 frontiersin.org
Marques-Quinteiro et al. 10.3389/fspas.2023.1184547

Delben, P. B., Cruz, R. M., de Melo, G. C., and de Wit, P. (2020). Pesquisa e Mathieu, J. E., and Rapp, T. L. (2009). Laying the foundation for successful team
intervenção psicológica no programa antártico brasileiro: perspectivas metodológicas. performance trajectories: the roles of team charters and performance strategies. J. Appl.
Av. Psicol. Latinoam. 38 (2), 1–17. doi:10.12804/revistas.urosario.edu.co/apl/a.7030 Psychol. 94 (1), 90–103. doi:10.1037/a0013257
Golden, S. J., Chang, C. H., and Kozlowski, S. W. (2018). Teams in isolated, confined, Maynard, M. T., Kennedy, D. M., and Sommer, S. A. (2015). Team adaptation: a
and extreme (ICE) environments: review and integration. J. Organ. Behav. 39 (6), fifteen-year synthesis (1998–2013) and framework for how this literature needs to
701–715. doi:10.1002/job.2288 “adapt” going forward. Eur. J. Work Organ. Psychol. 24 (5), 652–677. doi:10.1080/
1359432X.2014.1001376
Harris, K. M., Stankovic, A., Thoolen, S., Strangman, G., Caldwell, B., and Robinson,
S. K. (2023). Team dynamics and collaborative problem-solving for lunar construction: MAXQDA (2020). MAXQDA 2020 Manual. Available at: https://www.maxqda.com/
lessons from complex construction scenarios on earth. Hum. Factors 1, download/manuals/MAX2020-Online-Manual-Complete-EN.pdf.
187208221148610–187208221148617. doi:10.1177/00187208221148610
Nash, M., Leane, E., and Norris, K. (2022). It’s just that uncertainty that eats away at
Kahn, P. M., and Leon, G. R. (1994). Group climate and individual functioning in an people: antarctic expeditioners’ lived experiences of COVID-19. PLoS One 17 (11),
all-women antarctic expedition team. Environ. Behav. 26, 669–697. doi:10.1177/ e0277676. doi:10.1371/journal.pone.0277676
0013916594265004
Nicolas, M., Martinent, G., Suedfeld, P., Palinkas, L., Gaudino, M., and Marvin, G.
Käosaar, A., Marques-Quinteiro, P., and Burke, S. (2022). Fantastic teams and where (2021). The tougher the environment, the harder the adaptation? A psychological point
to find them: understanding team processes in space and analog environments through of view in extreme situations. Acta Astronaut. 187, 36–42. doi:10.1016/j.actaastro.2021.
the IMOI framework. Team Perform. Manag. Int. J. 28 (3/4), 109–124. doi:10.1108/ 05.045
TPM-02-2021-0012
Palinkas, L. A., and Suedfeld, P. (2021). Psychosocial issues in isolated and confined
Kaplan, S., LaPort, K., and Waller, M. J. (2013). The role of positive affectivity in team extreme environments. Neurosci. Biobehav. Rev. 126, 413–429. doi:10.1016/j.neubiorev.
effectiveness during crises. J. Organ. Behav. 34 (4), 473–491. doi:10.1002/job.1817 2021.03.032
Kjærgaard, A., Leon, G. R., and Fink, B. A. (2015). Personal challenges, Paoletti, J., Bisbey, T. M., Zajac, S., Waller, M. J., and Salas, E. (2021). Looking to the
communication processes, and team effectiveness in military special patrol teams middle of the qualitative-quantitative spectrum for integrated mixed methods. Small
operating in a polar environment. Environ. Behav. 47, 644–666. doi:10.1177/ Group Res. 52 (6), 641–675. doi:10.1177/1046496421992433
0013916513512834
Peuker, A. C. W. B., and Faller, S. (2021). “Avaliação de fatores de riscos psicossociais
Kjærgaard, A., Leon, G. R., and Chterev, K. (2022). Team effectiveness and person- em ambientes Isolados, Confinados e Extremos (ICE),” in Avaliação psicológica dos
environment adaptation in an analog lunar habitat. Aerosp. Med. Hum. Perform. 93 (2), fatores psicossociais do trabalho: Teoria e prática (Brasil: Editora Vetor).
70–78. doi:10.3357/amhp.5983.2022
Rico, R., Gibson, C., Sanchez-Manzanares, M., and Clark, M. A. (2020). Team
Kjærgaard, A., Leon, G. R., Venables, N. C., and Fink, B. A. (2013). Personality, adaptation and the changing nature of work: lessons from practice, evidence from
personal values and growth in military special unit patrol teams operating in a polar research, and challenges for the road ahead. Aust. J. Manag. 45 (3), 507–526. doi:10.
environment. Mil. Psychol. 25, 13–22. doi:10.1037/h0094753 1177/0312896220918908
Landon, L. B., Slack, K. J., and Barrett, J. D. (2018). Teamwork and collaboration in Russell, J. A. (2003). Core affect and the psychological construction of emotion.
long-duration space missions: going to extremes. Am. Psychol. 73 (4), 563–575. doi:10. Psychol. Rev. 110 (1), 145–172. doi:10.1037/0033-295x.110.1.145
1037/amp0000260
SAGA (2023). Space Architects. Available at: https://saga.dk.
Larson, L., Wojcik, H., Gokhman, I., DeChurch, L., Bell, S., and Contractor, N. (2019).
Salas, E., Tannenbaum, S. I., Kozlowski, S. W., Miller, C. A., Mathieu, J. E., and
Team performance in space crews: houston, we have a teamwork problem. Acta
Vessey, W. B. (2015). Teams in space exploration: a new frontier for the science of
Astronaut. 161, 108–114. doi:10.1016/j.actaastro.2019.04.052
team effectiveness. Curr. Dir. Psychol. Sci. 24 (3), 200–207. doi:10.1177/
Lau, D. C., and Murnighan, J. K. (1998). Demographic diversity and faultlines: the 0963721414566448
compositional dynamics of organizational groups. Acad. Manag. Rev. 23 (2), 325–340.
Sandal, G. M., Leon, G. R., and Palinkas, L. (2006). Human challenges in polar and
doi:10.5465/amr.1998.533229
space environments. Rev. Environ. Sci. Bio/Technology 5, 281–296. doi:10.1007/s11157-
Leon, G. R., Sandal, G. M., Fink, B., and Ciofani, P. (2011). Positive experiences and 006-9000-8
personal growth in a two-man North Pole expedition team. Environ. Behav. 43,
Salas, E. (2017). “It is about time: temporal considerations of team adaptation,” in
710–731. doi:10.1177/0013916510375039
Team dynamics over time (Bingley: Emerald Publishing Limited), 29–49. doi:10.1108/
LePine, J. A., Piccolo, R. F., Jackson, C. L., Mathieu, J. E., and Saul, J. R. (2008). A S1534-085620160000018002
meta-analysis of teamwork processes: tests of a multidimensional model and
Sandal, G. M., van deVijver, F. J., and Smith, N. (2018). Psychological hibernation in
relationships with team effectiveness criteria. Pers. Psychol. 61 (2), 273–307. doi:10.
Antarctica. Front. Psychol. 9, 2235. doi:10.3389/fpsyg.2018.02235
1111/j.1744-6570.2008.00114.x
Schmutz, J. B., Marques-Quinteiro, P., Eppich, W. J., Antino, M., and Kelman, I.
LePine, J. A. (2003). Team adaptation and postchange performance: effects of team
(2022). “Dealing with antarcticness: the ABC of effective antarctic teams,” in
composition in terms of members’ cognitive ability and personality. J. Appl. Psychol. 88
Antarcticness. Editor I. Kelman (China: UCL Press).
(1), 27–39. doi:10.1037/0021-9010.88.1.27
Tafforin, C. (2015). Confinement vs. isolation as analogue environments for Mars
Love, S. G., and Bleacher, J. E. (2013). Crew roles and interactions in scientific space
missions from a human ethology viewpoint. Aerosp. Med. Hum. Perform. 86 (2),
exploration. Acta Astronaut. 90 (2), 318–331. doi:10.1016/j.actaastro.2011.12.012
131–135. doi:10.3357/amhp.4100.2015
Loewenstein, G., and Lerner, J. S. (2003). “The role of affect in decision making,” in
Snijders, T. A. B., and Bosker, R. J. (2012). Multilevel analysis: an introduction to basic
Handbook of affective sciences. Editor R. J. Davidson, K. R. Scherer, and H. H. Goldsmith
and advanced multilevel modeling. London, United Kingdom: Sage.
(Oxford, United Kingdom: Oxford University Press), 619–642.
Van Cutsem, J., Abeln, V., Schneider, S., Keller, N., Diaz-Artiles, A., Ramallo, M. A.,
Marcinkowski, M. A., Bell, S. T., and Roma, P. G. (2021). The nature of conflict for
et al. (2022). The impact of the COVID-19 lockdown on human psychology and
teams in isolated, confined, and extreme environments. Acta Astronaut. 181, 81–91.
physical activity; a space analogue research perspective. Int. J. Astrobiol. 21 (1), 32–45.
doi:10.1016/j.actaastro.2021.01.004
doi:10.1017/S1473550421000409
Mathieu, J. E., Gallagher, P. T., Domingo, M. A., and Klock, E. A. (2019).
Zhang, Z., Yan, G., Sun, C., and Saklofske, D. H. (2021). Who will adapt best in
Embracing complexity: reviewing the past decade of team effectiveness research.
Antarctica? Resilience as mediator between past experiences in Antarctica and
Annu. Rev. Organ. Psychol. Organ. Behav. 6, 17–46. doi:10.1146/annurev-
present well-being. Personality Individ. Differ. 169, 109963. doi:10.1016/j.paid.
orgpsych-012218-015106
2020.109963

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