Blended Learning Training for Mentors of STEM Team
Competitions
Sharon M. Locke
1
, Susan L. Thomas
2
, Stephen Marlette
3
, Georgia L. Bracey
1
, Gary Mayer
4
,
Jerry B. Weinberg
4
, Janet K. Holt
5
and Bradford R. White
5
1
Center for STEM Research, Education, and Outreach, Southern Illinois University Edwardsville,
Campus Box 2224, Edwardsville, Illinois, U.S.A.
2
Office of Academic Affairs, Truman State University, 100 East Normal Avenue, Kirksville, Missouri, U.S.A.
3
Department of Curriculum and Instruction, Southern Illinois University Edwardsville, Edwardsville, Illinois, U.S.A.
4
Department of Computer Science, Southern Illinois University Edwardsville, Edwardsville, Illinois, U.S.A.
5
Illinois Education Research Council, Southern Illinois University Edwardsville, Edwardsville, Illinois, U.S.A.
Keywords: Blended Learning, Mentoring, Robotics, K-12 Education, Self-Efficacy, STEM.
Abstract: This paper describes the findings of a research study of a blended-learning approach to train mentors of
teams in the Botball® Educational Robotics Program. Botball is an international team-based robotics
competition for secondary students designed to build skills in computer programming, robotics, teamwork,
and problem solving. For this study, we recruited new teams comprising 8-10 middle school students per
team and a mentor. Teams were randomly assigned to one of three treatment groups or a control group.
Mentors of teams in the experimental groups received training in one of three types of mentor practices: best
practices, mentoring for self-efficacy, or a combination of best practices and self-efficacy. The training
format consisted of web-based self-paced tutorials, a face-to-face workshop, and webinars. Dependent
variables were student post-test scores on three assessments: Efficacy for Science-Related Jobs, STEM
Achievement-Related Choices, and STEM Self-Efficacy. A priori statistical analyses showed no difference
between the groups; however, post hoc analyses showed that the use of self-efficacy techniques was
positively related to the three dependent measures. Post-competition surveys of mentor practices indicated
that students in the treatment groups did not appear to receive distinctly different treatments, revealing some
of the potential challenges of the blended learning approach for professional development of teacher-
mentors.
1 INTRODUCTION
Science and engineering competitions offer the
potential to generate interest in STEM (science,
technology, engineering, and mathematics) among
K-12 students (Dabney et al., 2012), identify and
develop STEM talent and influence choice of
postsecondary major (Sahin, 2013), and foster
participation by historically underrepresented groups
(Alvarez et al., 2010). Existing competitions vary in
scope, format, and learning goals; some of the most
popular range from academic Olympiads (e.g.,
Science Olympiad), to math contests (e.g.,
MATHCOUNTS), to science fairs (e.g., Intel
International Science and Engineering Fair, Google
Science Fair), to robotics competitions (e.g.,
FIRST
®, Botball®, VEX®). Each of these activities
involves a mentor, often a school teacher, who
guides a student or group of students to successfully
complete a project or intense program of study in
preparation for a competition day. In addition to
aiming for high academic performance, mentors who
work with groups of students must manage team
dynamics so as to ensure a positive experience for
all. “Group mentoring” for academic competitions
has not been well studied, and very few advice
guides are available for mentors. Given the ongoing
interest in academic competitions, further research is
needed to determine which approaches to group
mentoring lead to positive student outcomes.
This research study examined the components of
effective mentor training for an out-of-school
robotics program for middle-school students. The
training used a blended learning approach that
included a one-day face-to-face workshop, 3-5 Web-
based tutorials, and interactive webinars. Blended
331
Locke S., Thomas S., Marlette S., Bracey G., Mayer G., Weinberg J., Holt J. and White B..
Blended Learning Training for Mentors of STEM Team Competitions.
DOI: 10.5220/0005487003310337
In Proceedings of the 7th International Conference on Computer Supported Education (CSEDU-2015), pages 331-337
ISBN: 978-989-758-108-3
Copyright
c
2015 SCITEPRESS (Science and Technology Publications, Lda.)
learning was chosen for its flexibility in delivering
content to mentors who were not co-located (e.g.,
Garrison and Kanuka, 2004). A total of four STEM
educators served as training facilitators: two
facilitators co-led the face-to-face workshop for
groups of mentors at two sites in the U.S., and three
facilitators shared responsibilities for leading the
webinars. The mentor training took place over a 10-
week period, beginning 6 weeks before the robotics
competition season started and ending 3 weeks prior
to the culminating competition day. This position
paper (work in progress) describes the benefits and
challenges of using blended learning to train team
mentors and reports initial research findings on
training outcomes.
2 THEORETICAL FRAMEWORK
The number of published studies of blended learning
has continued to increase since 2000 (Bliuc et al.,
2007). While several meanings for the term
“blended learning” have been proposed, a widely
accepted definition is that blended learning is a
combining of face-to-face instruction with web-
based instruction where learners are not co-located
(Garrison and Kanuka, 2004; Owston et al., 2008).
Furthermore, these researchers have argued that
effective blended learning is not simply the addition
of a technology-mediated component to an existing
traditional course, but rather an intentional
integration of face-to-face and web-based
components that capitalizes on the strengths of each
format. The online experience can add value by
allowing time for student reflection, extended
discussions, and personalization of content
(Ausburn, 2004; Bonk and Graham, 2006;
Laurillard, 2014). Researchers have reported that
compared to traditional courses, the blended learning
format promotes faculty-student interaction (Owston
et al., 2006), increases student satisfaction (Dziuban
et al., 2006), and increases student engagement
(Ziegler et al., 2006).
Much of the published literature on blended
learning focuses on university courses; however,
blended learning has also been applied to K-12 in-
service teacher professional development (e.g.,
Berger et al., 2008; Owston et al., 2008; Matzat,
2013; Eshtehardi, 2014; Ho et al., 2014). A primary
challenge of any teacher professional development is
to design a program that will facilitate lasting
change in teacher practice (Loucks-Horsley et al.,
2009). Using blended learning, facilitators can offer
support for teachers between face-to-face meetings
through structured online activities that enable
deeper reflection on their practice (Berger et al.,
2008). Blended learning is recognized as a
promising approach for working with in-service
teachers and other professionals because it can
extend the duration of the professional development,
allowing more time for teachers to try out new
practices in the classroom and receive immediate
feedback from the online community (Owston et al.,
2008b). Owston et al. have called for additional
studies that examine ways to better sustain teacher
participation in the online component and determine
the impact of blended programs on student learning.
3 TRAINING DESCRIPTION
The goal of this project was to develop a training
(professional development) program for robotics
team mentors that would give them knowledge and
skills necessary to effectively guide students through
the process of participating in a competition.
Weinberg et al. (2007) found that students
participating in the Botball robotics program who
have positive perceptions regarding their mentor's
effectiveness tend to have increased positive
perceptions towards STEM careers. However, the
components of effective mentoring are not well
understood, including the role that mentors might
play in increasing student self-efficacy for STEM.
Through an experimental study, the project sought to
determine which mentoring practices would be most
effective in increasing students’ self-efficacy in
STEM as measured by three assessments.
Mentors were teachers or administrators in the
students’ school, but they were not necessarily the
students’ STEM classroom teacher. New teams of 8-
10 students were recruited from 45 schools that had
never participated in the Botball program. Mentors
had a range of years of classroom experience and
most had no prior experience with robotics teams.
The study assigned teams to a control group or one
of three experimental groups. One group of mentors
received mentor training using best practices, a
second group of mentors received training in
mentoring for self-efficacy, and a third group
received training that combined best practices and
self-efficacy. Mentors were then expected to apply
these mentoring practices with their robotics teams
as they prepared for the Botball tournament. Surveys
administered to students before and after the
competition measured changes in students’ self-
efficacy and career-related choices.
CSEDU2015-7thInternationalConferenceonComputerSupportedEducation
332
The professional development for the best
practices group focused on team-building theory
(Tuckman, 1965) and practical issues such as team
member roles, goal-setting, creating cohesion,
managing interpersonal dynamics, and celebrating
success. The mentoring for self-efficacy professional
development focused on the theory of self-efficacy
and its four components: mastery experience,
vicarious experience, social persuasion, and
physiological reaction (Bandura, 1977, 1997).
Mentors in the third experimental group received
training that combined best practices and self-
efficacy. Mentors in the self-efficacy and combined
groups were given practical suggestions on how to
build students’ sense of mastery of technical and
communication tasks, provide students opportunities
to observe and learn from role models, offer targeted
feedback, and teach students strategies for managing
physiological responses to stress. The self-efficacy
techniques were drawn from the literature on STEM
and self-efficacy (Rittmayer and Beier, 2008).
The training program was well-suited to blended
learning because it required that mentors a) learn
theories with which they might be unfamiliar, b)
reflect on their own previous mentoring experiences,
c) practice team-based skills, and d) monitor and
discuss their mentoring practice throughout the
competition season. Mentors came from two
different geographic regions of the U.S., and they
were all based at different schools. The mentors’
widely varying and busy schedules meant that it
would have been difficult to schedule multiple face-
to-face workshops during a 10-week time span. Self-
paced Web-based modules gave mentors flexibility
to learn new content at a time and place convenient
for them. The tutorial modules also facilitated
personalization of learning by prompting mentors to
connect their learning to prior experience through
responses to open-ended questions. The
complementary face-to-face session promoted group
cohesion, which is critical to the development of a
community of practice, whether in-person or online
(Garrison and Arbaugh, 2007).
The training proceeded in a logical sequence that
began with an introduction to mentoring theory and
practice through the Web-based modules and
webinars. Prior to the face-to-face workshop,
mentors attended two facilitated webinars where
they were introduced to other mentors and provided
time to share and discuss their open-ended responses
to the tutorial questions. During the fourth week of
the training, mentors attended an on-site workshop
that included small-group activities and role-playing
to reinforce targeted concepts. Each mentor also
developed a written mentoring plan to help them
structure their team’s activities through the
competition season. Following the face-to-face
workshop, the mentors attended two webinars at 6
weeks prior and 3 weeks prior to the Botball
tournament. These webinars reinforced mentoring
concepts and addressed questions or problems
concerning the mentoring implementation. Total
mentor training contact hours were 17 hours for the
best practices and self-efficacy groups and 20 hours
for the combined group. Mentors in the control
group attended a technical workshop led by the
Botball organization, but did not receive any
additional training. Mentors in the experimental
groups also attended the technical workshop.
4 RESULTS
To examine the impact of the mentor training,
students in the four treatment groups (control, best
practices, self-efficacy, and combined) completed
three assessments pre- and post-competition:
Efficacy for Science-Related Jobs, STEM
Achievement-Related Choices, and STEM Self-
Efficacy. In addition, students evaluated their
mentor’s performance and reported on their mentor
practices, and mentors self-reported on their
mentoring practices. The reports on mentor practices
were intended as a check on implementation, since
the project facilitators were not present during team
practice sessions. Student reports of mentor practices
were considered alongside the mentor self-reports.
336 student and 41 mentors completed pre- and
post-surveys. Students who reported attending less
than 25% of their team’s meetings were excluded
from the statistical analysis because the treatment
was considered insufficient. It was expected that
mentor training that included self-efficacy would
result in higher student STEM self-efficacy and
STEM achievement-related choices compared to
best practices and the control. If that were the case,
then the study would provide evidence of the
benefits of including practical strategies that support
students’ self-efficacy in mentoring for STEM
competitions.
The proposed statistical approach was a mixed
analysis of variance (ANOVA) to test the
hypothesis. However, the implementation check
(student reports and mentor self-reports of practices)
suggested that students in the different treatment
groups did not receive distinctly different treatments.
With this confound, we were unable to explicitly
BlendedLearningTrainingforMentorsofSTEMTeamCompetitions
333
analyse the effect of mentor training on student
outcomes.
To further investigate the possible relationship
between effective mentoring practices and student
outcomes, the statistical team next conducted a post-
hoc analysis of covariance (ANCOVA) using the
student reports of mentoring practices. The student-
reported practices were categorized by student-
perceived amount of mentoring strategies applied
(low, mid-low, mid-high, and high groups). The
overall group effect of student-reported mentor
activities was significantly related to STEM Self-
Efficacy and to STEM Achievement-Related
Choices. The overall group effect was not
significantly related to Efficacy for Science-Related
Jobs. However, not using mentoring practices (low
group) had significantly lower outcomes than the
mid-low, mid-high, and high groups combined.
Thus, if only student-reported mentor practice
groups are considered, there was a significant
relationship for all three dependent variables.
Mentor practices do have a significant impact on
student STEM self-efficacy and achievement-related
choices.
In the next section we posit some of the possible
reasons for the lack of distinction between treatment
groups and provide recommendations for refining
the training using our qualitative evidence and
findings reported in the blended learning and teacher
professional development research bases.
5 DISCUSSION
The training program included many of the design
elements important for successful blended
professional development, including attention to
building a community of practice (Wenger et al.,
2002; Garrison and Vaughan, 2008); inclusion of
activities before, during, after, and in preparation for
face-to-face workshops (Berger et al., 2008;
Garrison and Arbaugh, 2007); flexibility (Owston et
al., 2008); and opportunity for extended discussion
(Bonk and Graham, 2006). During implementation,
however, mentor practices did not significantly
differ across treatment groups. Despite receiving
training in specific strategies targeted to best
practices and/or self-efficacy, similar mentor
practices were reported for all groups, including the
control. We hypothesize that a combination of
factors influenced these results, and that further
refinement of the training program could improve
the impact of training on student outcomes.
Important factors appear to be time constraints,
balancing group mentoring with technical tasks,
malleability of teacher practices, cohesiveness of the
community of practice, and the need for additional
structure in online activities.
Time and Scheduling: Webinar discussions
revealed that mentors faced significant challenges in
finding meeting times that would work for all team
members, in resolving conflicts with other student
activities such as music and athletics, and in moving
the team through the robotics design challenges
according to the Botball schedule. The relative short
competition season (7 weeks) meant that some
mentors struggled to simply keep the team on
schedule, and this may have prevented them from
implementing specific strategies discussed during
the mentor training sessions. Inconsistent student
attendance exacerbated some mentors’ efforts to
apply what they had learned.
Balancing Mentoring and Technical Guidance:
For mentors with limited exposure to robotics, and
those outside the fields of STEM, the need to help
students with the technical aspects of building a
robot was sometimes overwhelming and superseded
the mentoring implementation goals. One mentor, an
early-career English teacher, expressed frustration
with her inexperience with computer programming.
Although the Botball program is designed to
carefully scaffold the process of designing and
building a robot, mentors’ negative emotions might
interfere with their implementation of group
mentoring techniques. Allotting more time for
mentors to prepare for the technical aspects of the
program might build their own confidence levels,
enabling them to refocus attention to mentoring
strategies.
Malleability of Teacher Practices: When faced
with time limitations, teachers would be more likely
to revert to coaching and guiding the team in ways
that are familiar to them from classroom or other
experiences. For example, mentoring for self-
efficacy should include attention to all four sources
of self-efficacy (mastery, vicarious experiences,
social persuasion, and physiological response), but
some mentors were unable to schedule visits by role
models who could interact with students, a strategy
associated with increased self-efficacy.
Alternatively, experienced teachers might
unconsciously or even consciously resist changing
their practice. In one case in our study, a mentor
appeared to be resistant to trying new approaches,
stating that with “many years of teaching
experience” they were confident they knew the best
ways to work with their team.
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Building the Community of Practice: Zhao and
Rop (2001) emphasized the importance of
meaningful discourse in virtual communities, so that
teachers participating in professional development
feel they have a reason to stay connected to each
other. Using this principle, the interactive webinars
in this project provided opportunities for mentors to
reflect on their team’s progress, receive feedback on
specific problems, and experience emotional support
when faced with challenges beyond their control.
Although all webinars were scheduled well in
advance, as the program progressed many mentors
had trouble attending during scheduled times and
had to reschedule in smaller groups or in one-on-one
sessions with facilitators. This negatively impacted
the cohesion of the mentors within a treatment group
and reduced opportunities for reflective group
discourse. Owston et al. (2008) also found a decline
in participation rates for online biweekly reflective
tasks in a blended learning professional development
program for science and math teachers.
Structure of Online Activities: Owston et al.
(2008) suggested that shorter online tasks and skilled
online facilitators may help prevent weak
participation rates in blended learning environments.
For example, they found that teachers were more
motivated to post reflective online journals if they
received helpful feedback from facilitators. While
the mentoring webinars were an opportunity for real-
time feedback, the facilitators’ questioning was
generally open-ended. Our experiences and the
findings of Owston et al. suggest that the mentor
training might be improved by adding opportunities
to post online reflections and receive feedback more
frequently. For example, an online discussion board
would provide space for mentors to post the
implementation plans they developed during the
face-to-face workshop, revisit and revise them
periodically, and receive feedback from an online
facilitator and peers. The more frequent contact
would serve as a reminder to mentors to continually
integrate group mentoring principles into their
team’s activities.
6 SUMMARY AND
CONCLUSIONS
Team-based robotics competitions provide students
with the opportunity to learn technical skills such as
engineering design and computer programming,
while also enhancing problem solving, team work,
and communication—21
st
Century skills that are
valued by employers. Mentors for youth robotics
teams and other academic competitions may be
school teachers, university faculty and students, or
STEM professionals who have varied experiences
and skill levels in working with youth and guiding
teams. Despite the critical role these mentors play in
creating a positive experience, there are limited
resources available to mentors to help them
effectively guide their teams. To fill this gap, we
developed a training program for group mentoring
that is grounded in theory and empirical evidence of
mentoring best practices and sources of self-
efficacy. The training program was tested in a
robotics educational program, but the mentoring
concepts and strategies are applicable in any
learning environment where an adult mentor is
guiding a group of students through a team project.
The training used a blended learning approach
because mentors were not co-located and because a
long-term project goal is to make the training
available to a wide audience. The program
integrated Web-based tutorial modules on
mentoring, a face-to-face workshop, and interactive
webinars that reinforced the content and provided
time for group reflection and discussion.
The project tested three approaches to mentor
training using four groupings: control, best practices,
self-efficacy, and a combination of best practices
and self-efficacy. No differences were found in
student self-efficacy outcomes among the groups;
however, student and mentor reports of
implementation suggest that mentors in the four
groups did not differ significantly in their approach
to mentoring, despite the training. This finding is not
inconsistent with the teacher professional
development literature, which has noted the
difficulty of designing professional development that
leads to a sustained change in teacher practice
(Borko, 2004; Loucks-Horsley et al., 2009). We
suggest that both external factors (time and
scheduling) and training design features (the need
for additional structured online activities) influenced
the outcomes. Also, given the short duration of the
robotics competition season, it may be that
mentoring training is most effective with mentors
who have had at least one year of experience with
the robotics program, or who are sufficiently
familiar with the technology that they are able to
remain focused on evidence-based mentoring
strategies. In the next phase of this work we plan
interviews with a select group of mentors to
determine ways in which the online portions of the
training could be enhanced.
BlendedLearningTrainingforMentorsofSTEMTeamCompetitions
335
ACKNOWLEDGEMENTS
This material is based upon work supported by the
U.S. National Science Foundation under Grant No.
1139400. Any opinions, findings, and conclusions or
recommendations expressed in this material are
those of the authors and do not necessarily reflect
the views of the National Science Foundation.
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