=Paper=
{{Paper
|id=Vol-2356/research_short10
|storemode=property
|title=Bringing field and laboratory work into the classroom by using online modules in the edX platform
|pdfUrl=https://ceur-ws.org/Vol-2356/research_short10.pdf
|volume=Vol-2356
|authors=Alejandra Quintanilla-Terminel,Matej Pec,Oliver Jagoutz
|dblpUrl=https://dblp.org/rec/conf/emoocs/Quintanilla-Terminel19
}}
==Bringing field and laboratory work into the classroom by using online modules in the edX platform==
https://ceur-ws.org/Vol-2356/research_short10.pdf
Proceedings of EMOOCs 2019:
Work in Progress Papers of the Research, Experience and Business Tracks
Bringing field and laboratory work into the classroom by
using online modules in the edX platform
Alejandra Quintanilla-Terminel1,2 , Matej Pec1, and Oliver Jagoutz1
1 Department of Earth, Planetary, and Atmospheric Sciences,
Massachusetts Institute of Technology, Cambridge, MA 02139, USA
2 MIT Open Learning,
Massachusetts Institute of Technology, Cambridge MA 02139, USA
Abstract. We present two projects that aim at enhancing geoscience education
in the classroom through the use of online modules in the edX platform.
“Deform the Earth” and “Virtual field trip” are two online modules that the
department of Earth, Planetary, and Atmospheric sciences is developing in
collaboration with MITx. These two modules will be first used residentially at
MIT, and will be subsequently adapted to be freely accessible through the edX
platform in order to expand access to geoscience education worldwide. Each
module addresses different challenges in geoscience education. How to teach
laboratory skills in the classroom, particularly in a field that is both dangerous
and difficult to access? How to teach field skills in a dynamic and effective way?
How to make sure the students make the most out of their field experience? We
describe each module goals, learning outcomes, and instructional designs.
Keywords: Geoscience online modules, laboratory skills, field trip, edX,
blended learning
1 Introduction
Teaching the practical skills of science has been an interesting challenge since the
beginning of MOOCs (Waldrop, 2013). A variety of innovative uses of technology
allowed the development of online labs (de Jong, Sotiriou and Gillet, 2014) for blended
or online learning. The use of virtual, augmented and mixed reality and gamification of
content has stretched even further the possibilities for teaching scientific skills. (Psotka,
1995; Freina and Ott, 2015, ).
Geoscience education heavily relies on laboratory and field components. It is therefore
particularly challenging to adapt to a classroom if easy access to laboratory facilities or
field areas is not readily available. Geoscience education hence benefits from an
effective use of multimedia materials that can bring the field and laboratory aspects of
geoscience seamlessly into a classroom setting (Libarkin and Brick, 2002). MOOCs
further present both a challenge and an excellent opportunity to expand geoscience
education to underserved communities.
We present here the instructional design of two one-week long modules that will be
used on campus (at MIT) in the fall of 2019: “Deform the Earth!” and “Virtual field
60
� Proceedings of EMOOCs 2019:
Work in Progress Papers of the Research, Experience and Business Tracks
trip”. Both modules are targeted innovations of the edX platform and are developed in
collaboration with a faculty member at the department of Earth, Atmospheric, and
Planetary Sciences at MIT and a digital learning fellow at MITx (MIT Open Learning).
The objective of the modules is to teach field-geology and experimental rock mechanics
skills using the edX platform, and reinforce these two skills that are particularly
challenging to teach in a classroom. At this stage, we do not intend to replace the field
excursion and the laboratory component of our classes, rather we intend to use the
online modules to complement our classes and help our students consolidate their
knowledge throughout the semester. However, our final objective is to create an
introductory geology MOOC in which learners will acquire both observational and
experimental scientific skills in a purely online setting.
2 Residential use of “Deform the earth”
2.1 Motivation for “Deform the earth”
Our understanding of plate tectonics relies on the knowledge of strength of geological
materials. However, because the experimental protocols are difficult to explain in a
classroom, and only few rock deformation laboratories exist world-wide, students
overlook this component of Earth sciences and lack the knowledge to critically evaluate
experimental results. “Deform the Earth!” is a one-week long module that will allow
learners to visualize the components of a deformation apparatus, understand how
extreme conditions of pressure and temperature are achieved, and how the data is
acquired and analyzed, all without having to be in the laboratory.
At MIT, students can access the rock mechanics laboratory, however the experimental
set-up is very involved and it takes on average three days to prepare one single
experiment for an experienced user. Students struggle with the different steps of
experiment preparation and often get lost in the details and forget the big picture.
Moreover, we have noticed that similar, seemingly obvious mistakes, are repeated even
though the students received a detailed one to one explanation. It is likely that the
current training method leads to cognitive overload. We expect that the module will
allow us to scaffold the student’s learning. A blended learning model will be used in
the class “Flow, deformation, and fracture in Earth and other terrestrial bodies” and the
students will follow the module “Deform the Earth!” with a hands-on laboratory
activity.
2.2 Learning outcomes
At the end of the module, the students should be able to design an experiment that can
be performed in the experimental rock deformation laboratory, in order to test a
hypothesis they developed. The students need to have a clear understanding of the
scientific method (Popper, 2005), and the limitations of the experimental set-up they
will use.
61
� Proceedings of EMOOCs 2019:
Work in Progress Papers of the Research, Experience and Business Tracks
We expect the students to be able to describe each step of the experimental procedure
they will perform. Finally, students should know what data they are going to collect
and what data treatment they are going to perform in order to test their hypothesis.
2.3 Instructional design
The module is designed in four sections, incorporating research-based techniques for
better learning:
1. Introduction to experimental rock deformation
2. Experimental procedure
3. Data treatment
4. Extrapolation to nature
The introduction to experimental rock deformation is done via interviews to members
of the rock mechanics community and analysis of historically relevant papers.
Deformation machine design and engineering solutions necessary to replicate the
extreme conditions under which rocks deform in the Earth and other planets are
introduced via case analysis of famous experiments. Assessments focus on dissecting
the scientific method that was followed. The edX platform allows us to use how-to
videos explaining each component of the deformation apparatus and the steps required
to perform an experiment and integrate them into a learning sequence. The assessments
are designed in order to address common misconceptions and experimental mistakes
(Adams and Wieman, 2011). We use a variety of strategies for assessments in order to
develop rigorous activities for our students (Sandland and Rodenbough, 2018). The
data treatment is designed as worked examples (Renkl, 2014) using Matlab. Data
analysis is an excellent place to use worked and faded examples as it reflects very
accurately how users learn how to interpret the data, usually by working through
previous analysis.
Finally, the extrapolation to nature section ties all the acquired skills together. The
experimental results are used to understand how rocks deform in nature. In an open
response assessment, students have to formulate a hypothesis and design an experiment
to test it. Students are expected to grade each other’s experimental plan before being
graded by staff. The peer-grading stage will allow us to test how well they understand
the scientific method.
3 Residential use of “Virtual Field trip”
3.1 Motivation for “Virtual Field Trip”
An essential part of the geology training is learning how to make reliable field
observations. This skill is extremely difficult to teach in a traditional classroom setting
and is usually taught through field trips. However, during the trip students receive a lot
of information, ranging from how to make correct observations to geological processes
62
� Proceedings of EMOOCs 2019:
Work in Progress Papers of the Research, Experience and Business Tracks
and large scale geodynamics. Students have to make many new connections with
freshly acquired information. We see that they struggle establishing connections to the
big picture of plate tectonics, possibly because they are experiencing cognitive
overload. It is impossible to go back to the sites to reflect upon the observations made
at a later point, which would be an ideal situation to help their learning (Clark et al.,
2006). The “Virtual field trip” module will allow students both to prepare for their field
trip and to re-visit their field trip experience and strengthen the connections between
observations and learned geological concepts. It will also allow students who could not
participate in the field trip to access some of the teaching that is delivered in the field.
3.2 Learning outcomes
At the end of the module, students should be able to identify markers of the
geological processes inherent to the Wilson cycle, a model of the cyclical opening and
closing of ocean basins caused by movement of the Earth's plates (including rifting,
spreading, subduction, and collision). They should be able to make observations and
formulate hypothesis supported by those observations. Students should be able to
communicate those hypothesis by drawing a geological cross-section of the studied
area. A cross section is a graphical representations of vertical slices through the
Earth’s crust, or in other words a two-dimensional slice of Earth's subsurface used to
clarify or interpret geological relationships accompanying maps.
3.3 Instructional design
The module is divided in three sections that will be taken by students at different stages:
1- Introduction
2- Day 1
3- Day 2
The introduction revises concepts that were learned in class to ensure there are no
misconceptions. It also gives a broad perspective on the history of supercontinents.
Students will be required to complete this section before the field trip. The two
following sections will be completed after the field trip and mirror the field trip
structure. Each day is divided into “stops” corresponding to geographic locations
chosen illustrating a particular process or supporting our current hypothesis for the local
geological history. We are very deliberate in the use of video. VR technology would
have been great for giving the students the experience of being in the field (Jiayan Zhao
et al., 2017), but this module does not aim at replacing the field experience. The video
is used in two ways. First, it enriches the students’ view of the area, giving access to
perspectives that are not available in the field trip (with the use of drones or high
magnified images). Second, it allows us to train the observational skills of the students:
for each stop, they have to make observations on the video or on images, before hearing
the explanation. The final assessment is an open response assessment of a geological
63
� Proceedings of EMOOCs 2019:
Work in Progress Papers of the Research, Experience and Business Tracks
cross-section. Students are expected to grade they peers before being graded by staff,
this will lead them to test each other’s hypothesis.
4 Conclusion: towards a MOOC
The two geosciences modules will be offered residentially this fall. The blended
learning set-up will provide us with rapid feedback regarding the effectiveness of the
instructional design. Some questions are obvious: does the experimental exposure
shorten the hands-on training time? Does the virtual field trip make it easier for students
to make big picture connections? Others questions are more subtle and difficult to
answer. Could we design a hands-on activity that can be evaluated in a MOOC? How
can virtual reality or mixed reality help us recreate a field trip? How can we make this
MOOC accessible for all learners? We hope that our residential experience will allow
us to build a stronger MOOC.
References
1- Adams, W. K. and Wieman, C. E. (2011). Development and Validation of Instruments
to Measure Learning of Expert‐Like Thinking. International Journal of Science
Education, 33(9), pp. 1289–1312. doi: 10.1080/09500693.2010.512369.
2- Clark, R. C. et al. (2006). Efficiency in learning: Evidence-based guidelines to manage
cognitive load. Performance Improvement. John Wiley & Sons, Ltd, 45(9), pp. 46–47.
doi: 10.1002/pfi.4930450920.
3- Freina, Laura & Ott, Michela. (2015). A Literature Review on Immersive Virtual
Reality in Education: State Of The Art and Perspectives. Conference preceding in
eLearning and Software for Education (eLSE), At Bucharest (Romania).
4- Jiayan Zhao et al. (2017). iVR for the geosciences. in 2017 IEEE Virtual Reality
Workshop on K-12 Embodied Learning through Virtual & Augmented Reality
(KELVAR). IEEE, pp. 1–6. doi: 10.1109/KELVAR.2017.7961557.
5- de Jong, T., Sotiriou, S. and Gillet, D. (2014) ‘Innovations in STEM education: the Go-
Lab federation of online labs’, Smart Learning Environments. SpringerOpen, 1(1), p.
3. doi: 10.1186/s40561-014-0003-6.
6- C. Libarkin, Julie & Brick, Christine. (2002). Research Methodologies in Science
Education: Visualization and the Geosciences. Journal of Geoscience Education. 50.
449-455. 10.5408/1089-9995-50.4.449.
7- Popper, K. (2002). The Logic of Scientific Discovery. London: Routledge, pp. 27-36,
https://doi.org/10.4324/9780203994627
8- Psotka, Joseph. (1995). Immersive Training Systems: Virtual Reality and Education
and Training. Instructional Science, vol. 23, no. 5/6, pp. 405–431
9- Renkl, Alexander & Atkinson, R.K. (2010). Learning from worked-out examples and
problem solving. Cognitive Load Theory. 91-108. 10.1017/CBO9780511844744.007
10- Sandland, Jessica and Rodenbough, Philip. (2018). Strategies for Assessment in
Materials Science and Engineering MOOCs: Short-Answer Grading Best Practices.
Open Education Global Conference 2018
11- Waldrop, M. M. (2013). Education online: The virtual lab. Nature, 499(7458), pp.
64
� Proceedings of EMOOCs 2019:
Work in Progress Papers of the Research, Experience and Business Tracks
268–270. doi: 10.1038/499268a.
65
�