Data Literacy of Prospective Physics Teacher Students in STEM
Learning
Eko Sujarwanto
a
Physics Education Department, Siliwangi University, Siliwangi Street 24, Indonesia
Keywords: Data Literacy, Prospective Physics Teacher, STEM Learning.
Abstract: The solution to a problem, among others, requires identifying and collecting, processing, and interpreting
data. This process involves data literacy skills. Data literacy is one of the hidden variables in the physics
learning process, and only a few are analysed. This study aimed to assess the data literacy possessed by
prospective physics teacher students. The research uses a case study research design. The scope of the research
is on prospective physics teacher students taking Electromagnetic courses at the Physics Education
Department, Siliwangi University, in the 2022/2023 academic year. Data analysis used descriptive statistical
analysis. Data Literacy in this research consists of data introduction, data collection and recording, data
analysis and interpretation, data communication, and data use. The context of this data literacy study is the
search for a solution to the problem of contamination of combustion smoke in the chimney by applying the
concept of physics. The findings are that students' data literacy is still at the primary and intermediate data
literacy level. The remarkable thing that needs attention is data literacy in the aspects of data recognition, data
interpretation, data collection, and data use. These results mean that students still need to be more to identify
data according to the problem, categorize data according to its use to solve problems, make connections
between the results of data analysis, and use data to provide arguments. The findings of this study can be the
basis for developing a learning program that involves data literacy training.
1 INTRODUCTION
Data literacy is a hidden variable/hidden curriculum
in physics learning. Science process skills may have
become a general topic/study in Physics learning.
Data literacy also intersects with Science Process
Skills, especially regarding data collection, analysis,
visualization, and interpretation. Data literacy
requires meaning and the impact of using data on
people’s lives, both from natural and social
knowledge. It is the meaning and use of data that
differentiate Data Literacy and Science Process
Skills. Data literacy must be identified as a hidden
variable/hidden curriculum at the university student
level.
Identification of data literacy at the university
student level needs to be done because students are
expected to be able to solve problems, think critically,
and make decisions based on valid and reliable data.
These abilities need to be possessed in an
interdisciplinary context and able to be applied in the
a
https://orcid.org/0000-0003-2535-3112
context of social life. This data literacy is helpful as a
basis for building a data-based society. Recognizing
misinformation and disinformation becomes more
complicated if the data literacy level of students is
unknown, especially during a post-pandemic
situation(Schreiter et al., 2022). In addition, data
literacy can also be the basis for other literacy, i.e.,
scientific literacy. Students with data literacy skills
will have more potential to understand data patterns
presented in scientific studies and be able to predict
and utilize scientific knowledge. Thus, it is necessary
to do research related to student data literacy.
Data literacy research is more commonly carried
out in studies of Computer Science and Informatics,
Mass Media, Environmental Science, and Library
Metadata(Wolff, Gooch, Montaner, Rashid, &
Kortuem, 2016, Wolff, Wermelinger, & Petre, 2019,
Pangrazio & Sefton-green, 2020, Deahl, 2014). Wolff
researched data literacy to uncover learning
principles that train data literacy. Wolff uses the
context of the position of solar panels in each house
Sujarwanto, E.
Data Literacy of Prospective Physics Teacher Students in STEM Learning.
DOI: 10.5220/0012199800003738
Paper published under CC license (CC BY-NC-ND 4.0)
In Proceedings of the 4th International Conference on Innovation in Education (ICoIE 4 2022) - Digital Era Education After the Pandemic, pages 287-291
ISBN: 978-989-758-669-9; ISSN: 2975-9676
Proceedings Copyright © 2024 by SCITEPRESS – Science and Technology Publications, Lda.
287
in a residential area on energy consumption. The
actual results from Wolff are the principles of data
literacy learning, including learning that needs to
involve complex data, interesting teaching materials,
and STEM learning situations. Research by
Mandinach & Gummer (2013) and Schildkamp, Lai,
& Earl (2013) states that good data literacy helps
educators plan and implement learning. Gasevic,
Dawson, & Siemens (2015) added that if used
effectively and ethically, data is an essential part of
education, for example, in giving feedback.
Pangrazio & Sefton-green (2020) and Bhargava et al.
(2015) also emphasized that data literacy will impact
technological innovation and positive societal
changes.
Research on data literacy in physics is still less
significant than in metadata and informatics. In
addition to these gaps, data literacy in the context of
STEM education, especially at the university student
level, has yet to be explored too much. This research
will enrich data literacy research in education,
especially physics education in the STEM context.
The STEM context in this study was that students
were asked to provide alternative solutions with
physics concepts for air pollution from combustion
chimneys. Students are asked to provide a solution so
that the solid particles in the smoke are not released
freely with the smoke gas phase. After getting a
potential solution, students are asked to expand the
effect of using data on society.
This study aims to reveal the data literacy of
prospective physics teacher students. This research
will see to what extent physics education students
utilize the concepts and laws of physics to solve
problems in the context of air pollution from
chimneys. Knowing the position of university
students’ data literacy can help design learning
programs, media, teaching materials, or learning
models that support data literacy.
2 METHOD
These case studies reveal the data literacy of physics
teacher candidates at the Department of Physics
Education, Siliwangi University, who are taking the
Electromagnetics course for the 2022/2023 academic
year. The case study method was chosen because it
wanted in-depth data about data literacy for a certain
period. This research can be called a one-shot case
study because the timeframe is only two weeks and
only one problem context. Case studies are also
helpful when the group being studied has a different
context from others' research. The context of this
research is the problem of air pollution originating
from chimneys. Students are asked to provide a
solution so that the solid particles in the smoke do not
spread freely along with the smoke gas phase. The
collection uses task assignments related to the
problems given earlier. In addition, questions and
answers were conducted regarding the problem-
solving process. Data analysis used descriptive
qualitative, which was carried out on the problem-
solving process by students.
3 RESULT AND DISCUSSION
This case study has studied the data literacy of
prospective physics teacher students at Siliwangi
University. The prospective physics teacher students
in this case study emphasized that the physics
concepts learned can and must be used to solve
problems. From the problems given to students, they
initially worked in groups to brainstorm about
separating the solid and gas phases in the smoke
coming out of the chimney. Then the students do
independent work to solve problems through task
assignments.
Student data literacy is seen in Data Recognition,
Data Collection and Recording, Data Analysis and
Interpretation, Data Communication, and Data Use(
Sujarwanto, Madlazim, & Ibrahim, 2022). The
remarkable thing that needs attention in this case
study is data literacy in the aspects of data
recognition, data interpretation, and data use. Data
literacy owned by students has varying levels for each
component.
Data recognition is crucial before going further in
problem-solving. Data recognition is also a starting
point for data literacy. The introduction phase is
essential in problem-solving(Sujarwanto, Hidayat, &
Wartono, 2014; Fakcharoenphol, Morphew, &
Mestre, 2015; Good, Marshman, Yerushalmi, &
Singh, 2018; Good, Marshman, Yerushalmi, &
Singh, 2020) and in data literacy (Wolff et al., 2019;
Gibson & Mourad, 2018). Students, in this case, study
have a Data Introduction level at the Intermediate
level. It is characterized by being able to predict the
variation of available data, being able to identify
appropriate data for solving problems, but not being
specific about the type of data, for example, related to
specific pollutant sources of Ozone, SO
2
, or CO.
Data introduction by students is shown in Figure 1.
ICoIE 4 2022 - The Fourth International Conference on Innovation in Education
288
(a)
(b)
(c)
Figure 1: Data Recognition by Students.
Figure 1 shows students can predict and identify
the data needed to solve problems. Students propose
the data about environmental air quality data around
settlements, sources of air pollution (Figure 1a),
chemicals in smoke, and the distance of pollution
sources from settlements (Figure 1b and Figure 1c).
Data collection is characterized by knowing how
to use tools and technology to collect, store, integrate,
manage, and check the correctness of data. From a
series of these characteristics, aspects of data
collection owned by students are at the primary level.
It was indicated by mentioning the tools and their
functions used to obtain data sources but did not
specifically mention the working principles of the
tools. Figure 2 shows the data collection aspect of the
task assignment. Students have been able to name
tools that support data collection to solve chimney air
pollution problems, for example, opacity meters to
measure smoke density (Figure 2a), utilizing sensors
on smartphones and impingers (Figure 2b), and a
spectrophotometer (Figure 2c).
(a)
(b)
(c)
Figure 2: Description of Data Collection by Students.
Data interpretation is a challenging aspect of data
literacy(Glazer, 2011;Edwards et al., 2017). Incorrect
interpretation of data can lead to errors in decision-
making. Interpretation of data owned by students is
still at the primary level. The characteristics shown at
the basic level of interpretation are that the majority
have not been able to interpret in-depth but only
explain/re-describe the data obtained and cannot
provide models or compare analysis results. The
results of data interpretation are shown in Figure 3.
(a)
(b)
Figure 3: Data Interpretation by Students.
Data Literacy of Prospective Physics Teacher Students in STEM Learning
289
The use of data is not only limited to scientific
inquiry and giving arguments but also connecting
data with scientific or social issues and knowing the
impact of using data on society(Gibson & Mourad,
2018; Sujarwanto et al., 2022). In the aspect of data
usage, students are at the intermediate level. It was
marked by being able to describe data presentations
(tables and graphs), providing/suggesting problem-
solving using physics concepts, relating to science but
not yet to social utilities, and the solutions put
forward by the majority of students using a
centrifugal and electrostatic deposition. The results of
using data from students are shown in Figure 4.
(a)
(b)
Figure 4: Description of Data Usage by Students.
Recognizing data and its sources is an essential
aspect of data literacy. Students are still at the primary
and intermediate levels when data literacy is
associated with the chimney problem project because
the problem is less contextual. This results because
students’ prior knowledge needs to be improved to
carry out the process. Thus, if a learning process aims
to increase data literacy, the data context must be
close to students. It follows the suggestion by Wolff
et al. (2019) and Sujarwanto et al. (2022). In
sustainable development, data literacy results in
pollution through chimneys are supported by the
research of Ridwan, Kaniawati, Suhandi, Samsudin,
& Rizal (2020). The research stated that students are
aware of sustainable development but are less
effective in practical skills related to sustainable
development.
Interest affects the components of data usage.
Because the student’s background is physics and
science, students associate the use of data and
problem solutions with the science field, namely
environmental pollution, the greenhouse effect, and
health problems. Nothing has yet been linked to
economic and policy aspects. It is supported by
cognitive theory for situational interest type
motivation Moreno (2010) and the research results by
Wolff et al. (2019).
4 CONCLUSIONS
The results and discussion show that students still
need to be improved in identifying data according to
the problem, categorizing data according to its use to
solve problems, making connections between the
results of data analysis, and using data to provide
arguments. The findings of this research can be the
basis for developing learning programs that involve
data literacy training.
ACKNOWLEDGEMENTS
This research is supported and funded by LPPM-PMP
Siliwangi University.
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