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Australasian Journal of
Educational Technology

2006, 22(2), 229-250

Prospective science teachers as
e-learning designers

Matthew Kearney
University of Technology, Sydney

The study investigated the efficacy of prospective teachers authoring and
using their own online learning designs as a means of creating links between
theory classes and their teaching practicum. Trainee primary and secondary
teachers adopted an exemplary, well-researched learning design to inform
their own specific task designs, and used them in the context of science
lessons on their practicum. This process aided teachers’ development of
pedagogical and science content knowledge and helped them develop ICT
teacher competencies.

Introduction

This study builds on current interest in online learning designs by
investigating their potential role in teacher education. It uses the context of
prospective science teachers adapting and using a sample, well-researched
learning design, predict-observe-explain strategy supported by multimedia
(Kearney, 2002a), to facilitate a range of teacher learning outcomes. As well
as developing their pedagogical knowledge, the prospective teachers
revised and learned new science material and became aware of their own
alternative conceptions. Furthermore, they started to appreciate children’s
personal science views, the value of listening to and probing these views
and the challenge of confronting them. The student teachers’ immersion in
this e-learning design process acted as a rich context for a range of
significant teacher learning experiences.

Background

Theoretical perspective

Over the past decade, the field of educational technology has endorsed
constructivism as a suitable referent for the development and meaningful
use of appropriate software in education (Duffy & Cunningham, 1996). The
core view of learning from a constructivist perspective suggests that



230 Australasian Journal of Educational Technology, 2006, 22(2)

learners actively construct (rather than acquire) their own knowledge,
strongly influenced by what they already know. Learning is a social
process of making sense of experience, constructing new representations of
reality and further negotiating meaning through social activity, discourse
and debate (Tobin & Tippins, 1993). In this study, learning was viewed
from this constructivist perspective.

Learning designs

The term ‘learning designs’ refers to a coordinated set of online activities
designed to support conceptual change among learners (Oliver, 2001).
These web based learning sequences take advantage of the online medium
to make accessible effective learning strategies, supported by appropriate
structures and resources (Oliver and Herrington, 2003). Researchers have
recently identified and explored the underpinning support structures and
learning strategies incorporated in exemplary online learning designs,
particularly from tertiary education contexts (Agostinho, Oliver, Harper,
Hedberg & Wills, 2002; Laurillard & McAndrew, 2003).

Investigating how teachers might adapt and use exemplary online learning
designs is in its infancy and has so far mainly focused on tertiary teachers
(eg. Bennett, Lockyer & Agostinho, 2004). This study investigated pertinent
issues involved in using these designs in pre-service teacher education and
introduces prospective secondary and primary teachers as important
stakeholders in the learning design research agenda.

Current problems with teacher education

A problem facing teacher education is the resilient nature of student
teachers’ beliefs that shape their (face to face and online) classroom
practices and the need to provide them with opportunities to discuss and
reflect critically on these beliefs. For example, pre-service science teachers
study a variety of constructivist learning principles and strategies in theory
classes at university, and are exposed to an increasing range of exemplary
online learning designs in their studies. However, they often struggle to
implement theory into practice (Fang, 1996) and there is good evidence that
when faced with the hectic demands of everyday teaching duties, they
revert to more traditional didactic teaching methods (Goodrum, Hackling
& Rennie, 2001). Furthermore, their design of online activities tends to be
pedagogically shallow and content driven. This study investigates possible
ways of improving this situation.

Science teacher education was chosen as the context for this study as
problems in this domain are well documented (Goodrum et al., 2001) and
the sample learning design chosen is grounded in the science education
research literature.



Kearney 231

Sample exemplary learning design used in this study

The science education literature is filled with details of effective strategies
to support student learning. For example, strategies informed by a
constructivist perspective have been extensively reported, particularly
strategies that support students’ understanding of difficult concepts (eg.
Treagust, Duit & Fraser, 1996). One such strategy is the predict-observe-
explain (POE) strategy. It has been used widely for over two decades as an
assessment tool to probe learner’s conceptual understanding and more
generally as a tool to encourage quality peer learning. This strategy
involves learners predicting the result of a demonstration and discussing
the reasons for these predictions, observing the demonstration and finally
explaining any discrepancies between their predictions and observations
(White & Gunstone, 1992). Although the strategy is well researched (eg.
Champagne, Klopfer & Anderson, 1980; Gunstone, 1995; Liew & Treagust,
1995), few studies have investigated the use of these tasks in teacher
education. An exception was Palmer's (1995) study that investigated the
process of prospective primary school teachers creating their own (non
computer based) POE tasks to use as teacher centred, classroom based
learning activities. He reported that the prospective primary teachers
found the strategy to be a potentially useful formative assessment tool for
their teaching.

Multimedia supported predict-observe-explain (POE) tasks use the well-
researched POE learning strategy to effectively scaffold students’ learning
in a computer mediated environment, presenting digital demonstrations
set in real life contexts as stimuli for their learning. The online environment
gives students extra control over the pacing of their POE tasks and
facilitates peer discussions; while the use of digital media to present
demonstrations has significant affordances for learners’ observation
processes (Kearney, 2002b). This particular online learning design was
chosen for use in this study because it is well researched, has been
nominated as an exemplary design in a major Australian University
Teaching Committee project (Agostinho et al., 2002), and was already
included in the teacher education curricula at University of Technology,
Sydney (UTS). Also, there were existing web based templates (Kearney &
Wright, 2002) to help participants in the study build their own online POE
tasks to suit their own curriculum contexts.

Study design

Mainly qualitative data sources were used in this study, within an
interpretive methodology (Erickson, 1986, Lincoln & Guba, 1985), to
provide insights into pre-service teachers as online learning designers. The
study explored the following main research question using the context of



232 Australasian Journal of Educational Technology, 2006, 22(2)

prospective science teachers creating their own multimedia supported POE
tasks (at university) before using them in a school based teaching setting:
To what extent does pre-service teachers’ authoring and use of an online
learning design enhance their development as teachers? Subsidiary
questions included: To what extent do they develop their pedagogical,
technical and science content knowledge? To what extent is their
understanding of the sample learning design (POE strategy supported by
multimedia) enhanced?

Twenty-one prospective primary and secondary teachers from
undergraduate teacher education programs at UTS chose to participate in
this study. They were advised that participation in the study would not
influence their grades in their course and there was no background
technical skill requirement (approximately one half of the participants
indicated they had limited experience with computers). At the
commencement of the study, all student teachers had been exposed to the
principles of the POE strategy, and used examples of POE tasks in a range
of topics. The fourteen prospective primary teacher participants had
completed several one-month teaching practicums in primary schools and
had also completed science method subjects. The seven prospective
secondary teacher participants had completed one teaching practicum and
were in the process of completing their science method subjects.
Pseudonyms are used in this paper to protect individuals’ identities.

The student teachers were given one whole semester to design and create
their own multimedia based POE tasks before using them in a primary or
secondary classroom during their practicum. The design process included
consultation with appropriate science education literature and also with
relevant syllabus documents. For example, alternative conceptions
literature (eg. Driver, Squires, Rushworth & Wood-Robinson, 1994) was
consulted to find appropriate multiple choice options for the prediction
stage of their POE tasks. Student teachers used a web authoring package of
their choice (eg. Dreamweaver or Frontpage) to build their tasks. They were
required to write a rationale for their task designs and these were collected
as data to probe how well student teachers had used existing literature to
inform their designs. Semi-structured interviews took place with teachers
after this construction phase and they also completed a questionnaire at
this point. The actual multimedia tasks created by the student teachers
were collected as data for the study.

The next phase of the study took place during the student teachers’
practicum when they used their web based POE tasks with small groups of
school students. Semi-structured interviews were again conducted with
focus groups of student teachers after this implementation phase and they
completed a final questionnaire containing free response questions and 5



Kearney 233

Likert type items. The children’s task responses were collected as artefacts
for the project.

In summary, twenty-one student teachers were asked to develop a
multimedia based POE task for their own (K-12) students, and their work
was analysed in terms of what types of understandings and reflections
about science content and pedagogy were developed through this process.
Data were collected using questionnaires, focus group interviews,
observation and collected documents and artefacts.

Overview of teachers’ final tasks

The prospective teachers created their multimedia based POE tasks using
we based templates (or ‘eShells’) designed by Kearney and Wright (2002) to
support teachers’ construction of their own photographic, sound or video
based POE tasks. These POE eShells provided two possible formats: a
drawing format for tasks requiring more open ended responses and a
multiple choice format for tasks with demonstrations where possible
outcomes were limited. The templates also included a commitment section
(see Figure 2) where learners working in small groups on their task could
indicate their individual level of commitment to their initial predictions
before advancing to the reasoning and observation stages. Figures 1 to 4
show screen shots of selected pages from a sample task designed for
secondary physics students. In this task, the student teacher built a toy
sailing  boat and filmed the scenario of an electric  fan blowing air on to the

Figure 1: Prediction stage of sample task



234 Australasian Journal of Educational Technology, 2006, 22(2)

Figure 2: Commitment stage of sample task

Figure 3: Reasoning stage of sample task

sail. She then created a second, related POE task with one crucial variable
changed (the sail was taken away) - a technique encouraged by White and
Gunstone (1992) (two other students created dual tasks in this way). An
overview of other sample tasks created by the teachers is outlined in Table
1. The majority of teachers chose to create their own (mainly video based)
demonstrations while the others chose to find a pre-existing demonstration



Kearney 235

from the Internet. For example, many student teachers who chose an
astronomy theme found suitable photographic images from the web for
inclusion in their task. Most teachers chose a context within the physical
sciences. Only three teachers chose a life science theme. All task designs
can be accessed from the online POE Task Library at http://www.ed-
dev.uts.edu.au/teachered/poe/tasks/poehome.html

Figure 4: Observation stage of sample task

Findings

Findings are informed by mostly qualitative data from group interviews,
individual questionnaires and student teacher artefacts (their final POE
tasks and their rationales). Prospective teachers developed critical insights
into the POE learning strategy and its underpinning learning principles,
developed their own science content knowledge and ICT competencies.
They developed an ability to critique the learning design and
acknowledged that the POE procedure has its weaknesses and limits. They
became more sensitive to children’s world views and more developed
astute insights into children’s science learning processes. Quantitative data
from 5 Likert-style items in the final questionnaire supported these claims
(see Table 2).

This data particularly emphasised teachers’ perceptions that the whole
design and implementation process provided a positive model of effective
use of ICT in teaching and learning (see item 4).



236 Australasian Journal of Educational Technology, 2006, 22(2)

Table 1: Description of sample online POE tasks from study

Title/Topic
(type of demo.)

Description
(from Introduction Screen)

Key Question
(Response type)

Sailing boat
Newton’s Laws
(Video)

It's a great day to go sailing, there is
no breeze and the sun is shining. The
use of a fan might help us or will it?

The fan is pointing towards
the sail on the boat.  When
the fan is turned on, which
direction will the boat move
in?

Bushfire
Regeneration.
(Photo)

This is a photo of an area of National
Park near Sydney taken five days
after a bushfire swept through the
area.

If you were to visit the same
area of National Park three
months after the fire, what
do you think is most likely
to have happened to the
trees in the picture? (M-
Choice format)

Liquids in
space
Astronomy
(Video)

Here is some juice that was poured
into a glass

You’re now in a space
station, what would happen
to the juice if we spilt it?
(M-Choice)

Baked ice
cream
Heat / Insulation
(Video)

We all like desserts. The ice cream is
placed on a pancake and then covered
in pink meringue (beaten egg whites)
before being placed in the oven.

What will happen to the ice
cream when it is placed in a
hot oven for 5 minutes? (M-
Choice)

Ball in pool
Waves
(Video)

Here is a tennis ball in a swimming
pool. At the left end of the pool a
person using a boogie board to create
waves. There is no wind present. You
will be focusing on what happens to
the ball once the waves reach it.

In what direction will the
ball move when the waves
reach it? (Drawing)

Train
adventures
Motion
(Video)

Joel is travelling home on a train
travelling forwards at approximately
60 km/h. (It is not speeding up or
slowing down.) He will jump directly
up into the air while the train is still
moving (forward).

Where will Joel land after
jumping directly up into the
air on the moving Train?
(He is currently at Point B
marked in photo) (M-
Choice)

Thunder and
lightning
Waves
(Video)

You are sitting in a car watching
storm clouds in the distance. The
storm clouds are approximately 25
kilometres away from your
position…the storm will produce
thunder and lightning soon!

How will you observe the
thunder and lightning? (M-
Choice)

Developing teachers’ understanding and value of the POE teaching
strategy

Although they had covered the POE strategy in formal lectures, many
student teachers had not seriously considered using the strategy in their
teaching. Their design and implementation of a multimedia based POE



Kearney 237

task increased their value of this teaching strategy and the constructivist
philosophy in which it is grounded. At the end of the whole process, many
student teachers had developed an impressive insight into the strategy and
valued it as a potential tool for their future teaching.

Table 2: Participants’ responses from final questionnaire about teacher
learning during the process of building their POE Tasks (n=21)

Item
The whole process of building
and implementing my
multimedia based POE task has
helped me …

Strongly
agree

Agree Neutral Dis-
agree

Strongly
disagree

1. to build my knowledge of
teaching science.

8 9 4 0 0

2. to build my understanding of
kids as science learners

6 12 3 0 0

3. to revise and build on my own
science content knowledge

4 12 4 1 0

4. to build my knowledge of or
attitude to using technology to
enhance kids’ learning

13 6 2 0 0

5. to build my own technical
competencies

6 10 4 1 0

Analysing the nature of the learning design
Teachers revealed impressive insights into the underpinning constructivist
nature of the procedure. Bridie believed the real power was how the POE
tasks either challenged or re-affirmed children’s science views: “I became
aware that you can use tools and strategies to deal with kids’
misconceptions…you’re challenging their concepts they have in their head
- if they’re wrong. If they’re right, then you’re re-affirming them.” Isanne
also appreciated the engaging nature of the procedure and the opportunity
to help kids apply their knowledge to different contexts: “I think it’s better
than just showing them a demonstration. They have a chance to apply their
previous knowledge and use what they know already to try and work out
a new phenomenon they’re discovering.”

Like many students, Nasir appreciated the learner centred nature of the
procedure, in contrast to more traditional didactic teaching methods. He
also valued its effectiveness as a diagnostic tool:

You can gauge where they’re at, what ideas they have about science - by
getting them to predict stuff. They think about it a little bit more rather than
the teacher going ‘this is how it is, write it down!’ … I noticed a lot of
discussion between my kids: ‘What about this? What about that?’ They were
really focussed.



238 Australasian Journal of Educational Technology, 2006, 22(2)

Teachers also critically analysed each stage of the strategy. A number of
student teachers thought the crucial part of the strategy was its
requirement to commit to an outcome before viewing a demonstration.
Ruby mentioned: “They have to think about what they already know and
be prepared to put their money where their mouth is…their committing
themselves to something - it makes them think more - ‘well, what do I
really think about that’?” Lynne believed the real power was the reasoning
stage: “It’s the reasoning behind them [the students’ predictions] - that’s
where you really find out what they’re thinking.” Steve gave a detailed
appraisal of the strategy in his interview, and also emphasised the
reasoning stage:

The process draws out what they’re understanding … The reasoning part is
probably the strongest—it’s an endpoint for their ideas—belief in their ideas
and then they use it to commit—to ‘tell me why your beliefs are so weak or
strong’.

However, Gordon believed the observation and explanation stages were
the key to the strategy: “The strength is the observe and explain pages. The
explain page helps develop metacognitive thinking - it helps people think
about how their thinking. They know they are going to get to the explain
page.” However, some teachers acknowledged the challenging nature of
the final ‘explain’ stage for students (especially younger children), and
suggested a substitute ‘development’ stage, where learners could simply
record any questions that arose from the task, using a variant predict-
observe-develop strategy.

Insights into pedagogical issues
Student teachers were thoughtful about how they would fit their POE task
into a unit of work and most agreed that how they used their POE tasks
would depend on the level of complexity of the background concepts. To
enhance peer learning opportunities, most teachers asked their students to
work in pairs.

Many student teachers used their POE task as a diagnostic tool to probe
children’s pre-instructional science views and as introductory stimulus
material for discussion. Beth said she’d use her task again in this way at the
start of an astronomy unit: “The task was very effective in eliciting
students’ talk from which I was able to ascertain the level of the students’
understanding about the earth’s rotation as well as their misconceptions.”
Jane discovered that many of her kids did not recognise that the Earth spun
on an axis and used her task as a springboard for discussion and other
activities relating to seasons. Raja agreed that her tasks acted as stimulating
preliminary material: “This is just an introductory task. I think it is good to
introduce the concept and then you elaborate it more - another POE task or
something else in class – it stimulates them and gets them interested and



Kearney 239

you can therefore plan other lessons.” She found her students’ responses
were useful to her as a teacher: “We can see where they’re at, how they
think, what they know and don’t know.” Similarly, Steve observed
motivational benefits using his POE in this way. He thought the real value
of using his POE tasks at the start of the topic was that his students were
motivated to further explore the topic:

What they thought would happen was the opposite of what actually did
happen. So they actually said : ‘when are we going to do this?’ They actually
were going to go there [the next lesson] with a different frame of mind about
this topic.

Other student teachers decided to use their task as a revision exercise or as
a summative assessment tool. Alarna decided to use her task as a revision
tool, “after they’ve done their formal learning - to revise and ‘put into
practice’”. Mary commented on using her ‘butterfly life cycle’ task as an
assessment tool at then end of her unit of work: “I used it [my POE task] as
an ‘understanding task’, particularly seeing how clearly the students can
articulate the metamorphosis stage.”

There was some concern about when and how to present the ‘correct
science views’ relevant to each POE task. Some teachers wanted to add a
hyperlink to the ‘correct answer’ at the end of their web based task to add
closure. Others were happy to follow up their tasks with separate
investigations and teacher presentations that dealt with relevant science
concepts. For example, Jane’s kids wanted to know the ‘correct answers’
after they completed their task: “They didn’t want the task to be left open -
they wanted it ‘closed’!” Geoff strongly agreed:

It definitely needs a ‘follow up’. I was quite concerned about students not
able to confirm or deny their beliefs. Maybe they think they know it [the
correct science view] but even if they get it right, they may have misbeliefs -
especially if they just stay in their peer group, propagating their misbeliefs
in their peer group. The teacher needs an opportunity to ‘correct misbeliefs’
straight after task.

Student teachers such as Beth thought it was imperative to have a follow
up lesson to address this issue: “The POE strategy is an excellent tool for
establishing prior knowledge and for challenging children’s science
misconceptions. However, it does not stand alone. An explanation of the
demonstration should be provided.” Many student teachers placed a
similar emphasis on following up their POE task with a class discussion of
their responses and the correct science view. In this sense, they were
thinking beyond the specific learning strategy to develop an understanding
of how their task would fit into a broader (usually inquiry based) teaching
model.



240 Australasian Journal of Educational Technology, 2006, 22(2)

Developing teachers’ insights into e-learning design

Student teachers learned to distinguish the affordances and constraints of
both e-learning and face to face environments. They recognised the benefits
of using multimedia based demonstrations and the potential for
supporting self paced learning and peer learning conversations. Their
evaluations of the templates showed impressive insights into the
multimedia based POE strategy.

Justifying a computer mediated environment
Data from student rationales indicated that most teachers developed a
sound justification for using multimedia based science demonstrations (as
opposed to doing a ‘live’ class demonstration). Most teachers chose
demonstrations that were too time consuming, dangerous or simply
impossible to do in a ‘live’, class based POE. Many chose astronomy as
their topic for this reason: “Space is more inaccessible to students and
therefore seemed a better task for an electronic POE” [from Raja’s
rationale]. Mikal was the only student teacher to choose a sound based
demonstration and his rationale involved making a demonstration that
was indeed too dangerous for kids to do:

I chose my topic because it is one that cannot be experienced in the
classroom, nor could be investigated easily outside of the classroom. It
involves the use of a motor vehicle and section of the road that the vehicle
can travel at high speeds….

Many student teachers mentioned the out of class, realistic contexts made
possible via multimedia. They thought these rich contexts were an
important way for kids to link school science to their everyday lives. Lynne
mentioned in her questionnaire: “I feel the [multimedia based] POE
strategy brings science outside of the classroom and into the everyday
events of life.” Jack made similar comments: “One of the strengths of the
POE strategy is the way it presents exciting ideas from science ‘in your
face’. Students are directly confronted with actual science and it forces
them to immediately evaluate and explain.”

Students also appreciated the opportunities afforded by the computer
environment for learners to work independently and collaboratively. Mikal
emphasised the autonomous nature of the computer supported procedure
in his interview: “It allows for students to work independently and in small
groups…. My POE task allowed students to look at their science
misconceptions at their own pace.” Furthermore, one of Janet’s
questionnaire responses showed her appreciation of the peer collaboration
initiated by the tasks and also showed her value of the strategy:



Kearney 241

The tasks stress and promote the use of cooperative learning in that students
have to collate information, engage in conversation and draw scientific
conclusions when recording their results. Hence, students also learn from
each other and develop social skills and teamwork skills.

Other lecturers in the course noted student teachers from the project
referring to the POE strategy in their class discussions. For example, Jemma
initiated an online discussion thread devoted to the POE strategy. A
number of student teachers made postings to this forum indicating that
they intend to use the multimedia based POE strategy in their future
lessons. Indeed, Ruby believed that reflecting on the affordances of an
online environment indirectly helped her develop simple ideas for more
traditional, teacher led POE tasks in face to face, whole class situations.

Design issues with templates
Student teachers found the process of finding a suitable demonstration for
their POE task time consuming but eventually developed insights into the
type of phenomena appropriate for these tasks. They also found the
writing process challenging, particularly on the opening pages. Suggested
improvements to the templates pointed towards the need for a more child
friendly version for use in primary schools.

Many students found the writing process demanding, especially the level
of detail and choice of language on the crucial introductory and question
pages. For example, Stuart said the most challenging part of the design
process was “using kids friendly, appropriate language that is challenging
without going over the top - pitching at the right level. You had to be clear
and concise to help kids focus on the [subsequent] demonstration.”
Similarly, Jessica mentioned in her survey: “Choosing language on the first
page [was challenging], and making sure you found the medium between
enough detail to understand and too much detail to confuse.”

Most student teachers, including less experienced computer users, were
very positive about the templates and found them user friendly.  However,
many of the K-6 teachers thought the (designers’) language used on the
templates could be more child friendly and the graphic design needed
revision for younger learners. For example, they suggested the
commitment page could use a child friendly star or smiley face system
instead of the words ‘absolutely’, ‘moderately’ etc. The opportunity to
provide pictorial multiple choice options also was a commonly suggested
improvement to any future versions. Other suggestions included an open
ended written response option to supplement drawing responses and an
audio recording facility for young children who have trouble typing or
precisely communicating their science views in writing.



242 Australasian Journal of Educational Technology, 2006, 22(2)

Developing teachers’ understanding of children as science learners

The prospective teachers talked passionately about their new perceptions
of children’s learning processes. They developed insights into
collaborative learning and started to value the process of listening to
children’s personal science views via their conversations. They also
expressed an increased awareness of children’s alternative conceptions.
Final questionnaire data indicated that 86% of students either agreed or
strongly agreed with these claims - see item 2 from Table 2.

Learning to listen to children and appreciating the benefits of children’s learning
conversations
Teachers seemed to place great value on using their tasks as a vehicle to
listen to children’s science views via their learning conversations. For
example, in her interview, Janet indicated that she had listened carefully to
her students: “From listening to the children’s responses, I learned that
children have many unpredictable pre-conceived ideas. Their views are
extraordinary and very imaginative.” The whole process also helped Mary
gain an insight into the children’s world views: “The process helped me to
view scientific ideas from a child’s point of view.” Furthermore, Lynne
suggested listening to kids to initiate further ideas for creating more POE
tasks. “The best ideas would come from listening to the students and their
misconceptions.” Indeed, Mary’s final choice of demonstration (a time
lapse video clip of a caterpillar’s metamorphosis) was made after
discussing ideas with a stage 3 child.

There was insightful analysis and speculation about which part of the POE
process most strongly supports these peer learning interactions. Beth
believed that the prediction phase was a key to eliciting these learning
conversations: “The prediction is where I got to hear their thinking… that
was good for insight [into their science views]. It also illustrated the power
of prediction making in eliciting student talk.” Although, Archie found the
reason and commitment pages elicited more student talk: “There wasn’t
much discussion for their predictions but the ‘reason and commitment’
sections encouraged an increase in talk about why they were committed or
not.”

Student teachers thought critically about collaborative learning processes
and developed insights into peer learning. Most encouraged their students
to work on their tasks in pairs. For example, Isanne noticed her  students’
reviewing their ideas and talking to each other during the learning process:
“They kept going ‘no, it has to be this way! But it can’t be because if this…’
until they came to their idea … they were bouncing off ideas…the talking
helped them a lot.” Mary agreed: “I also learned that kids working
collaboratively greatly helps their science learning because it requires them



Kearney 243

to articulate and refine their ideas through their science conversation.”
However, Ruby touched on a potential weakness for group based POE
tasks. She appreciated the diversity of student views in her class but was
equally concerned about some students’ lack of science discourse skills and
their ability to reason and explain and defend their views:

I learned that the kids have very different ideas … often, the child who
selected the ‘right answer’ wasn’t able to explain why he thought his answer
was right and therefore he was over-ruled. Therefore, I think that often
children do know the right answer but lack the understanding to explain
‘why’ in a scientifically acceptable way.

Students do need a certain level of language skills to effectively debate,
clarify and defend their point of view in group situations and indeed, this
issue was seen as important to address before attempting these types of
tasks.

Learning about alternative conceptions in science education
Student teachers started to think carefully about children’s alternative
science views both during the design phase (eg. choosing a topic and
multiple choice options that target common misconceptions) and also in
the implementation phase when they elicited the children’s personal
science views.

In her interview, Lynne mentioned: “I just realised, when reading that
book on misconceptions [to design her task]…just how many
misconceptions children have in different areas—it’s just unbelievable!”
Most teachers expressed surprise at the exisiting alternative conceptions
held by their children. Jennifer discovered a whole range of kids’
misconceptions about heat from a misconceptions web page that helped
inform her task design. Beth was surprised at the children’s geocentric
views elicited from their use of her task: “The children’s perception [of the
solar system] was dominated by the earth – they saw everything [in the
solar system] as revolving around the earth.” She later added: “This
exhibition of misconceptions gave me some insight into children as science
learners… I think the whole misconception thing was really made clear by
doing this task—I didn’t even know about misconceptions before!” Steve
summarised:

I think that the strategy works down at a much deeper level for the student
and the teacher looking at any misconceptions—especially at a conceptual
level—that’s where you have to ‘dig’! You can’t be looking at any
misconceptions on the surface because they’re actually well hidden.

Mikal also learned to appreciate the range of students’ past experiences
and the influence of these experiences on their science views: “I learned
that all children come from different walks of life and have had different



244 Australasian Journal of Educational Technology, 2006, 22(2)

past experiences, which can reflect in their views of things.”  In this sense,
student teachers enhanced their awareness of children’s world views.

Developing teachers’ science content knowledge

It was widely acknowledged by the student teachers that the process of
designing a POE task encouraged them to review their own understanding
of relevant science phenomena. Final questionnaire data indicated that 76%
of students either agreed or strongly agreed with this claim (see item 3
from Table 2). Teachers engaged in debates and discussions with other
adult peers about relevant concepts during the design phase and many
discovered they had their own science alternative conceptions. The design
process also seemed to sharpen their observation of everyday science
phenomena.

Reviewing their personal science views
Teachers became aware of their own personal science views and
recognised the need for an expert knowledge base before attempting to
construct their POE tasks. For example, Alarna discovered she had
misconceptions regarding moon phases, while Beth also discovered her
own alternative conceptions in the area of local astronomy:

I had my own misconceptions and quite a few of them … I found a good
article on children’s stages of local astronomy misconceptions and I realised
that I was still in one of those stages … I’ve noticed that when my own kids
ask me something, I’m really going on my own prior knowledge, which
could be wrong… the process [of making the POE task] enhanced my
awareness of children’s science misconceptions and my own!

Ruby became more aware of the fallibility of her own science knowledge
base as she built her task: “I’ve got so many misconceptions—I don’t know
the scientific reason about many, many things.” She too became aware that
researching the accepted, correct science view was an essential part of
making these POE tasks: “You do have to research, you have to know your
topic; you can’t just put something down [from your own belief system]
because you might be wrong.” Many student teachers found themselves
consulting science books to clarify or revise their science content
knowledge. For example, Isanne said she had reviewed and clarified her
knowledge of butterflies whilst preparing her task:

I learned and re-capped! I had learned it before but didn’t remember it before
but now I understand properly about the processes…I researched it—so I
could make sure the [prediction] question was appropriate [in her task].

Initiation of science learning conversations with adults
An interesting feature of the task design process was student teachers’
frequent reports of in depth, engaging, science learning conversations with



Kearney 245

other adults, ranging from their own peers to expert scientists. Bridie and
Lynne said they both spent quality time reviewing Newton’s Laws and
discussed various scenarios with their adult flatmates. Lynne
acknowledged that her physics knowledge had benefited: “To be honest,
Newton’s Laws and in fact most of physics were not my strongest areas so
by doing this POE task, it has helped me to understand Newton’s 3rd Law
better.” Nasir also conducted in depth debates with his peers regarding the
background science to his task (relative motion): “I’ve argued with people
about mine so many times since I started making it. I’ve had in depth
arguments with people - even adults disagreed with me!”

Similarly, Damien learned something new about corrosion through his
discussions with outside professionals (he was not sure about the copper
compound causing the green stain in his photos). He discussed this issue
with three chemists and they all had different opinions! Indeed, Mikal
consulted a secondary science teacher, two scientists and a road expert
during his design process.

Development of observation skills
A number of student teachers said they started to observe natural
phenomena more closely as they searched for suitable topics for their POE
tasks. This was particularly the case for student teachers aiming to record
and make their own demonstration. For example, Gabrielle found it
difficult to think of a biology demonstration and finally came cross a heat
demonstration ‘as she was using the stove one day!’:

It took me three weeks to think of a task! I was constantly looking around
me saying: ‘Right! What science is there around me right now? How could I
make this significant?’ However, one day as I was lighting my stove, the
idea literally popped into my head!

Similarly, Nasir was on a train when his idea emerged: “I think you just
need to keep your ears and eyes open… I was riding on the train and it
dawned on me!” These comments were typical of teachers who chose to
design and create their own photo, sound or video based demonstrations.

Developing teachers’ comprehensive ICT competencies

A comprehensive view of teachers’ ICT competence was advocated by DEST
(2002), comprising the “collection of knowledge, skills, understandings and
attitudes that are inextricably bound up with context and pedagogy” (p.
13). As well as improving their technical skills, student teachers in this
study improved their attitudes towards and understanding of appropriate
use of ICT to enhance science learning. Final questionnaire data indicated
that a large majority of students either agreed or strongly agreed with this
claim - see items 4 and 5 from Table 2.



246 Australasian Journal of Educational Technology, 2006, 22(2)

Developing teachers’ confidence and technical competence levels
The prospect of developing technical skills was a major factor for many
student teachers when volunteering for this project, especially the students
with limited computer experience. Hence, it came as no surprise that many
student teachers felt they had learned new skills ranging from filming and
editing video and photos, to using web authoring software when
manipulating the POE templates. Student teachers who filmed their own
demonstrations recorded higher satisfaction levels and a sense of
ownership and enhanced confidence. For example, Raja said: “I feel a lot
more confident in my technical ability and was very proud of my finished
product - I never thought I’d be able to make a software program.” Alarna
concurred: “I thought the task would be challenging in the technology
aspects, however, it has actually made me more confident in using
technology and computers.” Interestingly, these same student teachers
reported that their children also noticed and appreciated their own
involvement in recording the demonstrations. For example, Janet
mentioned in her interview that her kids were excited because they knew
that she had filmed it: “The children conveyed how they enjoyed watching
a real video filmed at my own house and outside the classroom.”

Developing teachers’ knowledge of the role of ICT in supporting learning
Student teachers thought that making the multimedia based POE tasks
helped them to develop their attitudes toward and understanding of
innovative uses of technology to support learning. Alarna liked how the
technology supported active learning for kids: “It also showed me how
technology can be used to make learning a lot more relevant, interesting
and ‘hands on’ for children.” Also, Bridie realised the potential of
creatively using ICT in the classroom: “I feel like I can successfully attempt
to use technology in different ways now, creating tasks to enhance kids’
learning. I have a more positive attitude towards computers … it’s nice to
see a creative way of using them in teaching.” Ruby agreed: “I’ve realised
that there is a lot of potential for the use of technology in the in the
classroom that I am probably still not aware of.” The development of
student teachers’ insights into the nature and pedagogy of multimedia
supported POE tasks has also been discussed in previous sections.

Summary and discussion

A range of data sources were used to gain insights into the student
teachers’ learning experiences as they created their own online designs and
used them in their own practicum classes. They insightfully critiqued and
analysed the POE strategy and indeed, showed enhanced understanding of
constructivist learning principles underpinning this strategy. They
developed their knowledge of relevant pedagogy and reviewed and
clarified their personal science views. They valued their own technical



Kearney 247

skills development, and built positive attitudes towards the use of ICT in
their teaching. Furthermore, the application of their tasks in the school
setting helped fine tune their thinking, and provided further insights into
children’s learning processes.

The trainee teachers also reported broader outcomes in terms of their
teaching development. For example, Mary wanted to take the rich,
interesting contexts inherent in her online POE tasks into other teaching
strategies: “… by doing this [task], I believe I can create science lessons
which are more relevant to students. It also showed me how important it is
to gain students’ initial interest in science lessons.” Others were impressed
by the active learning evident amongst kids engaging with their tasks and
became motivated to emulate these conditions elsewhere in their face to
face teaching settings. For example, Nasir mentioned: “I learned that
children need to interact with science phenomena rather than just being
taught about it.” Ruby agreed: “I’ve learned that children really like to ‘do’
things and not only enjoy this more but learn more. So, providing children
with many opportunities to interact with objects and each other is a
positive teaching approach.” Finally, the project helped Bridie realise that
teaching is a complex business:

There are so many things to think about when planning a lesson – previous
knowledge, level of language, interests, misconceptions, learning strategies,
questioning etc. It has made me realise teaching science requires a lot of time
and patience, as creating this task did.

Another interesting outcome was student teachers’ exploration of potential
variations of the POE strategy. For example, some students proposed a
predict-observe-develop strategy to elicit learners’ questions (in the develop
stage), avoiding the difficult explain stage (especially for younger children).
Also, some teachers found stimulating, interesting multimedia based
demonstrations (particularly from the Internet) that were not suitable for a
POE task as they were either too challenging, or required too much
background information. For example, Bridie found a video clip of a plane
breaking the speed of sound and forming a small ‘cloud’ wrapped around
itself. Such ‘digital scenarios’ were interesting and thought provoking, and
student teachers speculated about how they might use them in the
classroom to promote discussion and questions; still fitting into an inquiry-
based teaching approach. Some teachers did experiment with these types
of demonstrations as stimulus material in the classroom, using a variant
observe-explain-develop strategy (again, eliciting learners’ questions in the
final develop stage). Hence, in these cases, the project encouraged teachers
to investigate valid variations of an existing exemplary learning design.

The positive results of this study warrant further research in teacher
education that focuses on both pre-service and practising teacher learning.



248 Australasian Journal of Educational Technology, 2006, 22(2)

Similar studies are needed to explore teacher development through their
adoption and investigation of other exemplary learning designs in a range
of discipline areas. Further research is also needed into the use of authoring
tools such as the Learning Activity Management System (Dalziel, 2003),
CopperCore (http://www.coppercore.org/), the R E L O A D s y s t e m
(http://www.reload.ac.uk/) and the Instructional Architect system
(http://ia.usu.edu/)  as flexible test beds for teachers’ designs. Also, the
Smart Learning Design Framework (Lukasiak et al., 2005) promises unique
opportunities for teacher education. These systems potentially provide
teachers and researchers with greater flexibility for their adaptation and
use of exemplary learning designs and also promote opportunities to
explore and spawn new variations of existing designs.

Conclusion

Findings from this study indicate that student teachers’ immersion in well
researched, exemplary online learning designs may indeed help them
bridge the gap between their university theory classes and practicum
experiences. Trainee teachers in this study successfully designed their own
online tasks using a sample, quality learning design (POE strategy
supported by multimedia) and in the process, developed astute insights
into the affordances and constraints of this design and also its
underpinning constructivist learning principles. They extended their
knowledge and sensitivity to the subtleties of children’s learning processes,
including their value of listening to children’s personal views and the
benefits of children’s peer conversations. The whole design and
implementation process helped the prospective teachers to review and
clarify their own content knowledge and also develop better attitudes to
and understandings of the role of technology in supporting learning.

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Dr Matthew Kearney
Faculty of Education, Kuring-gai Campus
University of Technology, Sydney
PO Box 222 Lindfield NSW 2070, Australia
Email: matthew.kearney@uts.edu.au
Web: http://www.education.uts.edu.au/
http://www.ed-dev.uts.edu.au/personal/mkearney/homepage/