murcia.pdf


Australasian Journal of
Educational Technology

2010, 26(Special issue, 4), 417-431

Talking about science in interactive
whiteboard classrooms

Karen Murcia and Rachel Sheffield
Edith Cowan University

Teachers using interactive whiteboards (IWB) effectively can engage and motivate
students with a range of digital resources to explore science's role in making sense of
our world and to construct knowledge of key scientific concepts. The case study
research described in this paper illustrates how interactive pedagogies in the IWB
classroom were used to support whole class substantive discourse about science. A
sociocultural framework structured the exploration of the discourse surrounding four
teachers and their students’ use of IWB technology in their primary science
classrooms. Action research methods and a professional learning intervention were
used for both exploring and developing teachers’ understanding of the interactive
technology and its impact on the nature of classroom talk. Comparing video captured
lessons with and without the use of the IWB provided some initial evidence of an
increase in students’ participation in substantive science conversations and
exploratory talk. The preliminary analysis of the data summary across the four case
studies suggested that the teachers were using more open questions, greater wait time
and required greater participation from students. This research suggests that teachers’
effective IWB pedagogy impacts positively on the way students talk about science.
Seven principles of effective interactive pedagogy focused on enhancing discourse
emerged from the action research. It is recommended that these principles be used
with IWB technology to scaffold deep substantial science discourse, which is essential
in developing students’ scientific literacy.

Introduction

Classroom technology is evolving quickly and so must teachers’ pedagogy in order to
meet the learning needs of contemporary ‘digital students’. The Australian
Government’s Digital Education Revolution recognises the changing needs and
motivation of these students and aims to contribute sustainable and meaningful
enhancements to teaching and learning and prepare students for further education and
for living and working in a digital world. This initiative recognises that Australian
students need greater access to, and more sophisticated use of, ICT as well as well-
trained teachers to integrate technology into teaching and learning (DEEWR, 2008).
Improving teachers’ expertise and students’ scientific literacy learning outcomes are
also strategic priorities for the Australian Government and it is argued that ICT
integration is a key reform strategy.

Research on effective classroom practice provides evidence to support a focus on
integrating ICT across the curriculum. For example, Hackling and Prain (2005) found
from their analysis of a series of seminal Australian research and professional
documents that the dominant characteristics of effective science teaching were life and



418 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

community relevant science learning experiences, active engagement and inquiry-
based learning focused on outcomes that contribute to scientific literacy. They also
stated that in effective science teaching “Information and Communication
Technologies (ICT) are exploited to enhance learning” (p. 19). The need to integrate the
use of ICTs into science learning and teaching was also explicitly addressed in the
Australian School Science Education National Action Plan. It was recommended as a
priority action that teaching and learning approaches be encouraged that promote the
outcome of scientific literacy and specifically stated, “students learn science by seeking
understanding from multiple sources of information, ranging from hands-on
investigation to Internet searching” (Goodrum & Rennie, 2007, p. 14).

Interactive whiteboards (IWB) are reported to be an effective way for teachers to
interact with and converge digital content and multimedia learning resources in the
classroom (Betcher & Lee, 2009; Hennessy, Deaney, Ruthven & Winterbottom, 2007;
Murcia, 2008a). Particularly as research suggests it is the interactivity in online digital
learning activities that students most value (Ng, 2008). The IWB enables students and
teachers to interact with all the functions of a desktop computer through the board’s
large touch sensitive surface.The IWB essentially acts as a port through which any
computer run ICT function can be displayed and interacted with. Teachers who use
effective interactive pedagogies with the IWB can enhance the learning benefits of
interactive websites and ICT generally by bringing the experience to the whole class or
alternatively, supporting small group learning with ICT. Teachers can engage students
with computer-based learning without being hidden behind a desktop screen or
isolating learners at a computer (Betcher & Lee, 2009; Murcia, 2008b).

Educational research suggests effective interactive pedagogy with an IWB can engage
and motivate students to explore science's role in making sense of our world and to
understand key scientific concepts. For example, research conducted by Hennessy et
al. (2007) and Murcia (2008a) investigated how interactive whiteboard technology
could be used to support science teaching and learning. The UK study conducted by
Hennessy et al. (2007) reported pedagogical strategies for using the IWB in school
science. They found teachers exploited the dynamic and manipulative nature of the
technology in order to “focus thinking on key scientific concepts and processes, to
unpack, explain and organically build them up and to negotiate new, shared
understandings” (p. 297). The Australian study conducted by Murcia (2008a) found
that active science learning connected to social contexts was increasingly possible with
the use of interactive whiteboard technology. The technology enabled the development
of creative science teaching resources that linked directly to Internet sites and online
activities. It enabled fluid access to online real life science contexts which could be
annotated at the board with the interactive tools. In both research contexts, multimedia
resources were converged efficiently into a sequence of learning activities with time
efficient links embedded into the IWB software’s notebook.

Teachers’ facilitation of discourse when using the IWB emerged as a dominant theme
from the research. Murcia (2008a) found that the IWB created a fluid space where
interactive communication allowed the teacher and students to “explore science ideas
together, pose questions and reconcile scientific and informal ideas” (p. 20). Integrated
with reported interactive activities were higher order questions and student led
discussions: “Questioning was the means for focusing students’ attention, provoking
action and for making connections” (Murcia, 2008a, p. 20). Higgins, Beachamp and
Miller (2007) in their review of the literature on interactive whiteboards further



Murcia and Sheffield 419

identified research evidence that “interactivity is most effectively sustained through
effective questioning as well as a wider range of activity” (p. 216). Strategies for
managing effective questioning and discussion are a key dimension of productive
interactive pedagogy. However, Hennessey et al. (2007) caution that the “ever present
concern to maintain lesson pace means that ironically IWB use may afford even less
thinking time and opportunity for pupil input than other forms of educational
technology” (p. 285). This concern, coupled with an understanding of the crucial role
played by language in sustaining effective interactive pedagogy in inquiry-based
science, provided the impetus for further research into the impact of IWB technology
on the nature and quality of discourse in the science classroom.

In response, this case study research was conducted with four teachers from two
Western Australian primary schools. The aim of this research was to explore the
impact of IWB technology on discourse in the primary science classroom. The case
study teachers introduced interactive whiteboards into their teaching of primary
science as a part of a professional learning intervention. They used the technology to
enhance and extend their implementation of selected primary science units from the
Australian Academy of Science resource, Primary Connections. This paper reports the
methods and preliminary findings of this research. Firstly, influential literature in the
field of discourse analysis and science inquiry is reviewed to establish the research
framework. A focus is then given to the action research methods used to explore the
teachers’ use of IWB technology and the nature of whole class discourse in their
science classrooms. The data analysis process is explained and evidence is then
presented to show the impact of teachers’ IWB pedagogy on the way their students
talked about science. The principles of effective interactive pedagogy supporting
substantive science conversations emerging from the case study are presented as an
outcome of the research.

Frameworks for exploring science discourse

To begin, it is essential from a sociocultural perspective of science education to give
consideration to the type of questions and the nature of discourse that supports
student learning and their development of scientific literacy. Through this lens science
education is viewed as a process of enculturing students into particular ways of
knowing and representing the world and making claims from a scientific perspective
(Hackling, Peers & Prain, 2007). It is evident that science has a distinctive social
language that Mortimer and Scott (2003) argue “can be thought as a tool, offering a
distinctive way of talking and thinking about the world” (p. 13). An important aspect
of enculturing is the use of language supported, inquiry-based activities that enable
students to meaningfully construct an understanding of science. It is argued that
engaging students with public discourse in which they experience meaningful
exploratory talk and substantive conversations, contributes to their development of
scientific literacy.

Mortimer and Scott (2003) identified two dimensions of classroom talk and described
these as interactive/non-interactive and dialogic/authoritative. They classified
classroom talk as interactive when multiple students and the teacher contribute to a
whole class conversation and non-interactive when one voice dominated or excluded
others’ contribution. They considered talk to be dialogic when many ideas are
presented and authoritative when consideration is given to only one point of view,
which in science is often the dominantly accepted scientific conception or explanation.



420 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

In addition, talk was considered to be interactive when multiple students and the
teacher contribute to a whole class conversation and alternatively non-interactive
when one voice dominated or excluded others’ contribution. Combining Mortimer and
Scott’s (2003) dimensions resulted in the identification of four communicative
approaches, as shown in Figure 1.

Interactive
Many voices

Non-interactive
One voice

Dialogic
Many ideas

Interactive/dialogic
Many voices and ideas

Non-interactive/dialogic
One voice but many ideas

Authoritative
One idea

Interactive/authoritative
Many voices but one idea

Non-interactive/authoritative
One voice and one idea

Figure 1: Dimensions of discourse and the communicative approaches
(based on Mortimer & Scott, 2003)

Mortimer and Scott’s (2003) interactive-dialogic communicative approach is consistent
with the notion of dialogic teaching developed by Robin Alexander (2008) which he
describes  as collective, reciprocal, supportive, sustained, cumulative and purposeful.

Inquiry-based teaching and learning is based on the social constructivist view that
students must actively construct understandings through making sense of experiences
using their prior knowledge and through conversation with others (Driver, Asko,
Leach, Mortimer & Scott, 1994). This suggests it is important to match the nature of
discourse to the inquiry process in primary science classrooms. When discourse is
explored in relation to the phases of inquiry and specifically the 5Es constructivist
model (Bybee, 1997; Australian Academy of Science, 2005) it is evident that different
communicative approaches are required to achieve the learning and teaching purposes
of each phase. These phases are described by Hackling, Smith & Murcia (2010) in the
following quote.

Teaching must start by exploring students’ prior beliefs (Engage) and then provide
experiences of science phenomena so as to work on students’ ideas (Explore), before
formal scientific explanations are introduced and developed on the social plane
(Explain). Subsequently, students should be given an opportunity to appropriate the
new scientific ideas and to apply them in a student-planned investigation (Elaborate)
(p. 18).

Logically, these ideas suggest teachers’ use of the IWB and development of digital
interactive resources should be matched to the phase of inquiry and facilitate
appropriate substantive classroom talk about science. Classroom talk that is
substantive emphasises the construction of students’ knowledge of and about science.
The direction and momentum of the conversation is maintained by teachers’
questioning, use of wait time, acceptance of a range of student ideas and asking further
questions that seek clarification, elaboration or evidence for assertions from the
students (Koufetta-Menicou & Scaife, 2000). The talk happening on the social plane of
the classroom becomes cumulative and supports collaborative construction of
knowledge and understanding (Hackling et al., 2010).

During the engage and explore phases of inquiry when the instructional purpose is to
elicit students’ prior conceptions and work on students’ ideas, the discourse is ideally



Murcia and Sheffield 421

interactive/dialogic - that is many voices and ideas. Achieving this depends on the use
of open questions that allow a range of ideas to be presented. Longer wait times and
non-evaluative teacher responses encourage more students to participate in the
conversation. While exploring a concept, students should be constructing a scientific
understanding. At the explain phase it is then expected that the communicative
approach becomes increasingly interactive/authoritative; still many voices but each
talking about the accepted scientific view or idea. Making this transition requires
teachers to use more closed questions to focus and direct the conversation towards the
desired outcome or scientific conception. Teacher feedback to student responses
should be evaluative in order to clarify understanding and avoid any confusion as to
which is the accepted scientific idea (Hackling et al., 2010).

The IWB and discourse research project

The current research project reported in this paper used the Mortimer and Scott (2003)
and Hackling et al. (2010) frameworks in conjunction with action research principles to
explore the impact of interactive whiteboard (IWB) technology on the nature of
discourse in primary science.

The participating teachers

The project ran for one year within a school cluster that included three primary schools
and a high school. Each school nominated two teachers who were already using an
IWB or interested in having one provided and fixed in their classroom. There were six
primary school teachers and two high school teachers participating in the project.
From this group, four primary school teachers (from two schools) were selected for the
case study research, as the focus of the study was the primary level and these four
teachers completed all aspects of the project. Pseudonyms were assigned to each
teacher for the purpose of the research and reporting.

School One: Janet and Lucy
Janet was teaching a Year 5/6 split class (ages 10 to 11). The Primary Connections
science topics programmed for the year included Spinning in Space and Earthquake
Explorers. Janet had been using interactive whiteboard technology in her classroom for
two years prior to the project. She had used the technology for accessing the Internet
and engaging students with online activities and videos.

Lucy was teaching a Year 6/7 split class (ages 11 to 12). Like Janet, her science program
was focused on Earth and Beyond outcomes from the Western Australian Curriculum.
Lucy and Janet worked collaboratively during the project and shared ideas and
resources. Lucy used the Earthquake Explorers unit first and followed with Spinning in
Space. Lucy had experienced IWB technology and as such was keen to have one
installed in her classroom. She stated, “It is the way teaching is going. Technology is a
big part of the students’ lives and we as teachers need to begin incorporating more
technology into our lessons”.

School Two: Elli and Tania
Elli was teaching a Year 6 class (aged 11). The Primary Connections science topics
programmed for the year included Package it Better, It’s Electrifying and Marvellous
Micro-organisms. Elli had been using interactive whiteboard technology in her
classroom for five years prior to the project. She reported that on average she



422 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

integrated the IWB into 80% of her teaching. Elli explained that she used the IWB to
access web-based interactive activities and for promoting student engagement.

Tania was teaching a Year 5 class (aged 10). She initially started the year working in
the Life and Living strand on Mini-beasts. Her science program then included Primary
Connections units Its Electrifying and Smooth Moves. At the start of the project Tania had
just received an IWB, which was permanently fixed to the wall in her classroom and
she had not yet started to use it in her teaching.

Action research and teachers’ professional learning

Action research principles contributed to the structure of the IWB and Discourse
Project. Weinstein (1995) describes action research as a way of learning from our
actions and from what happens around us by taking the time to question and reflect on
this in order to gain insights and consider how to act in the future. The project
structure aimed to facilitate practical action, based on the learning needs and interests
of the participating teachers, while supporting the teachers’ professional learning
about IWB technology and discourse in science. This was particularly important given
the range in IWB technology experience amongst the participating teachers. The action
research approach contributed to building a research partnership with the teachers in
which their prior and diverse professional experiences, knowledge and classroom
expertise were recognised, drawn from and built on to. This process contributed to the
development amongst the participating teachers of a sense of critical reflection or
questioning of existing perspectives of teaching and student learning. Throughout the
project teachers were encouraged to act as critical friends to their school-based partner
and then more broadly to the whole project team. There was a dual focus, firstly on
action in the form of change and then research in the form of understanding (Murcia,
2005). The project was intended to be a flexible and participatory process, alternating
between planning, acting, describing and critically reflecting. The teachers were able to
contribute to the research by sharing and reflecting on their practice in the science
classroom. This occurred when researchers visited the teachers at their school and at a
series of IWB Hub meetings held at intervals throughout the school year.

The IWB Hub meetings were critical to maintaining the momentum of the project, as
well as teachers’ attention to discourse strategies and their development of IWB skills.
Teachers received expert input at points of need both from the researchers and an
interactive technologies education consultant from industry. Teachers also received
three full days of professional learning in relation to inquiry-based science, discourse
in science and IWB skills development in which interactive pedagogies supporting
substantive science discourse were emphasised. A session for debriefing project
activity was included in each meeting and was guided by the following question set:

• What has my class been doing in science since our last meeting?
• What have I been doing on the IWB in my science lessons?
• What have I noticed about my students’ learning when I used the IWB in the

science classroom?

In addition, an online research site was developed to further support the teachers’
professional learning and to provide access to digital resources. This research site was
password protected and only available to members of the research team as it contained
video of classroom action and invited feedback through a discussion forum.



Murcia and Sheffield 423

At a mid-point in the project the teachers had the opportunity to demonstrate to the
research team the IWB science notebook they had developed to support a Primary
Connections unit. These demonstrations resulted in IWB skill sharing amongst the
teachers and generated professional reflection. The teachers provided constructive
feedback on each interactive notebook design and its implementation in the classroom.
Group discussion was focused on the teachers’ scaffolding of communicative
approaches matched appropriately to each stage of inquiry. The teachers were later
given time to redesign and further expand their approach to IWB notebook
development in the context of a second Primary Connections unit. The final IWB Hub
meeting was used to celebrate teachers’ work and completion of the project. Industry
partners, representatives of each participating school’s executive group and members
of the science education community were invited to attend the ‘Showcase of Teachers
Creativity’. Each teacher presented interactive examples from their Primary Connections
science notebooks and shared their personal learning journey experienced as a member
of the project team.

Video capture and analysis
The technology based and interactive nature of the IWB learning environment
required video recording of classroom action in order to capture and explain the
dynamic modes of learning and teaching, and the surrounding discourse in primary
science lessons. The participating teachers were filmed at the start of the project,
delivering a Primary Connections lesson without using the IWB. This pre-IWB
intervention lesson provided the baseline data for discourse analysis. At the conclusion
of the project after teachers had participated in IWB Hub Meetings and the research
training days as part of the action research process, they were again videoed but this
time using the IWB as they delivered a science lesson. The post IWB intervention
lesson was matched to the phase of inquiry addressed in the pre IWB lesson recording.
This allowed for a direct pre- and post-IWB intervention comparison of discourse to be
made in a particular phase of science inquiry.

Careful consideration and management of the video capturing of science lessons was
maintained throughout the project. Video recordings of science lessons were made
using a single camera with a wide angle lens placed at the back of the classroom out of
the students’ line of sight. This camera was fixed on a tripod to minimise its influence
on classroom activity. The teachers wore a lapel microphone linked to a receiver on the
camera so that a clear audio recording was obtained. A second desktop microphone
also linked to a receiver on the camera was used to capture student talk during whole
class discourse.

Field notes from lesson observations were used to write brief lesson outlines and to
identify the phase of inquiry and intended instructional purpose of the lessons.
Segments of video recordings that showed parts of lessons involving whole-class
discussion about science were viewed and the talk transcribed using NVivo software
(QSR International, 2008). Each segment was then referred to as an episode of whole
class substantive science discussion. Some episodes included talk about classroom
procedures and included the teacher giving instructions about tasks. These were not
transcribed and did not contribute to the data for analysis. In each of the episodes of
whole class substantive science discussion, the incidence of communicative approaches
and discourse moves used by the teacher (e.g., types of questions and wait time), and
the nature of students’ participation in classroom talk were coded into ‘nodes’ or
categories using the NVivo software. The validity of the coding scheme was first
checked by a group of five researchers working within the same conceptual framework



424 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

for discourse analysis. Definitions were clarified and illustrative examples of each
coding node were obtained. Coding into discourse nodes was then completed for both
the pre- and post-IWB intervention lessons from each participating teacher.

The purpose of this paper is to show some preliminary results from the analysis
summary across the four case studies rather than an in-depth analysis of the discourse
in each teacher’s classroom. This preliminary analysis is firstly contextualised with the
interactive pedagogies observed in the teachers’ classrooms and discussed in both the
professional learning hub meetings and post lesson semi-structured interviews.
Interviews with the teachers and their reflections during the professional learning
sessions are used to show how the IWB technology facilitated changes to their
pedagogy and facilitation of whole class science discourse.

Interactive pedagogies and discourse in the primary science
classroom
As with any other classroom resource or technological tool, it is what the teacher does
with an IWB that is far more important than the technology itself. Higgins et al. (2007)
shares this view; “good teaching remains good teaching with or without the
technology; the technology might enhance the pedagogy only if the teachers and
pupils engaged with it and understood its potential in such a way that the technology
is not seen as an end in itself but as another pedagogical means to achieve teaching
and learning goals” (p. 217). Technology-led initiatives in education are often not
accompanied by an adequate understanding of the technology’s impact on pedagogy.
Evidence from the initial uptake of IWB technology could support this inference
(Warwick & Kershner, 2008). The tool has been observed complementing traditional
teacher-led, whole class learning where the IWB is simply used as a surface for writing
notes or projecting images. Yet teachers using effective interactive pedagogies do
much more as they become “critical agents in mediating the technology to provide a
more dynamic, interactive and appropriate learning experience” (Rudd, 2007, p. 6).

In this project, features of the IWB software were used by the teachers to enhance
interactivity between themselves, the learning resources and the students. They used
software tools and simple design techniques to promote active learning with
manipulations such as drag and drop; hide and reveal; layering, colour, shading and
highlighting; annotating with digital ink, matching equivalent terms and movement
for sorting and classifying. The teachers used the IWB to facilitate an ICT rich learning
environment and to generate a social learning space that brought the whole class
together. The following seven principles of effective interactive pedagogy that
facilitated substantive whole class science discourse emerged from the teachers’ use of
the IWB.

1. Engaging and appealing interactive displays

Pictures, diagrams and photos were imported or captured by the teachers to produce
visually appealing notebooks. These were displayed on the IWB and were often
interactive as the teachers and students would edit, move objects or annotate
information at the board. Elli explained how she used colour and interesting images in
the creation of her science IWB notebook to engage students. She stated, “Colour and
images are motivating and a good guide or start to discussion. Using animations, films
and diagrams that students can interact with get the children involved and active.”



Murcia and Sheffield 425

2. Accessing online information

A range of online learning resources were accessed via links embedded by the teachers
into their interactive notebooks. Teachers selected websites that provided current
information about science concepts or provided relevant contexts or examples. They
were observed highlighting key words in the online text and underlining so as to focus
students’ thinking and talk. For example, Lucy explained, “I would bring up text on
the board, highlight points with the (digital ink) pen and discuss with the students.”

3. Linking in media files

Virtual demonstrations, documentaries and real life action, such as an earthquake
hitting a school were integrated into the classroom learning with media files held
efficiently as a notebook attachment. The teachers achieved smooth transitions
between questions and text to playing the attached media files. Janet explained, “I use
videos as a prompt for discussion. Through using a variety of mediums to present the
knowledge you can tap into children’s different learning styles. It enriches the
discussion and scientific language used”.

4. Interacting with online activities

A range of online learning resources were used to support the students’ learning while
working on the IWB. Interactive sites and games were found to be the most effective in
engaging students. Janet explained, “I use video, the gallery and online games to have
whole class discussion. With the games it’s great to have the students call out ideas
and use their books to tell the student at the board the answer. It’s loads of fun.”

5. Constructing a series of interactive activities to develop the scientific story

Teachers were designing their notebooks in a way that built connections between the
interactive activities, tasks at the students’ desks and classroom conversations. The
IWB notebook not only contained interactive activities but also well-structured,
purposeful questions and clear diagrams and instructions for exploration at the desk.
The notebook shaped and represented the learning journey which supported students’
development of the scientific story. Lucy explained, “It helps my teaching because I
can do a whole program or a plan on a notebook and each slide just follows on. I’ve
got my questions there. My lessons are organised, a lot more organised. It’s set out, the
expectations for the students are there and they can see them in black and white on the
board. Resources that were unavailable to us before are now; we can use them by
accessing the Internet. Instead of me trying to photocopy pictures or find pictures in
books.”

6. Reviewing learning

The connected nature of the interactive notebooks allowed the teacher and or students
to move quickly from one page of the learning experience to another. This allowed the
content of the lesson to be easily reviewed or connections to be made to previous
activities. Elli explained how she used the IWB to support her questioning and
students’ review of their investigations. She said, “There were other things happening
on the board, like predicting what we think might happen. What circuit worked and
what didn’t work. Then having the children draw circuits on the board and looking at



426 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

different parts of circuits and asking what’s different about each, why this one worked
and that one didn’t work. I was getting the children to pose questions as well.” Tania
also valued the use of the IWB for reviewing student learning and consolidating
concepts explored in the hands on investigations. She explained, “They (students)
were excited when they knew they were going to have science because they were
waiting to see what sort of things were going to happen on the IWB for that lesson. We
still did hands on investigations but they liked to come back to see what was on the
IWB and how it related to what they were doing. Also, it helped them to see their
answers come up on the screen.”

In addition, Lucy was beginning to explore the record function in the interactive
whiteboard software and using it as a tool for capturing the students’ talk surrounding
their actions on the IWB interactive task. Recordings were being saved as a media file
and later reviewed by the students and Lucy. This interactive pedagogy was extending
the options available to students for showing and sharing what they knew about
science. Lucy explained, “the students had been talking about how day and night
occurs, and so as part of their presentation back to the class I asked a few students to
come up and they actually drew on one of the slides what they thought day and night
was and how it happened. But we also used the record button to record exactly what
they were drawing and exactly what they were talking about.”

7. Using IWB tools to increase wait time

The project teachers explored a range of IWB tools and interactive pedagogies to
promote and support their facilitation of classroom discourse. For example, Lucy said,
“I now tend to list a lot of my questions on the IWB, hide them with different
techniques that the interactive whiteboard allows and then they’re there if or when I
need them. If I don’t need some questions then I can skip over them”. The teachers
were observed using a range of IWB tools for enhancing questioning techniques and
strategies. These included the use of the screen and spotlight functions, which they
used to increase the wait time after a question and provide space for students to think.
Lucy further explained, “you might have the answers hiding under the screen but you
just want the kids to think about it before you bring it up. Students need a lot of
prompting from time to time. So using the screen again or the hide and reveal or click
and reveal activities, just helps them. It gives them extra time and you see the students
think, oh yeah, I’ve got another idea.” Teachers also used the screen or spotlight over
an interactive whiteboard display to assist in focusing students thinking and talking to
the key ideas in a science lesson. Interactive activities incorporating simple hide and
reveal strategies were also used.

Exploring the impact of an IWB action research intervention on
science discourse

The action research methods used in this research provided an insight into how
teachers used interactive pedagogies with the IWB to facilitate whole class science
discourse. The holistic view of the classroom gained from repeated observations, video
capturing and interviews showed how teachers’ used the technology to mediate the
discourse process. The impact of these practices was then explored across the four case
studies through the coding of discourse types and teacher strategies. This broad
approach to the initial discourse analysis highlighted emerging trends in the data.



Murcia and Sheffield 427

To begin, the frequencies of communicative approaches, student participation types,
quality of student talk, and teachers’ questioning and wait time were determined
through NVivo queries and compared pre- to post-IWB intervention. This provided
evidence of the impact of the IWB intervention on discourse in the science classroom
across the four case study teachers. Any changes in the discourse in these science
classrooms would have been contributed to by both the use of the IWB technology
during the lesson and also the professional learning the teachers experienced as a
member of the research project. The descriptive analysis displayed in Tables 1 to 5 is
based on the video data and coding for the four case study teachers’ matched pre- and
post-IWB intervention lessons. When videoed Lucy and Elli were working at the
engage phase, Janet at the explain phase and Tania at the explore phase.

Communicative approach

The episodes of whole class science discussion within the videoed lessons aggregated
across all four classrooms increased in number from 26 to 34 in total and these became
increasingly interactive post-IWB intervention, as shown in Table 1. Teachers were
requiring more students to participate in the discussion when using the IWB as shown
by the increased percentage of episodes that were interactive, either combined with
authoritative or dialogic talk post-IWB intervention (81% to 94%). Talk was more often
than not dominated by a single idea, which was appropriate in the explain phase
lesson, but in the engage and explore phase discourse would ideally be more dialogic.
While looking more closely at each episode within the summary it was evident that
teachers were shifting from one communicative approach to another as the lesson
progressed. For example Lucy’s post intervention ‘engage’ lesson started interactive-
dialogic but became increasingly interactive-authoritative as the class focused on the
scientific explanation of night and day.

Table 1: Percentage of episodes of various communicative
approaches pre and post IWB intervention

Pre-IWB
(without IWB)

Post-IWB
(with IWB)Communicativeapproach No. % No. %

Interactive-authoritative 9 35 16 47
Non-interactive-authoritative 5 19 2 6
Interactive-dialogic 12 46 16 47
Non-interactive-dialogic 0 0 0 0

Student participation

As shown in Table 2, the teacher required greater student participation in classroom
discussion when teaching with the IWB. The frequency of episodes in which more than
five students contributed to the discussion rose from 9 to 21 post-IWB intervention.
Not only were more students contributing, but the number of instances when students
elaborated statements comprising more than 50 characters of transcript also increased
from 3 to 18. Yet the majority of these student contributions were in response to a
teacher’s question or request for a response. There were only four examples across all
of the eight videoed lessons when students contributed an idea without prompting
from the teacher and only one example of a student-initiated question.



428 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

Table 2: Frequency of student participation pre and post IWB intervention

Student participation Pre-IWB (without IWB)frequency (n)
Post-IWB (with IWB)

frequency (n)
More than five participating students 9 21
Elaborated utterances 3 18
Student initiated talk (idea) 0 4
Student initiated question 1 0

Quality of student talk

The overall quality of the student talk was higher in the post IWB intervention lessons,
as seen in Table 3. The lessons taught by the teachers while using the IWB had a higher
percentage (13%) of student argumentation-reasoning type statements. There were 55
examples from the four IWB lessons in which students made or justified a claim. These
included examples were students used evidence to support their claim or ideas. The
occurrence of student exploratory talk also increased from 7% to 16% of the total talk
contributed by students. This included students exploring ideas as they talked,
clarifying and shaping thinking or trying out ideas while talking to others. Students’
exploratory talk was directed towards the teacher as there was only one instance of a
student directing their ideas to another student during a whole class conversation. The
majority of the whole class substantive science discourse across the four classrooms
continued to be predominantly of low quality with frequent one-word responses from
the students.

Table 3: Frequency of quality student talk pre and post IWB intervention

Pre-IWB (without IWB) Post-IWB (with IWB)Quality of student talk No. % No. %
Argumentation-reasoning 8 3.0 55 13.0
Exploratory talk 19 7.0 71 16.0
Student to student 0 0.0 1 0.5
Other (low quality) 244 90.0 304 70.5

Teachers’ question types

The number of questions asked by teachers doubled post-IWB intervention across the
four lessons, as shown in Table 4. It was evident from the data that closed questions
contributed a smaller proportion of the total number of questions posed by the
teachers during lessons with the IWB. Alternatively, the teachers’ use of open
questions increased post-IWB intervention. When using the IWB there were a greater
percentage of open questions posed by the teacher which aimed to elicit a range of
student ideas. The percentage of open ideas questions rose from 46% to 59%. The
percentage of open questions that required students to describe or explain an idea also
increased, that was from 3.5% to 10.5% when the IWB was in use. Teachers were
observed following up a student answer or comment and asking them to explain their
thinking or provide evidence for inferences that may have been made. It was evident
from classroom observations and analysis of the video data that the type of question
posed by the teacher directly affected the students’ responses. The teachers used closed
questions for two main purposes - mostly to check students were understanding ideas
and instructions, but also to clarify and focus students’ thinking on a single science
concept.



Murcia and Sheffield 429

Table 4: Frequency of teachers’ question type pre-IWB and post-IWB intervention
Pre-IWB (without IWB) Post-IWB (with IWB)Question types No. % No. %

Closed 50 41.0 54 21.0
Open description 9 7.5 21 8.5
Open explanation 4 3.5 27 10.5
Open ideas 56 46.0 151 59.0
Open reason-justification 3 2.0 2 1.0

Teachers’ use of wait time

The number of wait times greater than a count of ‘one and two’ increased when
teachers were working with the IWB, as shown in Table 5. They were observed using
tools in the IWB software to increase the wait time, which increase the space in the
lesson for students to think. Teachers also used extended think time strategies such as
‘think-pair-share’.

Table 5: Frequency of teachers’ wait time strategies pre and post IWB intervention

Wait time Pre-IWB (without IWB)frequency (n)
Post-IWB (with IWB)

frequency (n)
Extended think time strategy 5 9
Extended wait time 4 30

This preliminary analysis and data summary illustrated emerging trends in the nature
of discourse in the IWB primary science classrooms. It is intended that these trends
will be used in the next stage of the research to further examine the data at a case level.
Exploration of the data at a case level would represent the individual teachers’
development of IWB supported discourse moves and how these impacted on the
nature of talk in their science classroom.

Conclusion
In summary, the project teachers used the IWB technology as a tool for embedding
ICTs into whole class science learning. Teachers and students participated in public
discourse as they engaged with the wide range of multimedia activities and
representations brought to the science classroom through the IWB technology.
Selecting appropriate interactive resources and materials supported the teaching and
learning purpose of each stage of the 5Es inquiry model and encouraged students to
engage in whole class substantive science discussions. Teachers’ use of different
question types, responses and wait time matched appropriately to the phase of enquiry
facilitated substantive conversations in the science classroom. The designing of an
interactive notebook for the Primary Connections unit being taught assisted the teachers
to structure the learning, focus students’ attention and to facilitate substantive science
discourse.

Comparing video captured lessons, matched in the stage of science inquiry and then,
with and without the use of the IWB provided evidence of some increase in the
amount and quality of student talk in whole class science conversations. Teachers were
found using more open questions, greater wait time and requiring more reasoning and
exploratory talk from students. This research provided evidence of teachers’ effective
IWB pedagogy impacting positively on the way students talked about science. The



430 Australasian Journal of Educational Technology, 2010, 26(Special issue, 4)

contribution of the professional learning the teachers received through the project’s
action research structure should not be underestimated. The increase in the quality of
whole class science discourse during teaching and learning with the IWB should not
only be attributed to the tools of the technology but also to the teachers’ development
of effective interactive pedagogy that focused on discourse.

The Australian national priority on ICT integration in education acknowledges that
students need greater access to, and more sophisticated use of ICT, but also that well-
trained teachers are essential to achieving this outcome. The findings of this case study
research should not be over generalised, but in the context of the four teachers’
primary science classrooms the use of interactive whiteboard technology enhanced
student learning opportunities on the social plane of the classroom through whole
class discourse practises. Consideration should now be given to teachers’ professional
learning that extends the principles of effective interactive pedagogies identified in this
project more broadly. Exploiting the potential of IWB technology for scaffolding deep
substantial discourse is essential in contemporary science learning and teaching that
aims to achieve scientific literacy.

It has been recognised in this paper that interactive whiteboard technology is only as
effective as the pedagogy that surrounds it. Teachers should be supported in their
professional learning as they integrate new technology into their daily classroom
practice. Research evidence must be considered and used to inform the development
of interactive science resources and the associated approach to professional learning.
Evidence based frameworks and strategies for effectively integrating interactive
whiteboard technology will assist in increasing the depth and quality of discourse in
the science classroom. A design model is recommended for developing interactive IWB
notebooks for use in primary science classrooms. The model used in this research can
be useful for developing original interactive dialogic science units that promote quality
discourse matched appropriately to the phase of inquiry. Developments of this nature
could enable teachers to not only use an IWB to support their existing pedagogies, but
also to explore possibilities which ideally transform classroom practice and digital
students learning opportunities.

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Dr Karen Murcia
Senior Lecturer, School of Education
Edith Cowan University, WA 6027, Australia
Email: k.murcia@ecu.edu.au
Web: http://www.ea.ecu.edu.au/staffdir/profile.php?id=0000001761

Dr Rachel Sheffield
Lecturer, School of Education
Edith Cowan University, WA 6027, Australia
Email: r.sheffield@ecu.edu.au