rodrigues


Australian Journal of 
Educational Technology 

1999, 15(2), 136-147 

 
 
Using CD-ROMs in teaching science: 
Findings from a small scale study 
 
S. Rodrigues, G. Chittleborough, A. Gooding, T. Papadimitropoulos, V. 
K. Varughese, S. Kemp, J. Sadler, M. Gilmour, B. McKenna and S. Helme 
University of Melbourne 
 

This paper reports on data collected through 52 surveys investigating teachers’ 
use of CD-ROMs. The paper indicates that while teachers are familiar with the 
commonly voiced potential of CD-ROMs and recognise CD-ROM features of 
merit, the majority of teachers have yet to realise CD-ROM potential in the 
reality of their classroom. For many teachers issues of access to hardware or 
software continue to dictate their practices, where location rather than resource 
levels have established use. Consequently CD-ROMs have been promoted in 
terms of individual student assignments and other strategies involving whole 
class or group work have not been implemented. 

 
Introduction 
 
Information and communication technologies (ICT) such as dataloggers, 
the Internet, modelling, simulations, CD-ROMs and spreadsheets are 
commonly advocated for use in science classrooms (Brooks and Brooks, 
1996; Rodrigues, 1996). For many teachers, the cost of datalogging kits 
and the difficulty in programming for modelling has limited the 
inclusion of these technologies in classroom practice. Similarly the cost, 
quality of access and the time to access relevant information has made 
Internet use within classroom time equally difficult. In contrast, CD-
ROMs are thought to provide inexpensive access, quick and easy search 
mechanisms and a wealth of data in various forms (Brooks and Brooks, 
1996). User-centred interactive environments are thought to have the 
potential to encourage students to become proactive learners (McCarthy 
1989; Kozma, 1991; Harwood and McMahon, 1997) in a self-pacing and 
non-threatening environment. It is also possible that the interactive 
illustrations and links found in CD-ROMs could help students to 
contemplate the symbolic world of equations and formula, the 
macroscopic world of everyday  substances  and  laboratory  practices  as  
 



Rodrigues et al 137 

well as the microscopic world of elementary particles (Brooks and 
Brooks, 1996). Simulations, often found in CD-ROMs have also been used 
in the development of science concepts dependent on graphical data 
(Trumper 1994; Lazarowitz & Huppert, 1993). The particular value of 
simulations in a constructivist environment lies in their ability to provide 
a variety of contexts with a minimum of expenditure. An added bonus 
stems from ethics issues, where students have ethical concerns or loathe 
dissecting animals. Kinzie, Strauss and Foss (1993) and Strauss and 
Kinzie (1991) demonstrated that a simulation of a frog dissection was as 
potent as a 'real' dissection in terms of promoting learning about frog 
anatomy and dissection procedures. 
 
Overall, it has been argued that the impact of CD-ROMs is four fold. 
They encourage robust concept development (Kearsley 1988; Gorsky and 
Finegold, 1992; Jones, 1994), influence different learning strategies 
(Marchionini 1988; Kirschner and Huisman, 1998), promote 
interconnectedness of knowledge (Costanzo 1988; Jones, 1994) and foster 
learner control (Trotter 1989; Harwood and McMahon, 1997). Therefore 
in theory there are several reasons why chemistry CD-ROMs could be 
effective tools when learning science. However, like practical work, 
motives for using CD-ROMs vary. 
 
Some of the many motives for using practical work in science classrooms 
relates to the perceived ability of practical work to illustrate or confirm 
scientific theory and its ability to help distil insight into scientific 
phenomena (Hodson, 1988). Others believe that practical work provides 
a more meaningful learning experience in comparison with rote learning 
(Hodson, 1988). Many of these beliefs and perceptions are being mirrored 
in the cited potential of CD-ROMs. There is a belief that the 
interactiveness and animations found in CD-ROMs will provide 
meaningful learning environments that could help distil insight into 
particular phenomena while providing subservience to the theory being 
touted in the classroom. For example, numerous visualisation techniques 
are available that allow, for example, students to play back and analyse 
the motion of objects (see Pearce, Livett and Rodrigues, 1998; Chaudhury 
and Zollman, 1994). Maor and Taylor (1995) suggested that scientific 
databases could provide students with scope to engage in scientific 
inquiry and become involved in negotiating meaning and producing 
creative research questions.  
 
 
 
 
 



138 Australian Journal of Educational Technology, 1999, 15(2) 

While there is a large body of research literature reporting on practical 
work in science classrooms in terms of teachers’ pedagogical content 
knowledge, there is little available with respect to the use of information 
communication technologies. The potential of CD-ROMs is very 
dependent upon teachers’ pedagogical content knowledge, rather than 
simply the format and content of a CD-ROM. 
 
Teachers’ prior practices and routines influence changes teachers make in 
their classrooms to accommodate technology (Miller and Olson, 1994). 
Evidence from Apple Computers’ effort to integrate education 
technology into classroom practice indicates that full advantage of the 
available technology did not eventuate until the project was almost three 
years old, allowing time for teacher change (Dwyer, 1996). According to 
Miller and Olson (1994) teachers tend to modify the technology to fit 
their teaching styles rather than modify their teaching style. Cuban (1986) 
suggested that the introduction of technology to classrooms often adopt a 
cyclical pattern: 
 

1. initially reformers introduce the innovation,  
2. academic studies demonstrate the effectiveness of the 

innovation in comparison with conventional strategies,  
3. complaints about incompatibility and or imperfection are voiced,  
4. infrequent use of the technology occurs 
5. administrators are criticised for minimising access and teachers 

criticised for intransigence. 
 
In this paper we document some teachers reported use of CD-ROMs in 
science education with a view to determining what, if any, changes in 
pedagogical content knowledge (Shulman, 1987) are signalled when a 
formal effort to integrate ICT use does not exist. Yet, even though there is 
fairly widespread availability with respect to CD-ROM use in schools, 
and there is much cited about the value of these technologies in learning 
science, there is limited reporting with respect to teachers’ perception of 
and use of these technologies as classroom tools. Though quite clearly, as 
McLauglin and Talbert (1990) have already suggested, effective teaching 
would depend on how teachers think and feel about what they do. 
 
In this paper we report on how teachers think and feel about the use of 
CD-ROMs in teaching chemistry. The paper also reports on teachers' 
reasons for using CD-ROMs and the manner in which they currently 
deploy CD-ROMs in their classrooms. 
 
 
 



Rodrigues et al 139 

Methodology 
 
The data presented in this paper originates from a sample drawn from 
various groups of science teacher who voluntarily completed surveys. 
The sample includes teachers who were mentors to students during final 
student-teaching rounds, teachers who attended a science teachers' 
conference and teachers who attended an ICT professional development 
day. Of the fifty mentor teachers contacted, 18 completed surveys, the 
rest indicated they did not use CD-ROMs. Seventy teachers attended the 
ICT day, 25 teachers completed surveys and the rest stated that they did 
not use CD-ROMs. Nine teachers at a science teachers' conferences 
voluntarily completed surveys. Hence in total 52 teachers voluntarily 
completed surveys. The findings from the surveys were coded to reflect 
the teacher sample. Hence teachers attending the ICT day were given a 
code ICT and a number to identify the teacher, the remainder of the 
sample, (science teacher mentors and science teachers at the conference), 
were given a code RTS (remaining teacher sample) and a number to 
identify the teacher. The surveys sought to document science teacher 
pedagogical content knowledge by asking the teachers to reflect on their 
own lessons and articulate the 'what?' 'how?' 'where?' and 'why?' of their 
teaching involved the use of CD-ROMs. The surveys were based on 
surveys used by Lehman and Brickner (1996) in their investigation into 
36 teachers’ use and perception of interactive videodiscs in the science 
classroom, and the surveys used by Germann and Barrow (1996) in their 
investigation into 635 teachers use of computer technologies in science 
classrooms. 
 
Once the surveys were completed and coded to identify the source, a 
team of researchers comprised of classroom teachers, student teachers, 
academics and educational researchers collated the data. The teams 
worked in two groups of four to identify themes and to classify the 
teachers’ responses. Each group then presented their criteria, analysis 
and themes to the other group. Discussion ensued until consensus was 
reached with respect to the criteria and classifications.  
 
Findings 
 
The fifty-two surveys were completed to various degrees. The majority of 
those teachers who completed the survey had significant teaching 
experience. Over two thirds had been teaching for more than seven years.  
 
 
 
 



140 Australian Journal of Educational Technology, 1999, 15(2) 

Group government non-government no response 
ICT 16 7 2 
RTS 13 12 2 
Total 29 19 4 

 

Table 1. Teachers and their school 
 
In general the ICT sample group perceived themselves to have a high 
levels of ICT skills, whereas the remaining science teacher sample either 
did not provide an indication of their skill level or considered themselves 
to be average. As we can see from table 2, only eight respondents said 
there was a school or department policy for ICT integration in science. 
 

Group yes no no response other 
ICT 4 18 3 0 
RTS 4 10 12 1 
Total 8 28 15 1 

 

Table 2. School ICT policy 
 
Interestingly, the majority of the ICT group did not have a school 
strategy or policy for ICT integration, but they were nevertheless seeking 
professional development by attending an ICT day. 
 
Findings from this small survey are documented under three broad 
areas: 
 

• Location and access of CD-ROMs 
• Features and format of CD-ROMs 
• Organisation, use and management of CD-ROMs 

 
Location and access 
 
This section reports on issues of access and location with respect to CD-
ROMs for science. One of the major issues voiced with respect to CD-
ROM use in Science was the lack of accessibility for both students and 
teachers. The issue of access did not simply imply a lack of resources in 
schools but rather, due to the location of available resources, a lack of 
access: 
 

I have the problem that many science staff have in getting access to computer 
(CD-ROM) use. Although we have fairly good computer numbers it is still 
difficult to get classes booked in. (RTS 5) 
No computers in labs. One room of computers for school: access problem. 
(RTS 25) 
No access or computer room booked out. (RTS24)  

 



Rodrigues et al 141 

The majority of teachers indicated that facilities were present but not 
necessarily available. This was a commonly voiced concern regarding 
access to rooms with computers The teachers believed there were 
benefits stemming from the use of CD-ROMs, but due to limited 
resources and time, many felt that using CD-ROMs during lessons was 
not a viable option. 
 

I think it is a very good idea, however we are limited by fund (s), time and 
resources (computers in classroom) and no network system. (RTS 4) 
Vastly superior to Internet but still has two main concerns: availability 
(under resourced government schools) (RTS 6) 

 
The lack of access to computers and thus CD-ROMs was a reflection of 
the location of the hardware rather than an indication of resource levels 
in schools. Twenty-four teachers indicated that CD-ROMs for chemistry 
were located in the school library. Just under a third of the sample did 
not have hardware available to operate CD-ROMs for chemistry classes. 
Only five teachers indicated that the CD-ROMs were located in their 
chemistry laboratory. Software storage of CD-ROMs also affected access.  
 

1 CD-ROM in library, 1 CD ROM in staffroom (ICT 26) 
CD-ROMs are kept in computer labs for IT students in one lab (ICT 20) 
CD-ROMs are kept: in Science department prep area. (ICT 16) 

 
Consequently, the main use of CD-ROMs for Chemistry involved student 
research tasks. Teachers provided CD-ROMs as an alternative to 
textbooks or videos, mainly for student assignments and CD-ROMs that 
were not readily available were rarely used. Therefore the location of 
hardware and software is having a marked impact on the use of CD-
ROMs in science classrooms. 
 

Features and formats of CD-ROMs 
 
The following is a ranked list of criteria that teachers used to purchase 
CD-ROMs. The most commonly cited reason is listed first. Teachers 
purchased CD-ROMs because of their: 
 

• relevance to the curriculum, topic, and level  
• ease of use 
• interactiveness  
• price 
• multimedia aspect 
• factually correct information 
• accompanying support material 
• technical compatibility 
• student interest, Australian product, awards or recommendations 

 



142 Australian Journal of Educational Technology, 1999, 15(2) 

The manner in which teachers made use of these features of the CD-ROM 
would provide a clue with respect to changes in pedagogy to suit the 
technology or whether technology was being used to fit existing teaching 
styles. Teachers commented on numerous aspects of CD-ROMs (Table 3). 
 

 
 

Table 3: Teachers' view regarding features of CD-ROMs 
 
Most teachers identified CD-ROM benefits either in terms of their 
significance to particular topics or their ability to provide support for 
student learning. Consequently more than half signalled that they 
promoted the use of CD-ROMs in student assignments. Many teachers 
suggested that CD-ROMs were valuable resource materials but the 
reason for this perceived value varied: 
 

1. Quality of information 
 

Download pictures etc for assignments (RTS 8) 
Access to information for assignments (ICT 13) 
Broadens student research base (RTS 1) 
To help students learn challenging ideas (RTS 20) 
Make it more interesting not so teacher orientated (ICT 24) 
Strengths not available through other learning media 
Makes modelling easy (RTS 5) 
Enhances visual displays (ICT 9) 
For the diagrams to show things you cannot usually see (RTS17) 

 
2. Interactiveness and option for self pace 
 

Self paced learning (ICT 8) 
Learner interactive (RTS 7) 
More engaging for all students (RTS 7) 
Interactive, provide instant feedback (ICT 11) 
 



Rodrigues et al 143 

3. CD-ROMs complemented their style of teaching:  
 

To complement existing materials, provide a different point of view 
(RTS11) 
To reinforce topics covered in class or introduced previously (ICT 19) 
To give repetitive practice at completing exercises (ICT 19) 

 
Organisation, use and management of CD-ROMs 
 
Teachers were asked to indicate the role of CD-ROMs in their teaching 
and learning environments. To what extent and how was teaching style 
changing? These questions were investigated in terms of the manner in 
which CD-ROMs were used with respect to task set and with respect to 
management issues. Seventeen teachers indicated that they used CD-
ROMs in lesson planning, but twenty-three teachers did not use CD-
ROMs in planning for lessons. Twenty-five teachers indicated that they 
did not use worksheets with CD-ROMs. Twenty teachers stated that CD-
ROMs did not save teachers time, and twenty-three teachers were 
undecided. 
 
The majority of teachers (31) did not use CD-ROMs in tests or use CD-
ROMs as rewards for students who completed work quickly. The 
majority of teachers (29) did not use CD-ROMs in practical lessons. 
Management questions investigated how teachers organised CD-ROM 
use. Teachers provided numerous suggestions with regard to organising 
students working with CD-ROMs. Although the majority of teachers 
indicated that best use of CD-ROMs would be accomplished by 
individuals when conducting research for projects/assignments or when 
revising for tests. 
 

Working individually students can work at their own pace.(ICT 26) 
Library resource and individual work and projects, assignments. (RTS 21)  
Working individually students can work at their own pace. (ICT 26)  

 
But some teachers felt that opportunities to work in groups provided a 
non threatening environment that encouraged students to help each 
other during the learning process. While other teachers suggested that 
working in groups may lead to one individual taking ownership and 
overall control of the task. Some teachers stated that CD-ROM use 
depended on the nature of the task and the access to resources. 
 

Revision work individually. Assignment work, introduction to concepts 
in small groups. (RTS 6) 
Small groups when doing parts of a joint project. Individually when 
revising for tests. (RTS 31) 
Research as individual. Problem solving in groups. (RTS 1) 

 



144 Australian Journal of Educational Technology, 1999, 15(2) 

A review of teachers responses with respect to access to computers 
would indicate that teachers choice of group or individual work was a 
consequence of the availability of computers. 
 
Whole class teaching involving CD-ROMs was not widely practised. 
Overall, teachers considered CD-ROM use to be a failure when 
inadequate facilities were available, when the quality of the CD-ROM 
was poor, or when there appeared to be no real advantage over hard text 
materials. 
 
Discussion 
 
Chemistry CD-ROMs have a lot of potential, due mainly to the volume of 
inexpensive accessible data, and their ability to illustrate microscopic, 
macroscopic and symbolic level chemistry. However creating 
opportunities to use these levels effectively, depend on teachers’ 
pedagogical content knowledge. This pedagogical content knowledge 
with particular reference to CD-ROM use is still evolving. 
 
CD-ROM use in the classroom is still pedestrian. Primary use of CD-
ROM tends to be as a resource for project work. This is most likely a 
consequence of lack of available resources. Having access to hardware to 
read CD-ROMs or having quality CD-ROMs does not result in 
appropriate or effective use. Teachers were not familiar with a variety of 
teaching strategies (see for example Rodrigues and Corrigan 1998) that 
could be used with CD-ROMs in order to increase effectiveness of limited 
resources. 
 
According to Miller and Olson, (1994) teachers tend to modify the 
technology to fit their teaching styles rather than modify their teaching 
style. The survey data would indicate that teachers used the technology 
in a limited way rather than modify their teaching style to maximise use 
and effectiveness of features they identified the CD-ROMs to have. The 
number of teachers attending ICT sessions at conferences and the 
proliferation of ICT courses and materials indicates a market for teacher 
professional development in terms of ICT experience and ICT pedagogy 
practice. 
 
Clearly teachers are considering their options with respect to using ICT 
in science classrooms. However, given the survey data, professional 
development courses need to consider meeting teachers’ needs in terms 
of: 
 
 
 



Rodrigues et al 145 

• Knowing how to organise use of ICT in classrooms given a range 
of resource levels 

 
• Familiarisation and understanding of the role of various ICT 

features 
 
• ICT features that best lend themselves to contemplating the 

symbolic, the macroscopic and the microscopic worlds commonly 
encountered in science. 

 
However, without a sound conceptual framework, the use of CD-ROMs 
in science classrooms may experience the same problems that face 
practical work. Allowing students to follow poorly designed simulations 
or animations is dangerous. Furthermore, because CD-ROMs offer 
students non linear access to information, potentially the learner becomes 
more responsible for their learning process (Newmark, 1989) but learner 
control is not necessarily automatic and some learners may not simply 
require access, they may require learner guidance. Familiarising teachers 
with a range of good quality CD-ROMs and best practice teaching 
strategies should help address some of these needs. It is only through a 
review of teachers’ pedagogical content knowledge that teachers are 
likely to review their teaching style to adapt to the inclusion of ICT in a 
meaningful and enhanced manner. For teacher educators and researchers 
simply signalling the potential of ICT is not enough, signalling how to 
realise this potential in the reality of a classroom is clearly warranted. 
Instead of touting how the use of ICT enhances student learning, we 
should now be illustrating some of the most effective ways for teachers to 
use the ICT to enhance learning. 
 
This small scale research exercise reported in this paper supports the 
view expressed by Dwyer, Ringstaff, Haymore-Sandholtz & Apple 
computer Inc (1990a, 1990b), and by Harwood and McMahon (1997), that 
simply having access to computers and multimedia in schools is not 
enough in terms of affecting student learning. Advocating the use of ICT 
in classroom practice, providing resources and making available these 
resources does not result in effective use of the ICT, but accompanying 
professional development is thought to enhance the likelihood of 
effective use. Without teacher facilitation, the merits of ICT use in 
classrooms will remain illusive. Without teacher professional 
development inordinate amounts of money and time will be wasted on 
purchasing equipment that will be used in a limited manner. 
 
 
 
 



146 Australian Journal of Educational Technology, 1999, 15(2) 

References 
 
Brooks, H. B. and Brooks, D. W. (1996). The emerging role of CD-ROMs in teaching 

Chemistry. Journal of Science Education and Teaching, 5, 3, 203-215. 
 

Chaudhury, S. R. and Zollman, D. A. (1994). Image processing enhances the value 
of digital video in physics instruction. Computers in Physics Education, 8, 518-523. 

 

Costanzo, W. V. (1988). Media, metaphors and models. English Journal, 77(Nov), 28-
32. 

 

Cuban, L. (1986). Teachers and machines: The classroom use of technology since 1920. 
New York: Teachers College Press. 

 

Dwyer, D. C., Ringstaff, C., Haymore-Sandholtz, J. & Apple Computer Inc, (1990b). 
Teacher Beliefs and practices, part II: Patterns of change. The evolution of 
teachers' instructional beliefs and practices in high- access-to technology 
classrooms. First - fourth Year findings. Apple Classrooms of Tomorrow Research 
Report Number 9. 

 

Dwyer, D.  C., Ringstaff, C., Haymore-Sandholtz, J. & Apple Computer Inc, (1990a). 
Teacher Beliefs and practices, part I: Patterns of change. The evolution of 
teachers' instructional beliefs and practices in high- access-to technology 
classrooms. First - fourth Year findings. Apple Classrooms of Tomorrow Research 
Report Number 8. 

 

Dwyer, D. C. (1996). The imperative to change our schools. In C. Fischer and K. 
Yocam (Eds), Education and technology: Reflections on computing in classrooms (pp 
15-34). San Francisco: Jossey Bass. 

 

Germann, P. J. and Barrow, L. H. (1996). The use of computer technologies in 
Missouri Secondary Science Classrooms. Journal of Computers in Mathematics and 
Science Teaching, 15(3), 217-236. 

 

Gorsky, P. and Finegold, M. (1992). Using computer simulations to restructure 
students’ conception of force. Journal of Computers in Mathematics and Science 
Teaching, 11, 163-178. 

 

Harwood, W. S. and McMahon, M. M. (1997). Effects of integrated video media on 
student achievement and attitudes in High School Chemistry. Journal of Research 
in Science Teaching, 34 ,6, 17-631. 

 

Hodson, D. (1988). Experiments in science and science teaching. Educational 
Philosophy and Theory, 20, 53-66. 

 

Jones, T. (1994). Video and multimedia for math and science instruction. Journal of 
Computers in Mathematics and Science Teaching, 13, 128-145. 

 

Kearsley, G. (1988). Authoring considerations for hypertext. Educational Technology, 
28(11), 21-24. 

 

Kinzie, M. B., Strauss, R. & Foss, J. (1993). The effects of an interactive dissection 
simulation on the performance and attitudes of high school biology students. 
Journal of Research in Science Teaching, 30(8), 989-1000. 

 

Kirschner, P. and Huisman, W. (1998). Dry laboratories in science education; 
computer-based practical work. International Journal of Science Education, 20(6), 
665-682. 

 



Rodrigues et al 147 

Kozma, R.B. (1991). Learning with media. Review of Educational Research, 61(2), 179-
211. 

 

Lazarowitz, R. & Huppert, J. (1993). Science process skills of 10th grade biology 
students in a computer assisted learning setting. Journal of Research on Computing 
in Education, 25(1), 366-381. 

 

Lehman, J.D and Brickner, D. (1996). Teachers’ uses and perceptions of Interactive 
Videodiscs in the Science classroom. Journal of Computers in Mathematics and 
Science Teaching, 15(1/2), 85-102. 

 

Maor, D. and Taylor, P.T. (1995). Teacher Epistemology and scientific inquiry in 
computerised classroom environments. Journal of Research in Science Teaching, 
32(8), 839-854. 

 

Marchionini, G. ( 1988). Hypermedia and learning: Freedom and chaos. Educational 
Technology, 28,11, 8-12. 

 

McCarthy, R ( 1989). Multimedia: What the excitement's all about. Electronic 
Learning, 8 (Jun), 26-31. 

 

McLaughlin, M. W. and Talbert, J. E. (1990). The context in question. The secondary 
school workplace. In M.W. McLaughlin, J.E. Talbert and N Bascia (Eds), The 
context of teaching in secondary schools: Teachers realities. New York: Teachers 
College Columbia University. 

 

Miller. L. and Olson, J. (1994). Putting the computer in its place: A study of teaching 
with technology. Journal of Curriculum Studies, 26(2), 121-141. 

 

Pearce, J., Livett, M. and Rodrigues, S. (1998). Development and use of an on-line 
video analysis tool for physics learning. Apple University Consortium Academic 
Conference Proceedings. Melbourne University, Melbourne, 27-30 September 1998. 
CD-ROM A8G12QK4S. 

 

Rodrigues, S. (1996). Review of computer based technologies on students' learning 
school science. p62 -101. In P.C.Clarkson and R. Toomey (Eds.), Computing across 
the Secondary Curriculum: A review of research. Melbourne: Deakin University 
Printery, National Professional Development Project, Computers Across the 
Secondary Curriculum Reference Group. 

 

Rodrigues, S. and Corrigan, D. (1998). Including IT: Managing information technology 
in the science classroom. Christchurch: User Friendly Resources. 

 

Shulman, LS (1987). Knowledge and teaching: Foundations of the new reform. 
Harvard Educational Review, 57, 1-22. 

 

Strauss, R. & Kinzie, M. B. (1991). Hi tech alternatives to dissection. American 
Biology Teacher, 53, 154 -158. 

 

Trotter, A. (1989.) Schools gear up for hypermedia: A quantum leap in electronic 
learning. American School Board Journal, 176(Mar), 35-37. 

 

Trumper, R . (1994). Computer assisted teaching of physics. Journal of Computers in 
Mathematics and Science Teaching, 13(2), 183-195. 

 

S. Rodrigues, G. Chittleborough, A. Gooding, T. Papadimitropoulos, V. K. 
Varughese, S. Kemp, J. Sadler, M. Gilmour, B. McKenna and S. Helme. 
University of Melbourne, Parkville Vic 3052, Australia