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‘Unpacking the Box’: A Novel Tool to Assess the Development of Working Memory in Children.
Lisa Iranzo
Student Number: 1023459
MSc Psychology (Conversion)PS7112 Research Dissertation
2015/2016
University of Chester
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‘Unpacking the Box’: A Novel Tool to Assess the Development of Working Memory in Children.
Word count – 12,068
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Declaration
This work is original and has not been submitted in relation to any other degree or qualification.
Signed:
Date:
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With thanks to my supervisor Michelle Mattison for her assistance with this piece of research.
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Department of Psychology
Research Module Meeting Log 2016/2017
NAME: Lisa Iranzo
SUPERVISOR: Michelle Mattison
Date Discussion topics
16/03/16 Discussion about areas of interest and ideas for dissertation.
21/03/16 Discussion about going in to a school and procedure for obtaining a DBS certificate.
31/03/16 Finalising details about the context and content of the study.
12/04/16 Final decision on the content of the study and how/where the data will be collected.
130/4/16 Discussion about the resource ‘Unpacking the Box’ and how it can be studied. Ideas from previous research discussed.
15/04/16 Email contact about the Ethics form and the parental information sheet to be distributed to parents.
20/04/16 Fine tuning of the study and discussion about the method, materials and procedure.
11/05/16 Discussion about the Ethics Amendment form and further adjustments to the testing materials.
25/05/16 Discussion about distribution of opt-out letters to the school and dates for collection of data.
01/06/16 Discussion about contact with the primary school.
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08/06/16 Discussion about how to conduct the study and how to work in a friendly and productive way with the primary schoolchildren.
15/06/16 Discussion about counterbalancing tasks and data collection.
30/06/16 Discussion of issues arising from data collection.
13/07/16 Discussion of initial findings from data collection.
12/08/16 Discussion about conducting Anovas and post hoc tests using SPSS.
19/08/16 Discussion about writing up results from the study.
31/08/16 Discussion about correlational tests and how to report the data.
06/09/16 Discussion about the qualitative data and non-parametric tests.
20/09/16 Discussion about the introduction and how to develop a rationale for the study.
30/09/16 Feedback meeting and discussion about the draft dissertation.
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Table of contents
Title page and word count 2
Declaration 3
Acknowledgements 4
Supervision log 5
Table of content 7
List of tables and figures 8
1. Abstract 9
2. Introduction 102.1 The development of working memory and 11
short term memory2.2 A framework to assess working memory 142.3 The working memory model 142.4 Phonological memory 192.5 Visuospatial memory 262.6 The implications of low working memory 29
in children
3. Method 323.1. Participants 323.2. Materials 323.3. Procedure 333.4. Design 35
4. Results 35
5. Discussion 415.1Implications, Limitations and future research 54
6. Conclusion 55
7. References 56
8. Appendices 63
9. SPSS data (on separate CD)
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List of Figures and Tables
Figures
Figure 1 ‘Unpacking the Box’ 33
Tables
Table 1 Descriptive Statistics 37
Table 2 Correlations between tasks 38
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Abstract
Children’s performance on working memory tests improves with age, although
the reasons for this development are not well understood. Furthermore, the
concept of enjoyment of task has received little attention. The aim of this study
was to examine a novel tool, ‘Unpacking the Box’, which has been designed by
the charity ‘Triangle’ to assess working memory in a friendly and enjoyable way.
Children were tested using four measures; a digit span task, a Corsi block task,
a listening span task and a task using the novel resource ‘Unpacking the Box’.
A 3x2 between-subjects design was employed with primary children aged six,
seven and eight years old. A 3x2 within subjects Anova revealed a significant
main effect of age on performance of ‘Unpacking the Box’, with the greatest
differences between six and seven year olds and six and eight year olds. Non-
parametric analyses revealed high levels of enjoyment with the novel tool
‘Unpacking the Box’. The tool is currently used to work with victims who are
giving evidence in court. This study demonstrated that the novel resource is a
highly effective, practical, enjoyable and engaging method for assessing
working memory in children. As such, there are many possibilities for the future
development of ‘Unpacking the Box’ for use in educational and clinical settings.
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Introduction
Working memory is the capacity to temporarily store and process
information in order for complex cognitive tasks to be completed such as
reading (Wagner & Torgesen, 1987), comprehension and language learning
(Baddeley, 2010; Daneman & Carpenter, 1980; Kemps, De Rammelaere &
Desmet, 2000). We often have to keep pieces of information in our minds for a
short period of time, such as telephone numbers or postcodes and this ability to
store and manipulate information is a vital part of cognitive functioning (Engle,
Carullo & Collins, 1991; Gathercole, 1999). Furthermore, the material to be
maintained and processed may be in verbal form such as words or phonemes
or it may be presented in a visual or spatial form such as shape, colour, location
or a sequence of movements (Logie & Cowan, 2015).
Research over many years has proposed the notion that working
memory is not a unitary store but a multi-component system of limited capacity
whereby the components interact with each other to maintain and process
material during complex cognitive activities (Alloway, Gathercole & Pickering,
2006). As children grow older, the cognitive demands placed upon them are
gradually increased and therefore, their cognitive development needs to
increase at a substantial rate in a short space of time, in order to meet these
challenges (Spiess, Meier & Roebers, 2016). According to Gathercole,
Pickering, Ambridge and Wearing (2004), whilst there is no change in the
structure of working memory, a significant period of development showing a
linear increase in performance is evident from age four up to adolescence. In
view of the significant changes in the development of working memory, it is
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important that research is carried out, in order to develop systems for identifying
and supporting children with working memory deficiencies (Alloway, Gathercole,
Kirkwood & Elliott, 2008). The aim of the present study was to assess
children’s working memory in practitioner settings using a recently developed
novel tool called ‘Unpacking the Box’.
The development of working memory and short term memory.
Extensive research has provided evidence that short term memory is mainly an
operation of storing and later recalling information in the same order, whereas
working memory is the storage and concurrent processing of the same material
in order to complete a complex task (Berg, 2008; Daneman & Carpenter, 1980;
Alloway, et al., 2006). A significant factor in the development and capacity of
short term memory is age, with estimates of memory span almost trebling
between pre-school years and early teenage years (Gathercole, 1999;
Gathercole & Adams, 1994). There is a steep increase in the capacity and
performance of short term memory up to age eight, followed by a more gradual
rate of development up to age 11 or 12 (Nichelli, Bulgheroni & Riva, 2001).
However, it seems that when using complex measures of working
memory, such as listening span, the development may continue up to age 16.
Therefore, according to Gathercole (1999), the development of working memory
may follow a longer trajectory than that of phonological or visuospatial short
term memory. This finding concurs with the development of the frontal lobes
which are mainly associated with the capacities used in complex working
memory tasks. (Collette & van der Linden, 2002; Egami et al., 2015). Executive
functioning and performance at an adult rate are reported to be reached in late
11
childhood when certain biological processes have taken place, such as synaptic
pruning and myelination (Zhong et al., 2014).
Despite the wealth of research about working memory in children, there
still seem to be many unanswered questions and a lack of understanding about
why and how working memory develops progressively (Cowan, Saults & Clark,
2015). Some researchers believe that memory has a limited capacity with a
specific amount of availability (Cowan et al., 2015), whilst others believe it is
due to an increase in sustained attention which rapidly improves until age 10
(Betts, McKay, Maruff & Anderson, 2006). An additional explanation could be
that as children get older they get better at using strategies such as rehearsal
(Rai and Harris, 2013) and chunking (Pickering, 2001, Rossi-Arnaud, Pieroni &
Baddeley, 2006). Furthermore, it is only once they reach age eight that children
start to show a strategic use of the phonological loop (Kemps et al., 2000;
Pickering, 2001).
Many researchers have found that children below the age of seven
perform at a significantly lower rate on working memory tasks than older
children (Gathercole et al., 2004). One suggestion is that children have the
physical ability to perform certain skills such as rehearsal, but they are unaware
of the complexity of their own abilities when performing memory tasks and will
not adopt a memory strategy unless instructed to do so (Rai & Harris, 2013).
Rai and Harris (2013), adopted a Brown-Peterson task of repeating trigrams to
assess working memory in adults and children. They employed a distractor
task of orally reciting the American pledge of allegiance, which served as a valid
measure for both age groups. The results revealed that in the first condition,
where children were not explicitly directed to rehearse, they performed poorly.
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However, in the second condition where they were explicitly instructed to use
subvocal rehearsal, their performance levels were similar to those of the adults.
This would suggest that children often do not understand the need to
remember, whilst their ability to use a strategy is often immature (Rai & Harris,
2013).
It is believed that as children develop and mature, they show increasing
levels of executive functioning, such as having the ability to control their
thoughts and actions (Huizinga, Dolan & van der Molen, 2006). Furthermore,
according to Baddeley (1992), the central executive is the component which
allows an individual to focus their attention and where necessary to divide their
attention. For example, a study by Dirk and Schmiedek (2016), indicated that
Grade 4 children showed a more consistent performance in working memory
tasks from one occasion to another than Grade 3 children. The Grade 4
children also seemed to display higher levels of maturity when facing
disturbances, indicating that as children get older they develop more mature
processes for self-regulation (Dirk & Schmiedek, 2016). This finding is in line
with the concept that executive functioning develops later in children and plays
a vital role in learning and in enabling children to maintain focus (Holmes,
Gathercole & Dunning, 2009). According to Stöcktel and Hughes (2016),
executive functioning plays an important role in the control of selective or
focused attention, in addition to the control of behaviour and emotions.
In summary, it has been suggested that working memory is a
combination of the storage capacity of short term memory with an additional
processing element. One opinion is that the same cognitive function is
associated with both short term memory and working memory, with the main
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difference being that working memory refers to active rather than passive tasks
(Zimmer, 2008). According to Engle, Tuholski, Laughlin and Conway (1999),
the necessity for controlled attention leads to the use of working memory.
Moreover, what constitutes a short term memory task for some may equal a
working memory task for others, for example, children who may be less
experienced in memory strategies, such as rehearsal or chunking (Engle et al.,
1999). Therefore, whilst it has been suggested that working memory and short
term memory are different constructs, it is reasonable to assume that working
memory relies on the storage component of short term memory and that both
constructs are highly correlated (Engle et al., 1999).
A framework to assess working memory. According to Henry (2001),
the working memory model proposed by Baddeley and Hitch in 1974 provides
an effective framework for analysing the components of working memory in
children. Logie and Cowan (2015) claim that this early work by Baddeley and
Hitch represents one of the most influential additions to the field of cognitive
science. Support for the working memory model was also found in the study by
Cowan et al., (1992). Similarly, Alloway et al., (2006) found that the capacity of
working memory in children can be explained effectively by a domain-general
model such as the working memory model. According to Berg (2008), the
model proposed by Baddeley and Hitch in 1974 is one of the most widely
accepted and researched models of working memory. Therefore, this study will
refer to the components of the working memory model in order to explain the
development of working memory in children.
The working memory model. The original working memory model
created by Baddeley and Hitch in 1974 comprised three subcomponents; the
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phonological loop, which stores and manipulates verbal material; the
visuospatial sketchpad, which holds and manipulates visual and spatial
information; and the central executive, which controls attention and is assisted
by the two subsidiary systems (Baddeley & Hitch 1994). Further research led to
the conclusion that the model was incomplete and could not account for all
processes; therefore, the episodic buffer was added to the model in 2000
(Baddeley, 2000).
According to Baddeley and Hitch (1994), the phonological loop contains
a temporary storage system for speech-based material which fades after two
seconds unless a process to maintain the memory is employed. The second
subcomponent of the loop is a subvocal rehearsal mechanism, which serves to
refresh material and prevent decay (Baddeley, 2003). According to Gathercole
et al., (2004), subvocal rehearsal can enable the recoding of material presented
in a non-phonological form, such as pictures or printed words, in order for this
material to gain access to the phonological store.
Extensive research has led to the discovery of links between the
phonological loop and language learning; it is assumed that a child’s ability to
learn new vocabulary and develop their native language alongside an adult’s
ability to learn a second language is supported by the phonological loop
(Baddeley, Gathercole & Papagno, 1998; Baddeley, 2003; French & O’Brien,
2008). Furthermore, as children become more experienced in learning
vocabulary and develop a good phonological memory, they become better at
repeating unfamiliar non-words (Baddeley et al., 1998). Therefore, it appears
that the relationship between phonological memory and vocabulary acquisition
is a reciprocal one which may also link with long term memory, (Baddeley,
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1993). According to French and O’Brien (2008), phonological memory has a
significant role in the acquisition of grammatical learning and is a reliable
predictor of the development of grammatical knowledge. In summary, the
phonological loop plays a significant role in the storage and processing of verbal
material (Henry, 2012).
According to Baddeley (2003), the second slave system of the working
memory model, which is responsible for the temporary storage and
manipulation of visual, spatial and kinaesthetic material, is known as the
visuospatial sketchpad. Similar to the rehearsal mechanism in the phonological
loop, it is thought that the visuospatial sketchpad is used as a mechanism of
visualisation in order to aid the retrieval of information (Rende, Ramsberger &
Miyake, 2002). According to Logie and Pearson (1997), the two major
components of the visuospatial sketchpad comprise a mechanism for
processing visual information; the visual cache, which handles information such
as colour and shape; and a component responsible for the processing of spatial
stimuli; the inner scribe, which handles information related to the sequences of
movements.
Notwithstanding the two distinct components of the visuospatial
sketchpad, it is often difficult to differentiate between visual and spatial tasks.
Numerous studies have been conducted to test each of these components. For
example, Logie and Pearson (1997) used a Corsi Block task to assess the
spatial element and a pattern test to measure the visual component. However,
according to Gathercole (1999), it is very difficult to find a pure measure of
verbal or spatial memory. In a study by Alloway et al., (2006), children who
undertook a dot matrix task which is considered a visual task, and a block recall
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task, which is a spatial measure, performed equally well on both tasks. As all of
the tasks were conducted in a dynamic way, one explanation would be that
previous findings may not be the result of a clear distinction between visual and
spatial elements, but rather a static versus a dynamic presentation of the tasks
(Alloway et al., 2006). Nevertheless, Baddeley (2003) ascertains that the
reliance on spatial memory during a Corsi-block task has been supported by
behavioural and neuropsychological evidence. Furthermore, there is also
evidence that visual and spatial processes are separate constructs (Baddeley &
Hitch, 1994). For example, one patient who had brain damage resulting from a
car crash, experienced difficulties in completing visual tasks, however, his ability
to complete spatial tasks was unimpaired (Baddeley & Hitch, 1994). This
evidence serves as one example to illustrate the complexity of working memory.
According to Baddeley and Hitch (1994), the central executive is the
most complex and least understood component of the model. It is thought to be
an attentional control mechanism served by the phonological loop and the
visuospatial sketchpad. Therefore, the central executive is involved in
regulating the focus of attention on a task and in dividing attention between the
other components in the model (Baddeley, 2002). According to Gathercole,
Durling, Evans, Jeffcock & Stone (2008), some complex memory tasks, which
involve manipulation and storage of lengthy sentences, rely on both the
phonological loop and the central executive. Furthermore, the central executive
plays a significant role in ensuring children keep track of where they are up to in
the sequence of instructions (Gathercole et al., 2008). For example, they are
aware of which part of the instruction they have completed, and which items still
need to be performed. However, there has been minimal focus on the central
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executive amongst researchers due to the vagueness and complexity of the
concept (Kemps et al., 2000), therefore this is an area which still requires
further investigation.
In 2000, a fourth component, the episodic buffer was added to the model
(Baddeley, 2000). The episodic buffer provides a system for binding
information from different sources and enables the different components to
interact with one another and with information from long term memory
(Baddeley, 2010). It is assumed that the episodic buffer is a system of limited
capacity, and unlike the central executive, it is concerned with storage rather
than attentional control (Baddeley, 2003). According to Rossi-Arnaud et al.
(2006), the act of binding items together to form chunks is performed by the
episodic buffer. It is estimated that the capacity of the episodic buffer is around
four chunks or episodes (Baddeley, 2010). There is a clear link between
working memory and long term memory, thus emphasizing the need for the
addition of the episodic buffer (Baddeley, 2010). This can be explained by the
ability to remember four or five unrelated words but up to approximately 15
words when they form part of a meaningful sentence. This illustrates the use of
semantic and grammatical concepts, which are dependent on long term
memory (Baddeley, 2010). For this reason, Alloway, Gathercole, Willis &
Adams (1994), ascertain that the repetition of sentences serves as an accurate
assessment of the role of the episodic buffer and its capacity.
Working memory is a processing resource of limited capacity involved in
the storage and processing demands of executive function (Alloway et al., 2008;
Baddeley, 2003; Daneman & Carpenter, 1980). Many factors are thought to be
involved in the level of functioning of memory, including decay (Daneman &
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Carpenter, 1980), interference, an excess load for the capacity available
(Gathercole, 1999) or even a delay at output due to various factors such as
word or phoneme length and a longer articulation rate (Gathercole & Adams,
1994).
Phonological Memory. Reliable and widely used tests, which assess
phonological short term memory, include digit span, word recall and non-word
recall; these measures test the ability to store and retrieve information without
any need for processing or manipulation of the source (Gathercole, 1999;
Gathercole et al., 2004). Whilst short term memory does not contain any
processing demands, it plays an important role in performance in any memory
task and short term storage has been highlighted as a key component in the
relationship between working memory and fluid intelligence (Hornung, Brunner,
Reuter & Martin, 2011). Furthermore, high levels of association have been
found between proficiency in phonological awareness, namely a child’s
awareness of how sound is structured in language, and a child’s ability to read
(Wagner & Torgesen, 1987).
More complex tasks, which require processing and storage demands and
therefore test phonological working memory, include backward digit span,
listening recall (sometimes referred to as listening span by some researchers,
eg. Henry, 2001), and counting recall (Alloway et al., 2008; Alloway et al., 2006;
Gathercole et al., 2004). During a listening span task, participants have to state
whether a sentence is true or false and they have to memorise the final word in
each sentence (Henry, 2001). As this task involves simultaneous storage and
processing, it is believed that the phonological loop is responsible for the
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storage element of the task whilst the central executive is needed to enable
processing (Gathercole et al., 2004).
Children face many cognitive tasks, in the day-to-day functioning at
school and one example of such a task is following classroom instructions
(Kaplan & White, 1980). Children with a deficit in working memory generally
have more difficulty in following classroom instructions and this deficit gets
larger with age (Alloway et al., 2008). Kaplan and White (1980) recorded and
analysed classrooms interactions, and found that, on average a direction was
issued every 40 seconds. According to Bergman-Nutley & Klingberg (2014),
failure to follow instructions correctly is a clear sign of a working memory deficit,
which, in view of the quantity of instructions given in a typical lesson, could
represent a considerable problem.
The original following directions task designed by Kaplan and White
(1980), was based on the notion that the ability to follow a series of instructions
increased as children got older. In this task a list of instructions, which become
progressively longer, is read out to children, who subsequently aim to follow the
directions. For example, according to Kaplan and White (1980), the instruction
to ‘open your books’ requires one single behaviour and therefore constitutes a
single direction. The directions become more complex by adding qualifying
statements, such as, at the back of the room, or more behaviours, such as
‘open your books and answer the questions’. The test has subsequently been
used by several researchers, to assess phonological working memory (Engle et
al, 1991; Gathercole et al., 2008).
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In the study conducted by Gathercole et al., (2008), children were given
short instructions, such as ‘touch the blue eraser and then progressively longer
instructions such as ‘pick up the green ruler and put it in the red box’. Further
instructions were added by using the adverb ‘then’, to increase the number of
steps to be performed, thus increasing the complexity of the task. The findings
showed that the ability to follow directions accurately is closely linked with
working memory ability and is not just a measure of the passive verbal storage
associated with short term memory (Gathercole et al., 2008).
Whilst Kaplan and White (1980), make no specific claims about
enjoyment of the following directions task they designed, Engle et al. (1991)
refer to it as a ‘game’. The word game implies a level of enjoyment and whilst
enjoyment has not been highlighted explicitly, it is clearly a matter for
consideration. It would be reasonable to assume that if children were enjoying
an activity they would show higher levels of focus and attention, thus resulting in
a possible improvement in performance on a memory task. Furthermore,
children who show deficits in working memory are often described by their
teachers as inattentive (Alloway et al., 2008; Gathercole et al., 2008), thus
highlighting the need for engaging and enjoyable tasks to be implemented.
The benefits of using a following instructions task to improve memory
and provide training opportunities have been clearly demonstrated (Bergman-
Nutley & Klingberg, 2014). For example, Holmes et al. (2009) conducted a
study to assess the benefits of employing a following instructions style training
programme which led to an improvement in task performance of 0.94 standard
deviations. Similarly, Bergman-Nutley and Klingberg (2014) used a following
21
instructions task as a training mechanism and found that children’s performance
in mathematical tests improved by 0.89 standard deviations.
The current study involves the analysis of a novel tool, which also
addresses the issue of children’s ability to follow instructions and their working
memory ability. ‘Unpacking the Box’ is a tool aimed at developing
communication skills, which has been evolved over several years by a charity
called Triangle. The tool is intended to address issues of communication skills
with a clear focus on the requirements for a child to be able to give evidence in
criminal or family proceedings. The contents of the box enable interviewers to
develop a rapport, to check understanding of position and sequencing
vocabulary and to assess auditory working memory. The task is also designed
to help children settle quickly and to provide an enjoyable and engaging task
(Triangle, 2015).
Similarities can be seen between ‘Unpacking the Box’ and the following
instructions task as both tasks involve verbal instructions with a direction to
follow. Furthermore, both tasks require the individual to physically move objects
around and the instructions for both tasks become progressively longer in order
to measure the span for each individual.
One explanation for the improvement in working memory, as children get
older could be due to a better use of strategies available for the maintenance of
material (Gathercole et al., 2004). Items held in the phonological store decay
rapidly unless a further mechanism, such as subvocal rehearsal is used to
maintain the material (Berg, 2008). Extensive research has found that one of
the main developmental changes in the verbal memory span of children is the
22
rehearsal process (Gathercole & Baddeley, 1993; Gathercole and Adams,
1994). However, it is unusual for children under seven years of age to actively
rehearse auditory information (Gathercole, 1999; Tam, Baddeley, Sabatos-
DeVito, 2010). Furthermore, it is believed that rehearsal increases at a similar
rate to articulation, therefore it would appear that the development of children’s
articulation rate is a significant factor in the increased memory span (Gathercole
& Adams, 1994).
Numerous pieces of research have supported the link between subvocal
rehearsal and articulation rate. For example, Cowan et al. (1992) found that
participants were able to recall the same amount of words that they could
articulate in 1.5 – 2.0 seconds. Gathercole and Adams (1994) tested the use of
subvocal rehearsal by measuring children’s rate of articulation and comparing it
to their scores on a digit span test. The results demonstrated that when children
aged four were tested, a zero correlation emerged between digit span and
articulation rate, whereas a significant correlation was found in five year olds.
This would suggest that the process of subvocal rehearsal emerges at some
point between the ages of four and five (Gathercole & Adams, 1994). However,
it was also found that articulation rates did not match memory span for words,
suggesting that subvocal rehearsal was not being used for recall of this type of
material (Gathercole & Adams, 1994). This raises the question of why this
strategy would be used inconsistently. One explanation could be that children
who are nearing the end of their first year of formal schooling are very familiar
with the digits 1 – 9 and will have completed many tasks using these digits
(Jones & Macken, 2015). The level of familiarity could be important in the
children’s use of subvocal rehearsal (Gathercole & Adams, 1994).
23
There are several factors which may be involved in the functioning of
memory (Cowan et al., 1992). One possible explanation may be related to the
decay at output caused by the longer phonemes. It was demonstrated that the
effect of output delays was mainly responsible for word length effects when
assessing verbal memory via lists of words from a visual source (Cowan et al.,
1992). Similarly, it has also been found that children with low articulation rates
are likely to have a lower performance rate on verbal tasks, particularly
repetition of non-words (Baddeley et al., 1998).
The differences between short term memory and working memory tasks
mean that the longer processing time involved in working memory tasks are
likely to lead to higher levels of interference between the initial presentation of
the word and the delay in it being recalled (Cowan, Towse, Hamilton & Hitch,
2003). Therefore, in more complex tasks, other more elaborate strategies may
be employed such as remembering the word by relating it to the context (Cowan
et al., 2003). For example, in a listening span task, a possible interpretation
could be that rather than rehearsing the final word for maintenance, the word
was allowed to become inactive and consequently recall of the sentences
provided a cue for remembering the final last word (Cowan et al., 2003).
According to Daneman and Carpenter (1980), one explanation for the
differences in function supports the idea that if the storage and processing
demands exceed the available capacity, there is a trade-off between storage
and processing activities; therefore, if more storage is required, there will be a
reduction in the processing that can take place. The explanation for the
improvement in working memory as children get older reflects the idea that
children get more experienced at reading and processing with age.
24
Consequently, as processing becomes more effective, it frees up more capacity
for storage Daneman & Carpenter, (1980). However, this explanation has been
challenged by several researchers, as it would seem that the expected
outcomes resulting from a trade-off between storage and processing have not
been observed in many cases (Gathercole et al., 2004). For example, in a
study by Gathercole et al. (2008), children with a low working memory had the
ability to complete the processing tasks, such as finding the rhymes or counting
the words, although it was expected that storage would be diminished due to
their reduced efficiency in processing. However, the data from this study did
not support this theory, suggesting that there may be other explanations for the
deficits in working memory, such as executive functioning and the contributions
of the central executive (Gathercole et al., 2008).
An additional explanation is the time-based resource sharing model, as
explained by Barrouillet, Gavens, Verguaume, Gaillard and Camos (2009). This
theory also relies on the idea of attentional resources being shared between the
demands of processing and storage. However, it is thought that during pauses
in processing activities, attention is switched to provide an opportunity for
refreshment of the material (Barrouillet et al., 2009). It has been demonstrated
that where a task occupies a participant’s attention almost continuously, this
results in a decrease in performance, whilst tasks which allow for pauses and
therefore more attentional switches represent a lower cognitive load and lead to
an improvement in performance (Barrouillet et al., 2009).
According to Baddeley (2000), the processing element of working
memory relies heavily on the central executive for controlling resources and
monitoring the processing of information. Alloway et al. (2006) found a greater
25
similarity between cognitive function in verbal and visuospatial working memory
than in verbal and short term memory tasks. One explanation for this could be
that the central executive is involved in complex working memory tasks
involving both the central executive and the phonological loop or the
visuospatial sketch pad and therefore the level of executive functioning is
similar for verbal and visual or spatial tasks when processing is required
(Alloway et al., 2006).
Visuospatial memory. According to Kokubo et al. (2012), the
development of visuo-spatial working memory begins in children as young as
six and continues into adulthood with the fastest developments happening
between the ages of six and eight.
A well-established measure of visuospatial short term memory is the
Corsi blocks test; participants observe and attempt to repeat a sequence tapped
out on the blocks (Berch, Krikorian & Huha, 1998). A developmental trend
whereby span increases with age has been observed in several studies. For
example, León, Cimadevilla & Tascón (2014), tested visuospatial memory using
Corsi blocks with children aged five to ten and found a significant effect of age
on performance. However, one criticism with the Corsi blocks task concerns
the variations in the material or procedure used, for example the size or colour
of the blocks or the distance between them, which may affect performance
(Berch et al., 1998). The dot matrix task involves the participant looking at the
location of a red dot on a 4 x 4 grid and then recalling the position by tapping
the correct square on a computer screen (Alloway et al., 2006). This type of
task requires the participant to store and retrieve visuospatial information but
unlike working memory tasks, there is no element of processing involved.
26
In the study by Alloway et al., (2006), three measures to assess
visuospatial working memory which involved recall and processing tasks were
used; the odd one out task, the Mr X task and the spatial span task. In the odd
one out task participants observed a set of 3 shapes in a row and had to identify
the odd one out. At the end of each trial, the participant then had to remember
the positions of the odd shape in the correct order (Alloway et al., 2006). In the
Mr X task participants compared two pictures of Mr X and decided if each Mr X
was holding the ball in the same hand. At the end of each trial the participant
had to recall the locations of the ball in the correct order (Alloway et al., 2006).
In the spatial span task, there is also a processing requirement where the
participant has to assess the similarity between two shapes, one of them often
rotated and then recall the location of a red dot (Alloway et al., 2006). The three
tasks listed above have been described as spatial working memory tasks.
However, one of the difficulties found with the visuospatial sketchpad is
how to differentiate the visual and spatial elements of this component (Alloway
et al., 2006). It has been suggested, that it is very difficult to find a task that
relies purely on visual or spatial resources (Gathercole, 1999). It would be
impossible to remove the visual aspect of any of these tasks. Nevertheless, it
has been proposed that visual and spatial tasks may rely on different underlying
cognitive mechanisms and thus develop at different rates. These mechanisms
include techniques such as maintaining a visual representation of stimuli,
labelling items so as to give them a verbal code and engaging in subvocal
rehearsal (Kemps et al., 2000).
According to Kemps et al., (2000), there is a gradual increase in
visuospatial memory span between the ages of four and eleven. However,
27
other research has found that the increase in visuospatial span between age
five and age eleven is rapid, with children aged eleven having acquired a similar
span to adults (Wilson, Scott & Power, 1987). Similarly, Riggs, McTaggart,
Simpson and Freeman (2006), report that visuospatial capacity is thought to
double between the ages of five and ten, with ten-year-old children reaching an
adult like capacity of three to four items. Therefore, an increase in capacity
could account for some of the developmental improvements observed in
visuospatial memory.
Another explanation for the rapid development in visuo-spatial memory
could be that younger children may find it more difficult to focus their attention
and as a result may miss some of the changes (Riggs et al., 2006). Similarly,
the use of a particular strategy and the type of strategy used could also account
for some of the developmental improvement. For example, it has been
suggested that unlike verbal stimuli, which have automatic access to the
phonological loop, visual stimuli have to undergo a recoding process to gain
access (Kemps et al., 2000). It would appear that storing information in a visual
form is the main strategy employed by younger children, whilst once children
reach age eight they become more proficient in encoding the material into a
verbal form, thus adopting a phonological approach to rehearsal (Pickering,
2001). Research has indicated that children develop the use of subvocal
rehearsal for auditory information earlier than for visually presented material
(Hitch, Halliday, Dodd & Littler, 1989). Therefore, younger children who have
not fully developed the skill of articulatory rehearsal often do not recode visual
stimuli whereas older children and adults usually do (Kemps et al., 2000).
28
The process of subvocal rehearsal may work for some visuospatial tasks,
however, it has been suggested that rehearsal strategies are of no benefit in
some of the less semantic tasks such as matrix tasks (Vogel, Woodman & Luck,
2001). Furthermore, it was also found that articulatory suppression did not
cause any negative effects in performance on a Corsi Blocks task, suggesting
that the phonological loop was not being used to recode the information for
rehearsal (Kemps et al., 2000).
Another explanation for the improvement in performance could be due to
an increase in capacity, as children aged five to seven are believed to have a
capacity for two items but this capacity doubles to four items for children aged
11 and adults (Riggs et al., 2006).
The implications of low working memory in children. There is a
substantial amount of evidence linking the ability to learn with the capacity of
working memory (Holmes et al., 2009). It has been highlighted, that children
with a low working memory often experience problems in everyday tasks such
as following instructions, and are more likely to have a record of poor academic
progress (Alloway et al., 2008). Furthermore, the deficits seem to grow as
children get older, highlighting the need for early intervention programmes
(Alloway et al., 2008). Improvements in working memory tasks and in general
classroom performance have been observed as a result of memory training
programmes (St Clair-Thompson, Stevens, Hunt & Bolder, 2010; Holmes et al.,
2009). However, it should also be pointed out that these improvements are not
always transferred to standardised ability measures.
29
There would appear to be a dearth of literature regarding enjoyment
levels of children completing memory tasks. One study refers to a measure
which was reported to be enjoyable and developmentally appropriate for
younger children; the Children’s Size-Ordering task (McInerney, Hrabok &
Kerns, 2005). Furthermore, whilst not explicitly highlighted in the literature,
several tasks aimed at children and levels of enjoyment and engagement have
been used in memory testing. Mr X involves children looking at two cartoon
pictures and identifying differences between the pictures (Alloway et al., 2006).
In the Mr Peanut task, children are presented with a clown shape image with
dots placed in different locations and they have to choose the correct locations
for the dots on a blank model (Kemps et al., 2000). In a spatial task by Hornung
et al. (2011), children had to memorize and subsequently report on the location
of dwarves that appeared briefly on a PC screen. Whilst the researchers do not
make explicit comments about the enjoyment factor of each of the tasks, it
would seem reasonable to assume that they have been designed to be more
appropriate for use with children and to boost levels of engagement and
enjoyment.
For example, in a training programme by Colmar, Davis and Sheldon
(2016) to assist children’s memory in classroom situations, the materials were
presented as pictorial icons. This choice of resource was based on finding
material that would be appealing to children, and the result was that children
reported the task as enjoyable (Colmar et al., 2016). However, little research
seems to have been conducted in analysing the benefits of enjoyment of task
on levels of performance or in developing resources which may lead to
increased enjoyment amongst children.
30
According to Engle et al., (1991), working memory is an essential part of
everyday life and is necessary for people to function in society. The importance
of working memory is evident across a range of school based tasks such as
mental arithmetic (St Clair Thompson et al., 2009), language development
(Baddeley et al., 1998) and following instructions (Alloway et al., 2008), and
deficits can lead to significant issues for many individuals. Therefore, it would
seem opportune to analyse a novel tool, which may help assess working
memory in children in a straightforward yet effective way, in order to aid future
developments in the field.
‘Unpacking the Box’ is a novel tool designed to check understanding and
assess verbal memory in children and it would appear that no previous research
has been carried out on this resource. However, there are many possible
implications for its usage in the future in many different settings, such as
schools and in clinical practices. As there would appear to be a lack of
enjoyable and easy to administer tasks for assessing working memory in
children, it is paramount that this apparatus is examined and compared with
other measures to assess its validity. Therefore, this study will examine
whether children perform according to their age on working memory span tasks,
if there is a correlation between working memory span tasks and Unpacking the
Box and children’s levels of enjoyment with the use of a novel resource
‘Unpacking the Box’. It is predicted that:
1. Children’s performance on memory tasks will increase with age.
2. Children will report high levels of enjoyment when being assessed
using the novel tool ‘Unpacking the Box’.
31
Method
Participants. A total of 71 pupils (37 males, 34 females) from ages 6 to
8 at a primary school in the North West of England participated in the study.
Ethical approval was obtained from the University of Chester (Appendix A) and
parents were provided with detailed information of the study (Appendix B) along
with an opt-out form prior to testing (Appendix C). The pupils were divided into
three age groups; age 6 (M 77 months, SD = 3.2), age 7 (M 90 months, SD =
3.5) and age 8 (M 101 months, SD = 3.4). Two pupils who were aged five were
removed from the data set, leaving a total of 69 participants (36 male and 33
female).
Materials. Lists of numbers ranging from a two item list to a nine item
list were used for the digit span task (Appendix D). For the Corsi blocks task a
similar list of numbers was used, with list length varying between two and nine
(Appendix E) alongside a wooden board containing nine blocks. The blocks
were numbered for the researcher, however, the participant was not able to see
the numbers during the testing period. For the listening span task, a list of
sentences was used (Appendix F) of which some sentences were true and
some were false or silly sentences. The tool ‘Unpacking the Box’ comprises a
silver tin containing a smaller tin and a selection of silver and black objects such
as stars, paperclips, ribbons and bags (see Figure 1) and a list of instructions to
be read out verbally to the children (Appendix G).
32
Figure 1: The novel tool ‘Unpacking the Box’
Procedure. Data collection and testing took place in a quiet area near to
the classroom of the children and all children were tested individually. At the
start of each trial the researcher explained to each child that they were not
completing a test and that no scores would be passed on to their teachers. It
was explained that they were helping with some jobs. Children were also
reminded that they did not have to take part if they did not want to and that they
could stop the trial at any time (Appendix H). A total of four tests were
administered to each child during a single session which lasted approximately
15 minutes. The order of the tasks was counterbalanced so that each task was
in first, second, third and fourth position an equal amount of times. An example
was given at the start of each test to ensure children understood the
requirements. A final questionnaire (Appendix I) was administered to the
children to assess levels of difficulty and enjoyment whilst completing each of
the tasks. The children also explained which task they enjoyed the most and
what they thought were the best and worst things about Unpacking the Box. At
33
the end of each individual test, a debrief took place and children were given the
opportunity to ask any questions (Appendix J). it was explained to the children
that if they had a question later on they could ask their teacher who would
contact the researcher if necessary.
Auditory digit span. The experimenter read a list of digits aloud at a
rate of one per second and the child attempted to repeat the same sequence of
digits. The list length started at two and increased by one digit each time if the
child successfully repeated the sequence. There were two lists at each level
and if the child failed to both attempts of the lists at a particular length no further
lists were given. The highest number of digits recalled correctly provided the
figure recorded as the digit span for each individual.
Corsi blocks. To test digit span, the experimenter tapped a pattern on
the Corsi blocks at a rate of one block per second and the child attempted to
copy the sequence. The list started with two numbers and increased by one
digit if the child repeated the sequence of tapping the blocks correctly. The
child had two attempts at each length and if unsuccessful, no further patterns
were given. The longest list length recalled was the figure recorded for each
child.
Listening span. To assess working memory via the listening span test,
the experimenter read a sentence aloud and the child attempted to remember
the last word of the sentence and to state if the sentence was true or false.
There were three attempts at each level and the child had to complete the task
successfully on two occasions to move to the next level. Each time the child
successfully completed a level the complexity of the task was increased by
34
adding another sentence. Children were allowed to recall the final words in any
order. The longest list on which two tasks were completed correctly provided
the listening span figure for each individual.
Unpacking the Box. To administer the ‘Unpacking the Box’ test, the
experimenter read an instruction aloud to each child who attempted to follow the
instruction by picking up or placing objects from the box in different positions.
The instruction was increased by one key word at each level. The children
were given two opportunities to complete the task successfully at each level. If
they were successful, they moved on to the next level. If the children were
unsuccessful on both attempts at a particular level, then no more instructions
were given. The highest amount of instructions performed correctly provided
the child’s individual score for ‘Unpacking the Box’.
Design
A 3x2 between-subjects design was employed. The first independent
variable was gender and there were two levels; male and female. The second
independent variable was age and there were three levels; age six, age seven
and age eight. There were four dependent variables; scores on a digit span
test, scores on a Corsi block test, scores on a listening span test and scores on
a test using Unpacking the box. A 3x2 within subjects ANOVA was used to
analyse the results. Post hoc Bonferroni corrected Tukey tests were carried out
with a reduced alpha level of .017.
Results
The aim of the study was to investigate the development of working
memory in children using a novel tool, ‘Unpacking the Box’ and to asses if there
35
was a correlation between working memory tasks. The mean and standard
deviation scores for each of the tasks and each of the age groups are displayed
in Table 1. A steady increase in performance according to age was observed
for all of the tasks.
Table 1:Descriptive statistics for tasks carried out with male and female children
aged 6, 7 and 8 years.
Task Digit Span Corsi Blocks Listening
SpanUnpacking
the boxAge/Gender M SD M SD M SD M SD
Age 6 4.57 0.82 4.03 0.93 1.27 1.02 5.53 2.45
Age 7 4.86 0.91 4.48 0.75 1.67 0.91 7.19 1.08
Age 8 5.00 0.69 4.67 0.84 1.78 0.73 7.17 0.92
Male
Age 6 4.53 0.80 4.00 1.12 1.41 1.18 5.65 2.50
Age 7 4.70 1.16 4.40 0.70 1.70 0.68 7.20 1.03
Age 8 4.78 0.67 4.78 0.97 1.56 0.53 6.89 0.93
Female
Age 6 4.62 0.87 4.08 0.64 1.08 0.77 5.38 2.47
Age 7 5.00 0.63 4.55 0.82 1.64 1.12 7.18 1.17
Age 8 5.22 0.67 4.56 0.73 2.00 0.87 7.44 0.88
The effect of age and gender on task performance. Analyses of
variance were conducted to examine the effect of age on performance for each
of the tasks. There was no significant main effect of age on digit span scores, F
= 1.657, p =.199, = .050, or of gender on digit span scores, F = 1.861,
p=.177, =.029. There was no significant interaction between age and gender
on digit span scores, F = .282, p = .755, = .009.
36
An analysis of variance yielded a significant main effect of age on
performance in a Corsi Blocks test, F (2, 63) = 3.272, p=.044, = .094.
Tukey’s post hoc tests, with a Bonferroni adjusted alpha level of 0.17 showed
no significant difference between pupils aged 6, 95% CI [3.178, 4.359] and 8
[4.256, 5.077], p=.046. The differences between pupils aged 6 and 7, 95% CI
[4.092, 4.853], p=.182 and those aged 7 and 8, p=.776 were not significant.
There was no significant main effect of gender on Corsi block scores, F = .000,
p=1.000, = .000 nor was there a significant interaction between age and
gender, F = .244, p = .784, = .008.
There was no significant main effect of age on scores in a listening span
test, F = 2.275, p=.111, = .067 or of gender on listening span scores, F
= .004, p=.947, =.000. No significant interaction was observed between age
and gender on listening span scores, F = .993, p = .376, = .031.
An Anova conducted on the Unpacking the Box resource yielded a
significant main effect of age on perfomance scores, F (2, 63) = 6.990, p=.002,
= 182. Tukey’s post hoc tests revealed a significant difference in
performance between children aged 6, 95% CI [4.845, 6.187] and children aged
7, 95% CI [6.395, 7.987], p=.006. There was also a significant difference
between children aged 6 and children aged 8, 95% CI [6.308, 8.025], p=.01. No
significant difference was found between children aged 7 and 8, p=.999. There
was no significant main effect of gender on Unpacking the box scores, F (2, 63)
= .041, p =.839, = .001, nor was there a significant interaction between age
and gender, F = .284, p = .754, = .009.
37
Correlational Analyses. Correlation analyses were conducted between
‘Unpacking the Box’ and each of the tasks were conducted (See Table 2).
Table 2: Correlations between tasks
Unpacking the box
Digit Span
Corsi Blocks
Listening Span
Digit Span .25*Corsi Blocks .29* .27*Listening Span .54** .41** .27*Age (Months) .44** .24* .36* .29*
* - significant at 0.05
** - significant at 0.01
As a relationship was expected between each of the tasks, one-tailed
tests were carried out with a 0.5% level of significance. All of the tasks were
significantly related to each other and the relationship between ‘Unpacking the
Box’ and Corsi blocks, ‘Unpacking the Box’ and listening span, and digit span
and listening span were significant at the 0.01 level.
Enjoyment of tasks. Non-parametric analyses were carried out to
measure the level of enjoyment on each of the tasks. The results of the
Friedman Test indicated that there was a significant difference in the level of
enjoyment between the four tasks; digit span, Corsi blocks, listening span and
‘Unpacking the Box’ χ² (3, n = 69) = 34.14, p <.001. Inspection of the mean
scores indicated that pupils enjoyed ‘Unpacking the Box’ the most (M = 4.67,
SD = .76), followed by Corsi Blocks (M = 4.46, SD = .83) and Digit Span (M =
4.33, SD = .82, ). The least enjoyable task for pupils was the listening span
task (M = 4.01, SD = .92).
38
Post hoc tests were conducted between Unpacking the Box and each of
the tasks and a Bonferroni adjusted alpha value of .017 was used. A Wilcoxon
Signed Rank Test revealed a significant difference in enjoyment levels between
‘Unpacking the Box’ and digit span, z = -2.86, p =.004, with a small effect size (r
= .24). The median enjoyment score for ‘Unpacking the Box’ (5.00) was higher
than the median enjoyment score for digit span (4.00) indicating higher levels of
enjoyment for ‘Unpacking the Box’. No significant difference was found
between enjoyment scores for Unpacking the Box and Corsi Blocks, z = -1.99, p
= .047. A significant difference was found between enjoyment levels for
Unpacking the Box and Listening span, z = -4.49, p <.001, with a medium effect
size (r =.38). A higher median score for Unpacking the Box (5.00) indicated
higher levels of enjoyment for that task than the median score for a listening
span task (4.00).
Difficulty of tasks. The Friedman Test was used to measure the level
of difficulty amongst each of the tasks. The results indicated a significant
difference in the level of difficulty between the four tasks χ² (3, n = 69) = 41.94,
p <.001. The mean scores indicated that pupils found the listening span the
most difficult (M = 2.94) of the tasks, followed by Digit Span (M = 2.80) and then
Corsi Blocks (M = 2.28). Unpacking the box was reported to be the least
difficult (M = 1.97).
A Wilcoxon Signed Rank Test revealed a significant difference in the
level of difficulty experienced between Unpacking the Box and digit span, z = -
4.761, p < .001, with a medium effect size (r = .41). A median score of 1.00 for
Unpacking the Box revealed that pupils found it easier than digit span with a
median score of 2.00. No significant difference was found in the level of
39
difficulty between Unpacking the box and Corsi blocks, z = -1.680, p = .093. A
significant difference was found in the level of difficulty between Unpacking the
Box and listening span, z = -4.864, p < .001, with a medium effect size (r = .41).
Formal qualitative analyses were not conducted on these data, however, when
asked to describe the best and worst things about ‘Unpacking the Box’ many
children gave very positive answers, for example, “Its’ easy and I knew what
everything was”; it’s fun”; “I liked seeing all the things inside it”. The children
were often unable to mention anything negative about the box, saying that there
was nothing that could be improved.
Discussion
The purpose of this study was to examine the development of working
memory in children and to assess the extent to which the novel resource
‘Unpacking the Box’ correlated with other measures of working memory. It was
expected that age would have an effect on performance in the memory span of
children whereby, children’s performance would improve with age. A further
aim of the study was to examine levels of enjoyment when using this novel tool
for measuring working memory in children.
The importance of memory in children and adults has been
demonstrated by many researchers (Gathercole et al., 2004; Kemps et al.,
2000). Working memory is a cognitive function, which is vital for many basic life
processes (Engle et al., 1991). The importance of working memory has been
established in terms of reading ability (Engle et al., 1991), language
development and vocabulary acquisition (Baddeley et al., 1998), mathematical
40
performance (Swanson & Kim, 2007) and following classroom instructions
(Engle et al., 1991). Children’s performance on short term and working memory
tasks has also been highly correlated with measures of intelligence (Engle et
al., 1999). Therefore, the memory span of an individual plays a vital role in their
level of intelligent functioning (Gignac & Weiss, 2015). Due to the contribution
of memory to cognitive functioning, it is vital that research is carried out to
develop practical and useful resources to assess and improve working memory
in children. Therefore, this study is of vital importance as it provides information
on a novel tool to respond to this need.
Extensive research into short term memory and working memory in
children has revealed a linear developmental pattern with capacity gradually
increasing from a young age to adulthood (Gathercole, 1999). It is suggested
that children can increase their memory capacity by one chunk every two years
(Engle et al., 1991). The results of this study support a developmental pattern
of a gradual increase in memory span as the mean score for each of the tasks
indicates a steady improvement from age six through to age eight. Therefore, a
linear developmental increase in memory span, demonstrated by a gradual
improvement with age was evident across all of the tasks.
Whilst a gradual increase across scores was observed, no significant
effect of age was found on digit span performance. This result was a little
surprising as previous research indicates that the phonological loop undergoes
significant change between these ages (Gathercole & Adams, 1994). Firstly, it
is assumed that subvocal rehearsal is not used regularly by children under
seven years of age and therefore the phonological loop is merely a storage
system for verbal material at this age (Gathercole, 1999). It is believed that
41
children have the ability to use rehearsal strategies when instructed to do so but
do not employ these strategies without being prompted to do so (Rai & Harris,
2013). Therefore, due to a lack of subvocal rehearsal in under sevens, a
significant effect of age would be expected at least between the six year olds
and the seven year olds or the six year olds and the eight year olds.
However, the youngest age group in the sample are nearing the end of
their first year of full-time education and will have undertaken a considerable
amount of work with the digits 1 – 9, thus creating high levels of familiarity with
the material. Furthermore, numbers are often repeated regularly on television
or radio advertisements leading to high exposure amongst children (Jones &
Macken, 2015). According to Alloway et al. (2008), one explanation for this
result could be that the familiarity and experience of using digits led to better
performance. For example, in adults it has been found that performance on
memory span tasks decreased when the stimuli were foreign language items
(Cowan et al., 2015), showing that the activation of the episodic buffer to bind
information from long term memory is also an important factor in working
memory performance (Baddeley, 2010). Further evidence demonstrated that
the capacity to remember a telephone number is much lower when it is
presented in a foreign language (Baddeley, 2010). Similarly, capacity for a
string of unrelated words is much lower than the span for a meaningful
sentence, thus highlighting the contribution of the episodic buffer in binding
items from long term memory such as grammar and meaning (Baddeley, 2010).
In addition, as highlighted by Jones and Macken (2015), digits occur with
great frequency in everyday life in the form of dates, times, scores in a game,
telephone numbers and many more. Another factor could be that children have
42
heard numbers being presented as chunks and they may employ chunking as a
strategy for recall (Engle et al., 1991). Therefore, if children are highly familiar
with the stimuli presented, this could lead to them adopting strategies which are
normally only adopted by older children, such as chunking and rehearsal. This
would account for a higher level of performance amongst the younger children
who may have spontaneously used strategies or who may have relied on their
long term memory to help with retrieval. As a result, the task would be relatively
simple for the younger children and they may perform at the same level as the
older children. This possible explanation would also rely on the use of the
episodic buffer in binding the information from long term memory with the
phonological loop. (Baddeley, 2010). This proposal has been supported by
neuroimaging studies which found that areas of the brain associated with long
term memory are often activated during short term memory tasks (Baddeley,
2010).
According to Jones and Macken (2015), whilst many studies have used
digit span as a measure of short term memory, this is problematic as these
studies neglect the contribution of learning by association and long term
memory. Moreover, the idea that digit span may tap into long term memory
would account for the high correlation between digit span and new language
acquisition (Baddeley et al., 1998). It can be seen that the processes needed
for learning digits, such as learning information in a sequential manner (Jones &
Macken, 2015), and the ability to encode sounds (Alloway et al., 2004) are also
necessary for processes of language learning, such as the sequencing of
phonemes (French & O’Brien, 2007). Language learning is an essential part of
development and is vital for cognitive functioning (Engle et al., 1991). In view of
43
the highly significant link between phonological memory and language learning
and cognitive development, it would seem imperative that research which
investigates the role of phonological memory in children is given priority.
Despite the clear differences between the phonological and visuospatial
tasks, similar results were found for the digit span and Corsi Blocks tasks.
Whilst an initial significant effect of age was found on performance in the Corsi
Blocks task, once post hoc tests were conducted using an adjusted alpha value,
no significant effect of age was found. This was a surprising result in view of
previous research, which suggests that visual working memory improves with
age leading to a substantial capacity change between five years of age and
adulthood (Busch, Farrell, Lisdahl-Medina & Krikorian, 2005). In a study by
Kemps et al. (2000), a developmental trend in performance in visuospatial
memory span was found in children aged six to nine. This is in line with
previous findings and showed that children who were older performed slightly
better. The researchers used two tasks; the Corsi Block task and a task called
Mr Peanut. The Mr Peanut task requires children to look at a picture of a
cartoon style clown with dots positioned in several locations and subsequently
place the dots in the correct place on a blank version. The results showed a
main effect of age for both of the tasks. However, the study found that children
performed better on the Corsi Block task than the Mr Peanut task. One
explanation for this was that the Corsi block task involves a minimal load as
children repeat the sequence immediately and only concentrate on one block at
a time rather than a pattern with lots of information and 14 possible locations for
the dots (Kemps et al., 2000).
44
In addition, other studies have also found a significant effect of age on
performance in a forward Corsi block test (León et al., 2014). One explanation
for a lack of main effect of age in the present study could be due to the narrower
age range between the children. In the study by León, et al. (2014), children
ranged from age five to age ten, and in the study by Kemps et al. (2000), ages
ranged from five to nine, whereas the current study looked at differences in
children from age six to age eight. It has been proposed that visuospatial
memory continues to develop up to adolescence (Belmonti, Cioni & Berthoz,
2015) and therefore it might be that the differences between younger children
are less significant due to the component not reaching full development.
However, as indicated by the mean scores on the Corsi Block task, the gradual
increase in performance with age represented a developmental increase albeit
not significant, and mirrored the results of other studies using the Corsi Block
task (Belmonti, et al., 2015; Piccardi, Leonzi, D’Amico, Marano & Guariglia,
2014). In terms of gender differences, our results which indicated that there
was no significant effect of gender on performance were in line with many other
studies (Piccardi et al., 2013; Belmonti et al., 2015; Nichelli et al., 2001; León et
al., 2014).
There is still uncertainty as to whether the development of visual working
memory is a result of a growth in capacity or more effective use of strategies,
such as recoding material for verbal rehearsal or visualisation of stimuli (Riggs
et al., 2006). Furthermore, it has been ascertained that often children might
achieve the same outcome by using different structures (Hitch, Towse & Hutton,
2001). It would appear that as children develop and gain awareness of memory
techniques, they are more likely to engage in the recoding of items into a verbal
45
format to allow rehearsal (Pickering, Gathercole, Hall, & Lloyd, 2001).
However, this form of verbal rehearsal is generally used for material that can be
labelled in some way and visualisation is usually used with static stimuli. As the
Corsi Block tapping task is presented in a dynamic form, it is unlikely that any
form of rehearsal was employed (Pickering et al., 2001).
According to Busch et al. (2005), inconsistency in scores on a Corsi-
Block tapping test was thought to be the result of more complex path
configuration. In this study, particularly at list length five, several pupils aged six
failed at their first attempt but succeeded on the second attempt when the
pattern followed a circular motion. Therefore, the higher score for some of the
younger children may be attributed to a simpler path configuration. This finding
could also be interpreted in terms of children’s performance being influenced by
path configuration rather than the processing of sequential information (Busch
et al., 2005). It is assumed that sequential processing relies on executive
function (Allen, Baddeley & Hitch, 2014), therefore, if children were relying on
configural information then it may have made the task easier, thus explaining
the lack of significant variance amongst the different age groups. However,
others may argue that the inconsistency in higher scores could also be the
result of difficulty in maintaining sustained attention (Busch et al., 2005).
The listening span task involved a much more complex activity as it
involved storage and processing. The descriptive statistics suggest that
children found this task more challenging than the other tasks. One explanation
for the linear development of working memory is that as children get older, they
become better at processing and therefore, more capacity is available for
storage (Engle et al., 1991). However, in this current study, no significant main
46
effect of age was found on performance on the listening span task. Initially this
result was surprising, as it would be assumed that a heavier load would lead to
significant differences between the age groups. However, as the task was very
challenging, many students achieved a low score and therefore, due to the high
number of low scores, little difference was evident between the age groups.
One limitation with the scoring system for the listening span task was that
it only credited full answers and on occasions, some children almost completed
the task but maybe forgot one last word in the sentence and thus the lower
span number was used for their score. This method of scoring signified that in
some cases there were differences in the level of performance amongst
children with the same score. In a future study, it would be beneficial to use a
more complex system (see Henry, 2001) which would credit partially correct
answers and thus give an overall better picture of performance and ability for
each individual.
A significant effect of age on performance in ‘Unpacking the Box’ was
found between six year olds and the seven and eight-year-old children whilst
there was no significant effect between the seven and eight-year-old groups.
Previous research has found that following verbal instructions is a complex task
which relies on the phonological loop and the central executive (Gathercole et
al., 2008). For example, Engle et al. (1991) found that there was a high
correlation between a following directions task and performance on a
comprehension task. It is assumed that the executive function involved is
associated with the need for children to keep track of their place in the
sequence of the instruction (Gathercole et al., 2008). For example, children
who show high levels of executive functioning remember how far along they are
47
in the sequence of the instruction whilst also being able to recall which activities
they have already performed and which they still need to complete. In a study
by Bergman-Nutley and Klingberg (2014), performance on a similar task
involving following instructions showed a linear improvement and the results of
this study support those findings.
However, whilst developmental trends have been shown in previous
literature regarding the improvement of memory span with age, little is known
about the actual processes involved; some have proposed that the capacity of
memory increases with age, whilst others suggest that the improvement is due
to a more efficient use of strategies, leaving more resources available for
storage (Engle et al., 1991; Gathercole et al., 2004). For example, Cowan et al.
(2015) conducted a study using a visual array, which was to be recalled and a
subsequent probe. In some of the trials, contextual information, such as a
similar shape or colour was given and it was found that this led to the possibility
for children to make guesses, thus enabling them to benefit from the contextual
information. In addition, it was assumed that the younger children were more
likely to make guesses (Cowan et al., 2015). This is an area for consideration
with ‘Unpacking the Box’ as children have all of the materials spread out in front
of them and if they were not sure they could depend on the visual cues to assist
them. This could explain the high scores often obtained on this task.
Nevertheless, it must be considered that this contextual information could also
lead to a higher level of error as children may be able to pick the correct item
but select an incorrect colour (Cowan et al., 2015). Cowan et al. (2015) found
clear evidence that when the probe item was not in the array and there was a
match in colour but a mismatch in the shape of the object, the children became
48
confused and performance decreased. Adults were more able to identify that
the shape was not in the array than children. In terms of ‘Unpacking the Box’,
the array of materials could enable to children to guess if they do not know an
answer. However, having such a vast array of materials in front of them could
also lead the children to confusion.
Furthermore, it has also been demonstrated in adults that when it is
necessary to maintain features such as colour and shape, there is often a trade-
off, therefore when fewer shapes need to be remembered then more colour will
be remembered (Cowan et al., 2015). In the present task, whilst children on
occasion had to remember the correct colour of an item, they had fewer options
as the items in the box were either black or silver. Subsequently, one might
suggest that the restriction of colours makes it easier and thus lightens the task
load. However, it is believed that younger children often store visual information
by features such as colour or shape, and therefore, the similarity between the
colours could lead to deficits in the reconstruction of items which are subject to
decay (Pickering, 2001). Consequently, the similarity of the items in only silver
or black could prevent children from distinguishing between them. This is an
area which needs to be considered in greater detail. Therefore, the impact of
using only two colours would represent an interesting area for future research.
As this was the first trial with this resource, instructions were fairly basic
at this stage and did not include sequencing words such as then, first, after.
However, one possibility is that this factor could have led to a ceiling effect as
was the case in the original following directions study by Kaplan and White
(1980). Therefore, if more complex instructions had been used, a significant
effect of age may also have been observed between the seven and eight year
49
olds. Nevertheless, this finding highlights the benefits of the tool in allowing the
use of sequencing, which would rely on executive control and place a greater
demand on working memory (Allen et al., 2014). The ability to include this type
of instruction in future tasks is an advantage of the resource as it shows the
potential for measuring complex working memory span.
A further consideration to be taken into account is the effect of
performing actions on memory span. Previous research has found an
improvement in recall when an action is performed rather than just being read
or heard by a researcher (Gathercole et al., 2008). However, it seems that the
main benefit which arises as a result of performance of the task, is related to the
encoding of the material (Gathercole et al., 2008) and as this task is more
concerned with immediate recall, it could be argued that this theory bears no
relevance. However, as explained by Riggs et al. (2006), younger children
often struggle to remain focused and may miss things due to their lack of
attention. Similarly, children with a low working memory are often described as
inattentive by their teachers (Gathercole et al., 2008). Therefore, one possible
benefit of the physical performance of the actions is that it could lead to higher
levels of enjoyment and thus help in maintaining sustained attention. This
would be an interesting area for future research with ‘Unpacking the Box’.
As highlighted by Stöcktel and Hughes (2016), executive functioning is
largely responsible for regulating behaviour and maintaining focus to ensure
tasks are finished. During the data collection, there were no obvious instances
of children losing focus or not wanting to complete the ‘Unpacking the Box’ task.
However, this was not the case for some of the other tasks used in the study.
For example, one six-year-old girl decided that she did not want to continue with
50
the digit span task, and was visibly fidgeting during the listening span task,
whilst another six-year-old girl said that she did not want to do any more on the
listening span task. One could assume that these pupils found the ‘Unpacking
the Box’ task more engaging and enjoyable than the other tasks. Therefore, it
would be reasonable to assume that having pupils actively engaged in the
activity, by them having to move objects about, could lead to higher levels of
enjoyment and sustained attention.
Previous research has found that short term and working memory
increases gradually with age (Alloway et al., 2006). As expected, and in line
with previous findings, a positive correlation was found amongst all four tasks.
Previous studies have found that verbal and visuospatial tasks often follow a
similar developmental pattern (León et al, 2014), indicating that whilst they are
different components of working memory, there are similarities between them.
As digit span, Corsi blocks and listening span are well established and
validated measures of memory, the correlation between Unpacking the Box and
these tasks suggests that it is also a valid measure of memory (Atkins et al.,
2014). The most significant correlations were found between Unpacking the
Box and listening span; and digit span and listening span. It has been
suggested that measures of working memory correlate more highly than
measures of short term memory because they have common underlying
cognitive demands (Alloway et al, 2006).
Many researchers support the view that executive functioning is involved
in working memory tasks (Baddeley, 2000; Engle, et al., 1999), thus explaining
the difference in performance from a developmental perspective. In the present
51
study, it is thought that the digit span task and the Corsi blocks task were
measures of short term memory whilst listening span and ‘Unpacking the Box’
involved a processing element which has been found to equate to a working
memory task (Alloway et al., 2006; Gathercole et al., 2008). Therefore, it is not
surprising that a highly significant association was found between ‘Unpacking
the Box’ and listening span, as both tasks place a higher demand on cognitive
skills. Therefore, the significant correlation between listening span and
‘Unpacking the Box’ and the need for processing within both tasks supports the
idea that the novel task ‘Unpacking the Box’ is a valid measure of working
memory as opposed to short term memory. However, as expressed by Engle et
al., (1991), this task may represent a short term memory task for some but a
working memory task for others who are better prepared at using strategies
such as rehearsal and chunking.
As demonstrated in previous research, a following instructions task is
more highly correlated with backward digit span rather than forward digit span
suggesting that the processes involved are not simply a form of passive storage
(Gathercole et al., 2008). Consequently, the high correlation between the
listening span and digit span tasks was a little surprising as it is assumed that
one is a measure of complex working memory whilst the other is thought to be a
measure of short term memory. Nevertheless, it is clear that both short term
memory and working memory rely on a common construct; the storage
component (Gathercole, 1999). Furthermore, both tasks involve verbally
presented material and the reliance on the phonological loop could explain the
significant correlation between the two tasks (Gathercole et al., 2008).
52
Non-parametric tests were conducted to assess levels of
enjoyment. The data suggest that children experienced high levels of
enjoyment when completing the task. When asked what was the best thing
about the box, many children mentioned their enjoyment in taking things out of
the box “It was fun when I had to put things in different places” or the fact that
there were lots of interesting things inside the box, “it’s silver, shiny and
reflective and can keep loads of stuff in it”. One of the children observed the
practicality of the box and how easy it was to have all the resources together
“You could do it whenever, you could get a box and do it at home with other
things” and one pupil enjoyed the feeling of success “I was good at sticking
things in place”. Some pupils expressed enjoyment at being challenged by
using the box, “it’s quite hard because it’s challenging and you have to look and
listen” and one child recognised the benefits of the resource for training
people’s memory “If people can’t remember much it could learn them how to
remember a bit more”. When asked what was the worst thing about the box,
many pupils said that there was nothing bad about the box. A few pupils said
that they found it difficult to put some of the objects inside the bag or that it was
difficult to move some of the objects, “there’s loads of things and they get mixed
up”. A few pupils felt that a lot of information was given and one pupil said that
“his brain got a little bit mixed up”. One pupil did not see the value in the box
and said that it would be more useful in the kitchen for storing food items.
Taken as a whole, the qualitative information indicates high levels of
enjoyment when using ‘Unpacking the Box’ and that it is a challenging,
engaging and useful tool for measuring working memory. The fact that most
children enjoyed the task and performed well on it could lead to the assumption
53
that if children enjoy a task they will remain focused, engaged and motivated
thus resulting in sustained attention. Therefore, a task to assess working
memory, which involves high levels of enjoyment is an extremely valuable tool
with vast potential for further development.
Implications, Limitations and Future Research
This research has demonstrated that the novel tool ‘Unpacking the Box’
is a practical, straightforward and rapid way to assess working memory in
children. Furthermore, in the absence of an array of literature regarding
enjoyment of memory tasks in children, it is pleasing that children reported high
levels of enjoyment on the task. There are many possible implications for the
use of this resource in the future, from clinical settings to educational
establishments, alongside its current use in preparing victims to give evidence
in court. As this was an initial study using this resource, sequencing words
were not included in the instructions and therefore, this may have led to a
ceiling effect (Kaplan & White, 1980), as many of the older children reached the
maximum span on this task. If subsequent studies are to compare the measure
to a listening span task, it would be beneficial to develop a more complex
scoring system for this task to differentiate more between the different levels of
working memory. As the younger pupils performed better than expected on the
digit span test due to the familiarity of the resource, it may be beneficial to
assess working memory by using a non-word repetition task (Henry, 2012). It
may be of interest in future research to assess the use of only two colours in the
resources and the effects of similarity that may be involved. Finally, an exciting
54
area for future research would be to assess the benefits of using this tool as a
training programme to help with the development of working memory.
Conclusion
To conclude, it has been established that the novel tool ‘Unpacking the
Box’, is a practical and effective way to assess working memory in children. As
pointed out in some of the qualitative data, the box is a very practical and
portable tool which is easy to use and can be carried out in a relatively short
space of time. All of the materials are kept together in one place and children
recorded high levels of enjoyment when using the resource. The novel
resource yielded significant correlations with the other established, validated
measures of memory. A highly significant correlation between ‘Unpacking the
Box’ and listening span would suggest that both are tasks of working memory
as they require an element of processing. The prediction of a developmental
linear improvement in memory span was generally supported by the research
although some of the analyses of variances yielded non-significant results. The
effect of age on ‘Unpacking the Box’ performance was supported and indicated
that this novel tool is an effective, simple and practical method of measuring
working memory in children.
55
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Appendices
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Appendix A – Ethics Forms
The Ethics forms can be found at the back of this document.
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Appendix B – Letter to parents detailing the study
Department of Psychology
The University of Chester
Parkgate Road
Chester
CH1 4BJ
Parental Information Sheet
Invitation for your child to take part in a research project investigating measures for
assessing working memory.
My name is Lisa Iranzo and I am a Masters student, conducting research with Dr
Michelle Mattison, within the Department of Psychology at The University of Chester.
My work is focusing on techniques for measuring a child’s working memory. I am
writing to ask you to allow your child to participate in this project.
What is involved?
Should you allow your child to take part, I will ask him/her to do a series of activities
with me. Altogether, these will take no longer than 30 minutes and will take place
during school hours:
TASKS:
- Listening to a list of digits and repeating the list, then watching a pattern being
tapped out on a set of blocks and repeating the pattern. (no longer than 15
minutes).
- Listening to and following short instructions, e.g. put the paperclip in the tin
(no longer than 15 minutes).
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Your child’s responses will be recorded. These recordings will be used for educational
and research purposes only. The overall findings may be published in academic
resources, but no personally identifiable information (e.g. child’s name or school) will
be disclosed throughout this research. The data collected will be securely stored by
the research team for up to five years.
This is not a compulsory school activity, and your child’s individual results will not be
discussed with other pupils or any teachers. This research has been designed to be
enjoyable, and should you give consent, your child’s participation on the day is also
voluntary. As such, should your child decline to take part, or ask to stop he/she may
do so at any time, and their data will be removed from the study. Further, I have
completed an Enhanced DBS check, and whilst I will be solely responsible for working
directly with children at Platt Bridge, the overall research project will be supervised by
Dr Michelle Mattison.
Your child’s participation is not compulsory. However, if YOU DO NOT want your child
to participate, please complete the attached opt out form and return it to your child’s
teacher as soon as possible. If you are happy for your child to take part, you do not
need to return the attached form.
If you would like any further information, please contact me at
1023459@chester.ac.uk. Alternatively, you may contact my supervisor Dr Michelle
Mattison (m.mattison@chester.ac.uk, 01244 513191).
Yours sincerely,
Lisa Iranzo
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Appendix C
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Appendix D – Digit Span List of Numbers and Instructions
I will read a list of numbers. I want you to listen and repeat the numbers in the same order. The lists will get longer each time. For example, if I said 4, 7 then you would repeat 4, 7. Are you ready to begin?
Example of digit span
7 1
3 5
6 2 7
3 1 8
2 9 5 6
1 4 8 3
7 2 1 5 3
8 2 4 1 6
9 5 2 1 3 6
7 3 5 1 2 8
8 7 1 5 4 9 3
1 6 2 3 9 4 7
8 9 1 4 5 7 6 3
2 5 9 3 7 6 8 1
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Appendix E – Corsi Blocks List of Numbers and Instructions
For the next task we are going to be using these little wooden blocks. I will tap out a pattern and I want you to tap the same pattern. Let’s have a practice. (I tap two blocks and ask them to copy). Well done! Are you ready to begin?
(Lists of numbers will get progressively longer as digit span above).
2 7
3 5
1 9 3
2 4 7
2 3 9 8
1 6 7 3
5 9 6 1 2
4 8 2 1 7
3 9 2 1 6 8
2 7 5 4 1 6
2 7 1 6 3 9 8
1 9 4 3 7 5 6
1 3 7 8 4 6 2 5
2 9 5 6 8 3 1 4
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Appendix F – Sentences for the Listening Span task
Sentence Response Recall
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Appendix G – Unpacking the Box instructions
We have now reached our final test. I am going to show you a little box of items. As you can see there are two tins and lots of smaller items such as paper clips, buttons, a thimble (I will point to the items as I am explaining). I am going to ask you to follow instructions using these materials. For example, put the paperclip in the small tin – Can you do that? Ok, well done! Are you ready to begin?
Where is the star? (1)
Where is the bag? (1) Point to a ribbon (2)
Point to a key (2) Put a key on a bag (3)
Put a paperclip under the box (3) Put the star inside the silver bag (4)
Put a ribbon under the black bag (4) Put the big silver paperclip under the card (5)
Put the small black paperclip on top of the black bag (5) Put the star, ribbon and key inside the silver bag (6)
Put the black bag on top of the two big paperclips (6)
Put the ribbon in the box and the big key on the triangle (7)
Put the clip next to the big key and the ribbon under the box (7)
Put the big star, big key, ribbon, and clip inside the box (8)
Put the small star inside the box and the big key under the box (8)
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Appendix H - Information to Participants – Script to be read out before testing.
Hello and thank you for joining in the study today. Today you are going to help me check out how good some new resources are. The activities you are going to do are not school tests. You are just helping me by doing some jobs. No scores or marks will be passed on to your teachers or anyone else. I am just looking at how good each of the tasks are to check your memory. I will tell you what you need to do at the start of each job. Are you happy to carry on?
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Appendix I - Questionnaire and instructions
There is a very short questionnaire that I would like you to fill in – You just have to tick the boxes for each question and write a short sentence for the final two questions. What you tell me will help me to decide which of these activities were most fun and I can tell other grown-ups which memory tests you liked most. Thank you again and well done!
Thank you for completing the tasks. Please tell us what you think of them.
Task 1 – Listen and repeat the numbers (Digit Span)
How easy was the task?
Very easy □
Easy □
Not too hard □
Quite hard □
Very hard □
How enjoyable was the task?
I loved it. □
I enjoyed it. □
It was ok. □
I didn’t like it. □
I hated it. □
Task 2 – Tap the blocks in the correct order (Corsi Blocks)
How easy was the task?
Very easy □
Easy □
Not too hard □
Quite hard □
Very hard □
How enjoyable was the task?
I loved it. □
I enjoyed it. □
It was ok. □
I didn’t like it. □
I hated it. □
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Task 3 – Listen to the sentences and say if they are true or false (Listening Span)
How easy was the task?
Very easy □
Easy □
Not too hard □
Quite hard □
Very hard □
How enjoyable was the task?
I loved it. □
I enjoyed it. □
It was ok. □
I didn’t like it. □
I hated it. □
Task 4 – Use the items from the box and follow the instructions (Unpacking the box)
How easy was the task?
Very easy □
Easy □
Not too hard □
Quite hard □
Very hard □
How enjoyable was the task?
I loved it. □
I enjoyed it. □
It was ok. □
I didn’t like it. □
I hated it. □
What was the best thing about ‘Unpacking the box’?
What was the worst thing about ‘Unpacking the box’?
Thank you for completing the questionnaire.
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Appendix J- Debriefing script
Thank you for helping me out today. I work with lots of children and everyone who is helping me is teaching me how people remember things and I am going to tell other grown-ups how people remember things.
Do you have any questions about the jobs you’ve done today?
If you have any questions later, ask the teacher and if she doesn’t know she can call me up and I’ll answer them. Thank you for helping me today.
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Appendix K SPSS outputs – CD attached to rear cover
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