CHILDRENÕS CONCEPTS ABOUT THE STARS






Mei-Hung Chiu
Graduate Institute of Science Education
National Taiwan Normal University

Shueh-Chin Weng
Ing-Shyan Chern
Graduate Institute of Earth Science
National Taiwan Normal University




Paper presented at the annual meeting for the Australian 
Association for Research in Education (AARE),  22nd-25th 
November, 1993, Fremantle, Western Australia.

ABSTRACT

Twinkle, twinkle, little star.....Ó We all have experience 
staring into the sky to look for twinkling stars.  However, have 
we ever known how much our children know about stars?  This study 
intended to understand our childrenÕs conceptions about the 
stars.  In particular, if there are differences between the 
fourth graders who have not learned the topic about the stars and 
the seventh graders who learned in a science class.
Fourth (n=90) and seventh (n=93) graders in Taipei, Taiwan, were 
asked to answer a series of open-ended questions about the sizes, 
shape, components, and movement of the stars.  Fifteen fourth 
graders and sixteen seventh graders were drawn based on their 
responses to the questionnaire to be interviewed.  They were 
individually interviewed by the researchers to further confirm 
their mental models.  The questions are designed to examine how 
much students know about characteristics of stars and 
relationships among the stars, the moon, the earth, and the sun.  
The data consist of a transcript of each interview and a piece of 
written work the subject produced.  All interviews were 
videotaped for later transcription and analysis. 

The findings suggest that the studentsÕ concepts and explanations 
of the phenomena of the stars are inconsistent even for those 
seventh graders who have been taught in a formal science class 
setting.  Their explanations and understandings are based on  
their incomplete and piecemeal scientific knowledge and daily 
experiences.  In particular, younger children tend to explain the 
phenomenon according to the framework of the earth.  For 
instance, first, 62.4% of the seventh graders consider the shape 
of the stars are round, while only 30% of the fourth graders 
think so.  Majority fourth graders (61.1%) considered that the 
stars ÒblinkingÓ, whereas only 16.1% of the seventh graders think 
so.  Second, 56.1% of the seventh graders explain the formation 
of the stars by providing scientific reasons (e.g., explosion or 
collision) while only 19.9% the fourth graders give these 
responses.  About one third (33.3%) of the fourth grade students 
reply ÒI donÕt know.Ó, ÒGod made it.Ó, ÒMan (or ancient people) 
made it.Ó, or ÒThe stars took the light from the sun and the 
moon.Ó, etc.  Third, more younger children consider that the star 
can only be seen at midnight and 3 AM because of its movement, 
while more older children attribute it to EarthÕs rotation. 


OBJECTIVES

In order to promote deeper understanding about childrenÕs 
conceptual knowledge about the stars, 183 fourth and seventh 
grade students were asked a series of questions about the shapes, 
sizes, distance, and movement of the stars, the sun, and the 
moon.  We are mainly interested in understanding the nature of 
childrenÕs initial knowledge about the stars in the solar system 
and in finding out how this knowledge changes as children are 
exposed to school formal training.

THEORETICAL BACKGROUND

During the past few decades research in cognitive science, 
science education, and developmental psychology has shown that 
children construct an intuitive understanding of the world based 
on their daily experiences and related conceptions.  Many 
different terms have been used to refer to this type of 
knowledge, namely, preconceptions (Ausubel, 1968), misconceptions 
(Novak, 1987), alternative frameworks (Driver & Easley, 1978), 
mental models (Collins & Gentner, 1987), intuitive theories 
(McCloskey & Kargon, 1988), and theory-like (Carey, 1985).  
Although different terms were given, there is a general agreement 
that this intuitive knowledge provides explanations of natural 
phenomena which are frequently different from the scientific 
explanations.  Also, these intuitive knowledge tend to be robust 
and resistant to change (Chi, 1992; Vosniadou and Brewer, 1992).  
In this paper, we would address childrenÕs knowledge structures 
in terms of mental models because we consider these models to be 
more appropriate to represent what we found from the study.  The 
following is to briefly discuss the characteristics of mental 
models and childrenÕs knowledge acquisition in astronomy.ÿ

Mental model
Viscuso and Spoehr (1986) have given a definition to mental 
models after reviewing research in cognitive science, science 
education, and developmental psychology.  First, mental models 
are runnable.  They allow the user to make mental simulations of 
situations and events, and make predictions about how changes in 
one part of a system will affect the other parts. Second, since 
the propagation of such effects throughout an entire system must 
be simulatable, a mental model contains topographical or 
connectedness information.  Third, causality is inherent in a 
mental model since the propagation of change across the simulated 
system implies causal links.  And fourth, because causal 
propagation makes it possible to make inferences about the 
functions of different parts of the system, a mental model 
thereby contains functional information.  

Williams, Hollan, and Stevens  (1983) also point out that 
basically a mental model is a combination of some runnable 
objects or mental entities.  In this mental model, there exists a 
specific association, parameters, and procedures among the 
objects for making inference and problem solving (Holland et al., 
1986).  Experts use this multiple characteristics model to decide 
when, where, and how it can be used correctly in the process of 
solving problems.ÿ

Knowledge in astronomy
This area was chosen because several research has shown 
that childrenÕs knowledge about astronomy projecting consistent 
results across countries and usually, this knowledge interacts 
with childrenÕs daily experiences heavily (Vosniado and Brewer, 
1989; Vosniado and Brewer, 1992). While most of the science 
education research in astronomy emphasizes on childrenÕs concepts 

of the earth and the sun,  very limited studies are found on 
childrenÕs concepts of the star.  For instance, Vosniado and 
Brewer (1989) found that most of the younger children thought 
that the earth is bigger than the sun, the moon and the stars.  
But, it is interesting to note that the change to the Copernican 
model goes through an intermediate stage where children believe 
that the earth is smaller than the sun but bigger than the stars.  
Some children believe that sun and the stars are bigger than the 
earth and the moon.  Nussbaum (1986) also found that pupil 
knowledge about the earth is elementary and piecemeal. Model 
communications media did not seem capable of bringing manÕs 
considerable knowledge of the universe to the schools.  Finegold 
and Pundak (1991) administered a multiple choice test to identify 
and categorize school studentsÕ conceptual frameworks in 
astronomy and examined studentsÕ level of knowledge and 
conceptualization from grades 7 through 12.  They found that 
junior high studentsÕ conceptualization is mainly geocentric; 
students at this level tend to explain observed astronomical 
phenomena relative to the framework of the earth, as did the 
ancient Greeks.  However, high school students showed progress 
toward a heliocentric explanatory framework. 
In this study, we attempt to uncover what the childrenÕs 
conceptions about the star and how students use their conceptual 
framework to answer questions which is highly related to their 
daily experiences.  We hope our finding could further help 
studentsÕ learning and design meaningful instructional materials. 

METHOD

In this paper, open-ended questionnaires were used to test 
childrenÕs concepts about the star.  Individual interview 
techniques and simulated models were also employed to investigate 
how they arrived at the answers.  The following are brief 
descriptions of the study.

Subjectsÿ
The study was conducted in Taiwan.  Our subjects included 90 
fourth (boy=43, girl=47) and 93 seventh (boy=49, girl=44) 
graders.  The average age for the fourth graders is 9 years and 9 
months old (ranging from 8 years and 9 months old to 11 years and 
2 months old).  The average age for the seventh graders is 12 
year and 6 month old (ranging from 12 year-old to 13 years and 6 
months old).  The subjects came from middle-class backgrounds and 
attended schools in Taipei county.  

Materialsÿ
ChildrenÕs knowledge of observational astronomy was examined 
using an elaborated verbal questionnaire which included questions 
about the shape, size, composition, motion, and location of the 
stars, the sun, the earth, and the moon.  The questionnaire  has 
12 test items covering those main topics as described above.  The 
questionnaire was developed through a pilot study and the 
supplemented with explanatory questions (Why the stars looks 
shining?) and generative questions (e.g., ÒIf you see the stars 
above your head at midnight, where would it be at 3 AM?Ó).

Processÿ
The subjects were asked to answer opened-ended questions 
regarding to the nature of the stars.  Then Fifteen fourth grader 
and sixteen seventh grade students were selected for interviewing 
based on their special and interesting explanations to the 
questions.  The purpose of the afterward interview was to further 
confirm childrenÕs explanations about their responses.  Few more 
questions were added to request the interviewees to explain 
phenomenon with models.  All the process of interview was 
videotaped for later translation and data analysis.


RESULTS

This report will only be covering one small part of the major 
study.  As described before, after the questionnaire, we also 
used interviewing technique and models to further investigate 
childrenÕs conceptions about the stars and its relationship 
between the sun and the moon.  However, in this paper, we will 
limit our presentation in some preliminary findings from the 
questionnaire.

The shape of  the stars.ÿ
The students were asked to describe the shape of the stars.  
Table 1 presents the fourth and seventh gradersÕ responses to the 
question.  It reveals that 62.4% of the seventh graders 
considered the stars are round.  Among them, 41.9% considered 
that the surface of the stars have some holes, just like the 
surface of the moon.  However, 61.1% of the fourth graders thout 
that the stars are stary ÒblinkingÓ and all of them were unable 
to provide any descriptions for the surface of the stars.


Relative sizeÿ

Table 2 shows the responses of the fourth and seventh graders to 
the question ÒPlease list the order of the sizes of the sun, the 
earth, the moon, and the stars.Ó.  About 75.3% of the seventh 
graders were able to show sun > earth > moon while only 34.4% of 
the fourth graders were correct.  Within each grade, majority of 
students considered that the stars are smaller than the sun 
(33.3% for the fourth graders and 55.9% for the seventh graders 
respectively).  Not surprisingly, there is  a quite large group 
of fourth graders (43.3%) considered that the earth was the 
biggest (earth > sun > moon) which was consistent with other 
research results in astronomy (Vosniado and Brewer, 1989).  

Table 3.1 indicates that among the 55.9% of the seventh graders, 
41.9% of them consider the stars were the smallest as opposed to 
28.9% of the younger children.  Also, there were 11.8% of the 
older children considered the stars can be smaller than the sun 
but bigger than the earth and the moon.  Even though more than 
10% of the students from both grades considered the moon is 
bigger than the earth, again, most of them still considered the 
stars are the smallest (see Table 3.2).  This finding suggests 
that our students simply use their intuition and observational 
experiences to judge the scientific phenomenon.

As described before, we also interviewed some students to examine 
their mental models about if the star can be seen at different 
time frame.  We present here with some premitive results from the 
interview.  Basically, there are five types of studentsÕ 
conceptions about the relationship between the sun, the earth, 
and the star in terms of their movement and .  The five types 
are: 

Type I: None of the sun, the earth, and the star      moves. 
Type II:  The star moves but the earth does not. 
Type III:  Both the star and the earth move.
Type IV:  The earth moves but the star does not.
Type V:  Correct mental model of the phenomena.ÿ

Figure 4.  The earth moves but the star does not.

IMPLICATIONS

The findings from this study show that the younger children 

explain the observational astronomy based on their own personal 
experiences or their imagination while the older children are 
able to apply their scientific knowledge to the phenomenon and 
provide logical explanations to the problem situations.  Also, 
the younger children ÒseeÓ the solar system from their own 
personal points of view so that about half of them considered the 
earth is biggest among the sun, the moon, and the stars.  Knowing 
childrenÕs conceptions about the stars, we, as science educators, 
might be able to design some instructional aids for helping them 
construct meaningful and useful mental models to learn astronomy.

REFERENCE

Ausubel, D. P. (1968). Educational psychology: A cognitive view.  
New York:  Holt, Rinehart, & Winston.

Carey, S. (1985).  Conceptual change in children.  Cambridge, MA: 
MIT Press.

Chi, M. T. H. (1992).  Conceptual change within and across 
ontological categories:  Examples from learning and discovery in 
science.  In R. Giere (Ed.), Cognitive models of science 
(Minnesota studies in the philosophy of science, vol 15, 129-
186).  Minneapolis:  University of Minnesota Press.

Driver, R. & Easley, J. (1978).  Pupils and paradigms:  A review 
of literature related to concept development in adolescent 
science students. Studies in Science Education, 5, 61-84.

Finegold, M. & Pundak, D. (1991).  A study of change in studentsÕ 
conceptual frameworks in astronomy, Studies in Educational 
Evaluation, 17, 151-166.

Gentner, D. & Stevens, A. L. (Eds.). (1983). Mental models. 
Hillsdale, NJ: Erlbaum.

Holland & N. Quinn (Eds.) (1986). Cultural models in thought and 
language. Cambridge UK:  Cambridge University Press.

McCloskey, M. (1983).  Naive theories of motion.  In D. Gentner & 
A. L. Stevens (Eds.), Mental models. Hillsdale, NJ: Erlbaum.

Nussbaum, J. (1986).  StudentsÕ perceptions of astronomical 
concepts.  Proceedings of the GIREP Conference, Copenhagen.

Viscuso, S. R. & Spoehr, K. T. (1986). How does a mental model 
facilitate comprehension of instructions? Paper presented at the 
annual meeting of the Psychonomic Society, New Orleans, LA, 
November.

Vosniadou, S. and Brewer, W. F. (1992). Mental models of the 
earth:  A study of conceptual change in childhood, Cognitive 
psychology, 24, 535-585.ÿ

Vosniadou, S. and Brewer, W. F. (1989).  A cross-cultural 
investigation of childrenÕs conceptions about the earth, the sun, 
and the moon: Greek and American data.  In H. Mandl, E. DeCorte, 
N. Bennett, & H. F. Friedrich (Eds.), Learning and instruction:  
European research in an international context (vol. 2.2, 605-
629).  Oxford: Pergamon.

Williams, M. D., Hollan, J. D., & Stevens, A. L. (1983).  Human 
reasoning about a simple physical system.   In D. Gentner & A. L. 
Stevens (Eds.), Mental models.  Hillsdale, NJ: Erlbaum.

Table 2.  Percentage to the question ÒWhat is the order of the 

sizes    of the sun, the earth, the moon, and the starsÓ.

Table 3.1  Sub-analysis to sun>earth>moon when stars

Table 3.2.  Sub-analysis to sun>moon>earth when stars

Relative distanceÿ

Table 4 presents the percentage of responses to the question 
regarding to the relative distances of the earth, sun, moon, and 
stars.  87.2% of the seventh graders know the sun is farther than 
the moon as opposed to 58.9% of the fourth graders.  54.9% of the 
seventh graders considered the stars are even farther than the 
sun, whereas there are only 22.3% of the fourth graders thought 
so. There were similar percentages of the fourth and seventh 
graders considered the stars are closer to the earth than the sun 
or even than the moon, 36.6% for the fourth graders and 32.3% for 
the seventh graders respectively. Surprisingly, we found that 
over one fifth of young children considered the sun is the 
closest (22.2%).  This might have something to do with the size 
of the sun which is relatively larger than the moon and the 
stars.  

Table 4.  Percentage of responses to the question ÒWhat is the  
correct order of the earth, sun, moon, and stars if we      
arrange them according to size?Ó by grade level.  
ÿ
Formation of the starsÿ

Table 5 indicates that 56.1% of the seventh graders were able to 
use scientific explanations to interpret how the stars were 
formed, such as explosion, collision, or cluster.  However, only 
19.9% of the fourth graders attributed the cause to these 
factors.  For those younger children, they tended to answer the 
question by providing responses like ÒmythÓ, Òby its natureÓ, 
Òfrom other planetsÓ , Òby meteoriteÓ, ÒI donÕt know.Ó,  and so 
on.

Table 5.  Percentage of responses to the question  ÒWhat causes 
the formation of the stars?Ó

Why the stars shine?
ÿ
Table 6 indicates that 40.9% of the seventh graders replied that 
the stars can shine from its own body while only 18.7% of the 
fourth children thought so.  We have to note that 42.2% of the 
younger children considered the stars reflect the sunlight 
whereas only 26.9% of the seventh graders used this 
interpretation.  Also, over 1/5 of the fourth graders were unable 
to give explanations.


The stars are created by God, Man, ancient people, scientists, or 
absorbing the essence of the sun and the moon.
      
Table 6.  Percentage of responses to the question ÒWhy the  stars 
shine?Ó

Do the stars move?ÿ
This is a set of question about an event.  The questions were 
formed as follows.  
     
(1) Can you see the star at 3 AM if it was above your head  at 
midnight?  Please explain why.
(2)  Can you see the same star at noon? Please explain why.


Among 93 seventh graders, 71.1% of them replied ÒYes.Ó to the 
first question and 59.1% of the fourth graders did so.  23.8% of 
the seventh graders said NO as opposed to 33.4% of the fourth 
graders (See Table 7).  Most of them were able to provide with 
some explanation except a low percentage of them.  Only few were 
unable to provide with yes or no answer (6.7% for 7th and 5.4% 
for 4th graders respectively).

Table 7 shows reasons that the students gave when they answered 
ÒYes.Ó to the question (1).  Among 93 seventh graders, there were 
21.5% of the older children able to attribute the phenomena to 
earthÕs rotation whereas only 1.1% of the fourth graders were 
able to do the same.  About one fourth of the fourth graders 
considered that the star has moved to where we could not see it.

Table 7.  Percentage of responses to the question of   ÒCan you 
see the star at 3 AM if it was      above your head at midnight?  
Please    explain why.   


For the second question, although very high percentages of our 
subjects answered ÒNo.Ó (94.7% for the seventh and 82.3% for the 
fourth graders, see Table 8), the distributions of the 
percentages of their answers were quite different.  Besides a 
relatively high percentage goes to ÒThe sunlight is too 
strong.Ó(50% for the fourth graders and 47.3% for the seventh 
graders respectively), 21.5% of the seventh graders were able to 
use earthÕs rotation to explain it and there was even 10.8% of 
the older students were able to provide with a more complete 
answer (rotation and sunlight).  However, there were 17.8% of the 
younger children used story-telling strategy to explain the 
phenomenon.  Finally, it is quite reasonable to find that very 
few subjects considered that the star can be seen at noon.

Table 8.  Percentage of responses to the question of ÒCan  you 
see the same star at noon?  Please explain    why. 

Mental models of an astronomical eventÿ
ÿÿÿ
Note: 6.7% of 4th graders and 5.4% of the 7th graders did not 
provideanswers.

Note:  8.9% of the fourth graders and 4.3% of the seventh, 
graders did not provide answers.

Figure 1, a typical example by a young child, 401 (first digit 
stands for the grade and the other two digits for observational 
number), indicates that none of the sun, the earth, and the star 
moves.  The reason we cannot see the star at noon is simply 
because the sunlight is too strong (The circle on the left hand 
side represents the sun, regardless of its size.  The circle with 
a stick (as a person) on it represents the earth.  The smallest 
circle represents the star.).

    
Figure 1.  None of the sun, the earth, and the star moves   
(three 4th graders).

Subject 401

S: We cannot see the star because the sun light is too strong.

Figure 2 shows that the younger children tended to consider the 
earth is the largest planet and it does not move in this event 
(same as subject 401).  As you can see, the young child (404) 
does not take the sun into account as shown in Figure 1.  The 

star is always above the person (stick) although it moves 
slightly from time to time.  This information supports what we 
have discussed earlier about lacking of the knowledge of earthÕs 
rotation and making the use of egocentric viewpoints.



Figure 2.  The star moves but the earth does not   (ten 4th 
graders). 
Subjec 404

S:  The star can been    S: We cannot see             
seen at east.                   the star at west because of 
                                the strong sunshine.   

About one third of the seventh graders considered both the star 
and the earth move (see Figure 3) while none of the fourth 
graders thought so.  Due to the earth moves slower than the star 
moves, we were unable to see the star in the sky at noon.  Even 
though the students have the concept of earth rotation, they were 
unable to relate it to the situation.  Therefore, they attribute 
the incorrect cause to this event.

Figure 3.  Both the star and the earth move (five 7th  graders). 

Figure 4 shows that the students  (two 4th and eight 7th graders) 
consider the star stays constantly at the same place.  The reason 
we were unable to see the star is because the earth rotates so 
that we are not at the right place for it.

Finally, the Figure 5 indicates a mental model held by a seventh 
grader, the subject 703, which not only does he use the correctly 
relative sizes to represent the sun, the earth, and the moon, but 
he also takes the light source into account to show their 
relationships of position.  Only seventh graders were found for 
this type. 

Figure 5.  Correct mental model of the phenomena  (four 7th 
graders).