a 
  

© 2020 Indonesian Society for Science Educator 117 J.Sci.Learn.2020.3(2).117-123 

 

Received:  12 December 2019 

Revised: 5 March 2020 

Published: 19 March 2020 

 

 

The Relation between Gender, Reasons to Participate in STEM-Related 
Subjects, Programs and the University Supports on First-Year University 
Student’s Satisfaction: A Structural Equation Model 

Ikmanda Nugraha1*, Tatang Suranto2, Asep Kadarohman3, Ari Widodo4, I Gusti Darmawan5 

1Department of Science Education, Universitas Pendidikan Indonesia, Bandung, Indonesia 
2Elementary School Teacher Study Program, Universitas Pendidikan Indonesia, Serang, Indonesia 
3Department of Chemistry Education, Universitas Pendidikan Indonesia, Bandung, Indonesia 
4Department of Biology Education, Universitas Pendidikan Indonesia, Bandung, Indonesia 
5School of Education, The University of Adelaide, Adelaide, Australia 
 

*Corresponding Author. ikmandanugraha@upi.edu 

ABSTRACT First-year student's satisfaction has considered an important factor in the quality education offered by the university 
program. The objective of this study is to investigate the relationship among gender, a reason to participate in STEM -related 
subjects, program, and the university support on first-year student's satisfaction of STEM learning. The methods used in this 
study surveyed student's satisfaction using adapted interest and recruitment in the science questionnaire (IRIS Q) instrument. The 
questionnaire comprised question items covering school science experiences, sources of inspiration for the choice of education, 
expectations for future job, first-year experiences as a STEM student, and attitudes to gender equity in STEM. A total of 448 
students, first-year students from STEM-related programs, have participated voluntarily in this study. The structural equating 
model assisted by computer program IBM SPSS Amos 20 was employed to analyze the hypothesized model. The results from 
the model showed that reason and university support have a positive direct effect on first-year students' satisfaction with STEM 
learning. From this study, it is suggested for the university to improve first-year student's satisfaction by helping STEM students 
to develop appropriate expectations of the program, facilitating teaching quality to meet STEM students' learning, and assisting 
students in developing positive attitudes toward their future carriers. 

Keywords Structural equation model, STEM learning, first-year university students, satisfaction student’s satisfaction. 

1. INTRODUCTION 
In higher education, the issues of student satisfaction 

have been a great concern among researchers, 
policymakers, and practitioners. The point of student's 
satisfaction has become the major concern of many 
research, and the majority of the studies agreed that 
student's satisfaction has a strong correlation with 
university supports (e.g., Crisp et al., 2009; Duong, 2015; 
Green, Hood, & Neumann, 2015; Gruber, Fuß, Voss, & 

Gläser‐Zikuda, 2010; Hakim, 2014; Josephat, Ismail, & 
Martin, 2014; Li & Carroll, 2017; Lo, 2010; Mehdipour & 
Zerehkafi, 2013; Möller, 2006; Naaj, Nachouki, & Ankit, 
2012). Most of the finding discuss that student's 
satisfaction can be used as the indicators to identify the 
areas where the university are performing well. Moreover, 
it can use for performing strategies to retain and fit the 
students, providing insights or reputation of the university 

from people, and providing feedback for future program 
planning (Billups, 2008). 

The first-year student becomes the concern because, 
this year, the student will decide whether they will stay or 
leave in STEM-related subjects. In the middle of various 
issue related to the reducing interest of students to 
participate in science, technology, engineering and 
mathematics (STEM) related subjects, the issue of lack of 
teaching quality come to the surface as one of the 
determinants of student's satisfaction.  In the United 
Kingdom, students from STEM programs satisfied with 
funding and supporting facilities, but they were unsatisfied 
with the STEM teaching. In contrast, students from non-
STEM programs experienced different directions (Pawson, 

mailto:ikmandanugraha@upi.edu


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2012). Because teaching practices are context-specific 
(Shulman, 1987), it is evident that certain teaching practices 
are common in a university STEM teaching but different 
from another social discipline. Moreover, students in a 
university STEM classroom probably have different 
learning needs compared to students in different subject 
areas, such as laboratory activities or site visits (Chang & 
Park, 2014). This finding has encouraged STEM teaching 
to satisfy the students expectation because teaching quality 
and expertise showed the most reliable relationship with 
student's satisfaction and their learning outcomes (Green, 
Hood, & Neumann, 2015; Hakim, 2014; Lo, 2010; 
Suarman, Aziz, & Yasin, 2013; Burgess, Senior, Moores, 
2018; Khalil-Ur-Rehman, Farooq, & Younas, 2018; Son, 
Ha, Thi, & Khuyen, 2018). 

In terms of lecturer-student interaction, the study from 
a university in Australia found that students expect the 
university to provide learning resources that can be 
accessed by the students anytime and anywhere. Lectures 
need to engage students in interactive activities, student 
works must be read and give feedback, and the assessment 
marked and returned to them (Crisp et al., 2009). On the 
other hand, the university's core service, i.e., the lecture, 
including the attainment of knowledge, class notes and 
materials, and classroom delivery, are more important than 
the physical aspects of the University services (Douglas, 
Douglas, & Barnes, 2006). 

Another study showed different findings such as (1) 
students' satisfaction with their university is based on a 
relatively stable person-environment relationship (Gruber, 

Fuß, Voss, & Gläser‐Zikuda, 2010), (2) college curriculum 

needs to meet the student's expectation (Zhou, 2016), (3) 
physical facilities and staff responsiveness also play an 
important role for student's satisfaction (Ahmed & Masud, 
2014), (4) gender play different perspective, female 
students put higher expectation and demanding on the 
importance of university services than male students 
(Grebennikov & Skaines, 2009), (5) gender and the 
program do not have a significant influence on student's 
satisfaction (Elhadary, 2016a), (6) a sense of belonging, and 
citizenship knowledge and skills were the best determinants 
of the level of first-year student satisfaction (Al-Sheeb, B., 
Hamouda, A. M., & Abdella, G. M. (2018). To sum up, it 
should also be noted that student satisfaction results not 
only from quality in teaching and learning, but it also comes 
from total student's experiences in their study (Wilkins, 
Balakrishnan, & Huisman, 2012). Therefore, to study 
student satisfaction, many other factors must come into 
consideration, such as ethnographic information, motives, 
assessment and Feedback, learning resources, facilities, 
social life, etc.  

Based on the literature above, the author formulated the 
following hypothesized model (Figure 1) that describes the 
determinants of student satisfaction. Accordingly, the 
author hypothesizes that the following factors will have a 
positive direct effect on student satisfaction: 1) gender, 2) 
reason to participate in STEM-related subjects, 3) 
programs, and 4) university support. All the factors are 
included in the hypothesized model because they have the 
possibility to become the determinants of student 
satisfaction. Using Structural Equation Model (SEM) 

 
Figure 1 Hypothesized model of first year student satisfaction 

 



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analysis, this study intended to test the good-fit of the 
hypothesized model.  

In the hypothesized model, gender as an observed 
variable. The reason to participate in STEM-related 
subjects as a latent variable was formed from school 
science experience, influential others, and daily inspiration. 
The factor has confirmed through confirmatory factor 
analysis (CFA) as a single factor with RMSEA value (0.101). 
The program, as observed variable, consists of seven major 
programs. They are mathematics, chemistry, physics, 
biology, agriculture, health, and engineering. In the 
hypothesized model, mathematic did not appear because it 
treated like a dummy. Therefore only six programs appear. 
University support as a latent variable constructed from 9 
items from the IRIS Q questionnaire. 

2. METHOD  
The sample (N=448) were first-year university students 

who registered in STEM-related subjects in Bandung, West 
Java Indonesia. The sample consists of 237 male students 
and 211 female students from seven major STEM-related 
subjects (mathematics, chemistry, physics, biology, 
agriculture, health, and engineering). The sample is 
randomly selected by distributing the online questionnaire. 
The sample gathered in this study was the students who 
voluntarily filled the online questionnaire completely.  

Under the permission of IRIS International, the IRIS Q 
questionnaire was translated into Bahasa Indonesia by one 
translator. From Bahasa Indonesia, the survey was back-
translated into English by another translator to ensure 
consistency and minimize the loss of meaning. The final 
form of the questionnaire was in Bahasa Indonesia after all 

Table 1 IRIS Q questionnaire  

 No  Components CODE 

 
How important was each of the following school experiences in choosing your 
course? 

School Experiences 

1 Your interset in related subjects SCEXP1 
2 Your previous attainment in related subjects SCEXP2 
3 Experiment/Lboratory work SCEXP3 
4 Field work/Excursions SCEXP4 
5 Lessong showing the relevance of the subject to the society SCEXP5 
6 Lesson showing practical applications of the subjects SCEXP6 
7 using mathematics in lessons SCEXP7 
8 Clear Feedback on wheter you got the right answer SCEXP8 

 How important were the following persons in choosing your course? Influential others/people 

9 Mother or step mother PP1 

10 Father or step father PP2 

11 Good teachers PP3 
12 Friends (Including boyfriend/girlfriend) PP4 
13 Sibling or other relatives PP5 
14 Carriers advisor in school PP6 

 How important were each of the following in choosing your course? Daily Inspiration 

15 Popular Science books and magazines DLYEXP1 
16  Science Fiction or fantasy book/films DLYEXP2 
17  Computer games DLYEXP3 
18  Museum/Science center DLYEXP4 
19  Popular science television program (Discovery Channel, National Geographic, etc.) DLYEXP5 
20  Film or drama on television (CSI, Numbers, Etc.) DLYEXP6 
21  Science, Technology, or Mathematics competitions DLYEXP7 
22 Other kinds of outreach activities (e.g. Science Festivals, Science Summer Schools) DLYEXP8 

 
To what extend do you agree with the following statements about university 
supports and your experiences as student so far? 

University support/ 
experiences as student 

23 I enjoy the company of the other students on my course UNI1 
24 I feel I fit in socially UNI2 
25 I feel I can keep up with the pace of the teaching UNI3 
26 I get personal feedback from lectures and teachers when I need it UNI4 
27 I feel my teachers care about whether students learn or not UNI5 

28 
The university/college offers good working conditions (equipment, library, common 
areas, cafes, technical support 

UNI6 

29 I can see the relevance of what I learn UNI7 
30 I feel that my course suits the kind of person that I am UNI8 
31 I have become more interested in the subject since I started UNI9 

 



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of the translators meet their agreement. The original IRIS 
Q comprises 65 items, but only 31 elements administered 
for this study (Table 1). Questions on the IRIS Q 
responded using a 5-point Likert Scale, ranging from 1 
(Strongly Disagree) to 5 (Strongly Agree). The adapted 
IRIS Q consists of three components, school science 
experience (8 items), influential others (6 items), and daily 
source of inspirations (8 items) and university 
support/experiences as students (9 items). The adapted 
IRIS Q then uploaded as an online questionnaire and 
randomly distributed to first-year students in STEM-
related subjects by using the student's association network. 

First, confirmatory factor analysis (CFA) was 
performed to identify underlying factors of the reason to 
participate in STEM-related subjects. The result showed 
that the constructs of the instrument are consistent with a 
researcher's understanding of the nature of that construct 
(or factor). Second, the structural equation model (SEM) 
analysis performed using IBM SPSS Amos 20 (Arbuckle, 
2011) software to assess the causal relationships of the 
factors. SEM that seek the relationship between multiple 
variables as a member of statistical models lies in two 
multivariate techniques: factor analysis and multiple 
regression analysis (Hair, Black, Babin, & Anderson, 2014). 
SEM has been widely to test the model many studies such 
as sociology, psychology, business and marketing, 
education, and many other related studies (e.g., Ahmed & 
Masud, 2014; Archambault, 2008; Sembiring, 2016; 
Camgoz-akdag & Zaim, 2012; Dyana & Adeline, 2014; 

Elhadary, 2016a, 2016b; Gruber, Fuß, Voss, & Gläser‐
Zikuda, 2010; Ijaz, Irfan, Shahbaz, Awan, & Sabir, 2011; Li 
& Carroll, 2017). Hair, Black, Babin, & Anderson (2014) 
explained there are six steps to decide on the fit model. 
They are: (1) define individual constructs, (2) develop 
overall measurement model, (3) formulate the study to 
produce the empirical results, (4) asses the measurement 
model validity, (5) specify the model, and (6) assessing 
structural model validity. In this study, the process of 
analysis was using those steps. In this study, the primary 
purpose of SEM is to simultaneously test the hypothesized 
model relationship among a set of latent constructs.  

In terms of good-fit indices, this study used the 
standard fit indices for an SEM, which are comparative fit 
index (CFI), Tucker-Lewis index (TLI, or non-normed fit 
index), and RMSEA. The TLI and CFI values should be 

greater than or equal to 0.80 and the RMSEA; the value 
should be between 0.08 to 0.10 to get mediocre fit 
(Hooper, Coughlan, & Mullen, 2008). It should also be 
considered that there should be justification for the group 
of fit indices provided, it should converge to a conclusion 
that the data fit the sample model and also it is very crucial 
to determine the overall fit from multiple indices and not 
just a single fit index (Schreiber, 2008). 

Furthermore, the model Chi-square value and degrees 
of freedom should also be reported because some fit 
indices are based on those values but are not typically used 
to justify the fit of the data to the model because of the 
Chi-square value is sensitive to sample size (Schreiber, 
2008). At last, to be considered is because of the volume of 
fit indices, it becomes a temptation to choose the best-fit 
indices that indicate the best fit. It is should also be avoided 
at all costs removing important just because only based on 
the cut-off of fit indices. As a way to improve model fit, it 
is good practice to check the fit of each construct and its 
items individually to specify whether there are any poor 
items (Hooper, Coughlan, & Mullen, 2008). At last, SEM 
is an a priori method; therefore, the removal or addition of 
a relationship during model modification must consider 
theoretical, not just statistical sense. Because modifying 
using statistical results may lead to producing a non-
representative model from the actual data (Schreiber, 2008) 

 
3. RESULT AND DISCUSSION  

 

The hypothesized model was tested by following the 
procedure to test the good-fit of the model (Hair, Black, 
Babin, & Anderson, 2014). There were seven tested models 
to find the good-fit of the model (Table 2). The 
hypothesized model has not fit the actual data with TLI 
value (0.499), CFI Value (0.610), and RMSEA value 
(0.136). Then, to improve the good-fit of the model, the 
insignificant relationships indicated by p-value higher than 
0.05 were excluded in the hypothesized model to form 
tested model 1. In this model (gender to 
satisfaction=0.952), (dummy2 to university 
support=0.717), (gender to university support=0.999), 
(dummy7 to reason=0.837), (gender to reason=0.777), and 
(dummy5 to reason=0.806). After modification, tested 
model 1 showed better fit to the actual data indicated by 

Table 2 Good-fit index for the tested models (n=448) 

No Model CMIN df CMIN/df NFI RFI TLI CFI RMSEA 

1 Hypothesized model  1380.115 148 9.325 0.588 0.471 0.499 0.610 0.136 
2 Tested model 1 1380.291 154 8.963 0.588 0.492 0.521 0.612 0.133 
3 Tested model 2 1383.545 161 8.593 0.587 0.513 0.543 0.613 0.130 
4 Tested model 3 1038.124 147 7.062 0.653 0.597 0.633 0.684 0.116 
5 Tested model 4 1045.640 151 6.925 0.651 0.605 0.641 0.683 0.115 
6 Tested model 5 815.730 150 5.438 0.728 0.690 0.731 0.764 0.100 
7 Tested model 6 294.278 63 4.671 0.876 0.847 0.875 0.899 0.091 

 



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TLI value (0.521), CFI Value (0.612), and RMSEA value 
(0.133) but still has not met the required fit indices.  

Tested model 1 then further analyzed to identify the 
insignificant relationship. To improve the model fit, 
insignificant in this model were excluded to form tested 
model 2 (dummy2 to reason=0.300), (dummy7 to 
university support=0.498), (dummy3 to 
satisfaction=0.699), (dummy2 to satisfaction=0.486), 
(dummy5 to satisfaction=0.641), (dummy6 to 
satisfaction=0.621) and (dummy7 to satisfaction=0.806). 
After modification, tested model 2 showed better fit to the 
actual data indicated by TLI value (0.543), CFI Value 

(0.613), and RMSEA value (0.130) but still has not met the 
required fit indices. 

Tested model 2 further modified to improve the model 
fit by exclude the insignificant relationship to form tested 
model 3, they were (dummy4 to satisfaction=0.177), 
(reason to satisfaction=0.115), (dummy6 to university 
support=0.153), (gender to dummy2=0.108), (dummy2 to 
reason=0.276), and (dummy6 to university 
support=0.153). After modification, tested model 3 
showed better fit to the actual data indicated by TLI value 
(0.633), CFI Value (0.684), and RMSEA value (0.116) but 
still has not met the required fit indices. 

Tested model 3 further modified to improve the model 
fit by excluding the insignificant relationship to form tested 
model 4, they were (dummy4 to satisfaction=0.177), 
(reason to satisfaction=0.115), (dummy6 to reason=0.193), 
(dummy3 to university support=0.150) and (dummy4 to 
university support=0.144). After modification, tested 
model 4 showed better fit to the actual data indicated by 
TLI value (0.641), CFI Value (0.683), and RMSEA value 
(0.115) but still has not met the required fit indices. 

They tested model 4 further modified to improve the 
model fit by excluding the insignificant relationship 
(dummy3 to university support=0.352) to form tested 
model 5. After modification, tested model 5 showed better 
fit to the actual data indicated by TLI value (0.731), CFI 
Value (0.764), and RMSEA value (0.100) but still has not 
met the required fit indices. 

Tested model 5 further modified to improve the model 
fit by excluding the insignificant relationship, but in this 
model, the relationships were all significant. To improve 

Table 3 Factor loading of factor in the good-fit models 

Factor Loading Estimate 

UNISPPRT <--- REASON .556 

SCexp <--- REASON .679 

People <--- REASON .554 

Dailiy <--- REASON .617 

UNI1 <--- UNISPPRT .543 

UNI2 <--- UNISPPRT .572 

UNI3 <--- UNISPPRT .728 

UNI4 <--- UNISPPRT .587 

UNI5 <--- UNISPPRT .530 

UNI6 <--- UNISPPRT .469 

UNI7 <--- UNISPPRT .677 

UNI8 <--- UNISPPRT .832 

UNI9 <--- UNISPPRT .787 

FRYRSTF <--- UNISPPRT .615 

 

 
Figure 2 Final model of first year student satisfaction (standardized)  
 



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the model by considering closely related errors, the author 
correlated error4 and error5 because of both of the highly 
correlated. The author also excluded gender and program 
because they were not significantly having a direct effect on 
student satisfaction confirmed by an independent sample 
t-test and one-way ANOVA. An independent sample t-test 
showed that there were no significant differences of 
satisfaction between male (M=10.01; SD=1.90) and female 
(M=9.99; SD= 1.82; t(446)=1.62, p=0.90, two-tailed). 
While program also showed that there was no significant 
difference at the p <.05 in the groups: F(6,441)= 0.74, p= 
0.62. Mathematics (M=10.03; SD=1.56), Chemistry 
(M=10.40; SD=1.98), Physics (M=9.85; SD=1.50), Biology 
(M=10.50; SD=1.89), Agriculture (M=9.86; SD=2.05), 
Health (M=9.91; SD=1.92) and Engineering (M=10.00; 
SD=1.86). After modification, tested model 6 showed 
better fit to the actual data indicated by TLI value (0.875), 
CFI Value (0.899), and RMSEA value (0.091) and also met 
the requirement for model fit to the actual data (figure 2). 

All of the factor loadings in the tested model 6 met the 
minimum requirement (0.32), as can be seen in table 3. 
(Hair, Black, Babin, & Anderson, 2014). That signified that 
construct validity is adequate. The model also showed that 
reason, and university support indirectly explained 38% of 
the total variances of student's satisfaction and reason 
explained 31% of total variations of university supports. In 
this case, the model can consider contributing to the 
planning of the university program. 

This study explored the relationship gender, reasons to 
participate in STEM-related subjects, programs, and the 
university supports on first-year university student's 
satisfaction. The SEM results showed that students' 
satisfaction with STEM learning is highly affected by 
university supports (experiences as a student) which is 
consistent with previous studies that university supports 
highly correlated with student's overall satisfaction (Crisp 
et al., 2009; Green, Hood, & Neumann, 2015; Gruber, Fuß, 

Voss, & Gläser‐Zikuda, 2010; Hakim, 2014; Lo, 2010; 
Suarman, Aziz, & Yasin, 2013; Wilkins, Balakrishnan, & 
Huisman, 2012). This result confirms and strengthens the 
fact that student satisfaction can be used as indicators to 
identify the areas where the university is performing well. 
Moreover, it can also apply for performing strategies to 
retain and fit the students, providing insights or reputation 
of the university from people, and providing feedback for 
future program planning (Billups, 2008). 

Gender and program are excluded in the model because 
both showed no difference in terms of satisfaction 
confirmed by independent sample t-test and one-way 
ANOVA, so it is unnecessary to control the effect from the 
model.  This finding also consistent with the previous study 
that gender and program do not have a significant influence 
on student's satisfaction (Elhadary, 2016a). Female 
students put higher expectations and demands on the 

importance of university services than male students 
(Grebennikov & Skaines, 2009). 

In the model, UNI1 and UNI2 are highly correlated; 
this is because after checking the items, the statements 
from both items are asking quite a similar question. UNI1 
(I enjoy the company of the other students on my course) 
and UN2 (I feel I fit in socially). Both of them asking the 
social life and interaction of the student. 

The model also showed that reason and university 
support indirectly explained 38% of the total variances of 
student's satisfaction and reason itself explained 31% of 
total variations of university supports. In this case, the 
higher the reason, the more the students need university 
support, and the more the university supports the students, 
the more they feel satisfied. This finding is in line with the 
previous research that highlight the more the university 
helps the students the more they feel satisfied (Al-Sheeb, 
Hamouda, & Abdella, 2018; Son, Ha, Thi, & Khuyen, 2018; 
Burgess, Senior, Moores, 2018; Khalil-Ur-Rehman, 
Farooq, & Younas, 2018: Tandilashvili, 2019). Knowing 
this finding, the university needs to manage the students as 
customers by providing the supports which able to prepare 
the students for successful carrier and worthy employment 
after graduation. Seem like the business industry, which 
depends on customer satisfaction. When the students 
satisfied with the university, indirectly, they will share and 
encourage people to choose the programs that make them 
satisfied. If the university is able to achieve it, it is also 
indicating that the university is performing well to provide 
education that fit the students and the society in general. 
 

4. CONCLUSION 
This study is an exploratory way using SEM that was 

conducted based on data obtained from students in STEM-
related subjects in West Java Province. As a result, it should 
be considered to confirm if the final model in this study 
can be generalized to other university students in general. 
For the next future studies, it is essential to verify the 
existence of the model constructs and the structural 
relationships between constructs using the data obtained 
from other university students to generate a better 
generalization. 

 

 

ACKNOWLEDGMENT 
The author would like to thanks Ellen K. Henriksen for 

permission to adapt the IRIS Q instrument and Che Yee 
Lye and AAI Awardees 2017 for their helpful lessons, 
advice, and supports during the data analysis. 

 

 

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