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Article

Analysis of Factors Affecting Academic Performance of Mathematics Education Doctoral Students: A Structural Equation Modeling Approach

1
School of Mathematical Sciences, Beijing Normal University, Beijing 100875, China
2
Teachers College, Columbia University, New York, NY 10027, USA
3
School of Mathematics and Statistics, Hunan Normal University, Changsha 410081, China
4
Mathematics Education Department, Universitas Syiah Kuala, Banda Aceh 23111, Indonesia
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Int. J. Environ. Res. Public Health 2023, 20(5), 4518; https://doi.org/10.3390/ijerph20054518
Submission received: 20 January 2023 / Revised: 22 February 2023 / Accepted: 27 February 2023 / Published: 3 March 2023
(This article belongs to the Special Issue 2nd Edition of Parental Attachment and Adolescent Well-Being)

Abstract

:
Student academic performance is an important indicator of doctoral education quality, but limited research has focused on how multiple influential factors of doctoral students’ academic performance work together. This study aims to explore the factors significantly affecting the academic performance of mathematics education doctoral students in Indonesia. Several factors were recognized from prior studies, such as the fear of delay, student engagement, parental support, teacher support, facilitating conditions, stress level, and well-being. An online questionnaire was designed and answered by a total of 147 mathematics education doctoral students. The partial least squares structural equation modeling (PLS-SEM) approach was adopted to analyze the questionnaire data. The results suggested that teacher support had the strongest positive effects on mathematics education doctoral students’ academic performance in Indonesia. Student engagement was the most significant positive factor in improving doctoral students’ well-being, while parental support could most significantly reduce their stress levels. Practically, these results are expected to provide implications to universities and supervisors regarding the improvement of doctoral students’ well-being to promote their academic success and further the quality of doctoral programs in education. Theoretically, these results can also contribute to building an empirical model that can be used to explore and explain how multiple factors could affect doctoral students’ academic performance in other contexts.

1. Introduction

Achieving academic success at the doctoral level is very arduous, and there is a high dropout rate and a poor satisfaction level among doctorate students [1,2]. The doctoral attrition rate varies from 30% to 90% across different cultural backgrounds [3,4], and the average satisfaction rate of doctoral programs was not optimistic [5]. Attrition of doctoral students indicates a high price for institutions, as the Ph.D. students are mostly responsible for a large share of academic output and financial input [6]. More importantly, Ph.D. students, who were admitted to the doctoral programs with the most brilliant achievement, suffered from the heavy cost of dropout. Though quitting doctoral programs does not mean failure, students may suffer from physical and psychological disorders as well as a great loss of time and money [7].
Contrary to the high dropout rate of doctoral students, previous studies suggested a proliferation of doctoral education programs in East Asia. Policymakers started to provide equally intensive input into doctoral education as their counterparts in America and Europe to increase the number of world-class ranked universities [5]. With a strong intent of training domestic scholars and knowledge-makers to improve university research performance, active reforms were implemented to improve doctoral training quality and raise the number of doctorates within East Asian countries. Examples include Brain Korea 21, China’s 985 Project, and Japan’s Top Global University. According to UNESCO, China has become the world’s second-largest doctoral-degree-granting system. Other developing Asian countries also witnessed a rapid increase in the number of students involved in doctoral programs [8,9,10]. However, most studies on East Asian doctoral education concentrated on developed countries, with less emphasis on other developing nations. Considering this situation, the exploration of the factors affecting the academic achievement of doctoral students is of great practical significance for empirical evidence and implications on how to provide better support for Ph.D. students in developing East Asian countries.
The latest trend in the investigation of doctoral students’ academic success is to stress the importance of individual, social, and environmental factors. Scholars have studied multiple psychological factors at the individual level that can influence doctoral students’ achievement. As individuals’ consistent endeavors are indispensable to generate academic output, students’ willingness to become engaged in learning was well recognized as a significant indicator of their academic performance in the higher education context [11,12]. The findings on student engagement have triggered researchers’ interest in other emotional factors that can influence the extent to which students actively get involved in their doctoral training. Besides the well-studied importance of doctoral students’ well-being as a premise for active learning [13], negative emotions such as fear and stress were suggested to have unfavorable effects on their academic performance. Pascoe and colleagues examined the impact of stress across different educational levels and found that stress can undermine students’ learning capacity, bring mental and physical health issues (e.g., depression and sleep disturbances), and further influence their academic performance [14]. Such stress can be more common among social sciences doctoral students as they will find it more difficult to secure financial support than their peers in nature sciences [15]. Similarly, the fear of failure can increase doctoral students’ mental health problems and have further negative effects on their academic achievement [16]. Such fear is more common for doctoral students in social sciences as they tend to spend more time to obtain degrees than their peers in natural sciences or humanities [2,17,18]. Besides the significance of these individual factors, it is also believed that support from parents, supervisors, and institutions are of equal importance in completing doctoral degrees [19,20,21]. These studies lamented insufficient exploration of how individual and environmental factors can work together in doctoral students’ academic success in a specific area. Therefore, it is necessary to explore the complex mechanism of factors contributing to doctoral students’ success in a specific branch of social sciences.
Previous studies examining the influential factors of doctoral students’ success rarely focused on the multifaceted nature of achievement at the doctoral level. The completion of the doctoral program was commonly used as an indicator of academic success at the doctoral level. However, according to Bagaka’s et al. [22], taking “All But Dissertation” (ABD) as equivalent to the success of doctoral students undermined the aim of successful doctoral education programs. To prepare scholars to be sufficiently grounded in subject content and research, doctoral education programs have more ambitious goals of individual achievement, including performance in coursework, mastery of subject content knowledge, academic writing and oral communication skills, self-learning ability, and critical thinking ability, as well as valuable personal characteristics such as perseverance and commitment to excellence. According to Cullen, subjects in social science are identified to belong to the Pure/Applied cluster, where there is no specific paradigm but a concentration on practice in the subject [23]. Studies focusing on social science doctoral students’ academic achievement have specified many skills that marked a successful doctoral student (e.g., academic writing skills [24], learning strategies [25], and a synthesis of academic skills and coursework [26]). In the field of education, one of the most practice-oriented social science subjects, there are more requirements to prepare qualified education doctoral students (e.g., their epistemological diversity [27], and their ability as a practitioner researcher [28]). Though there were many studies on education doctoral students, few quantitative studies focused on the academic performance of mathematics education doctoral students as a specialization field in education.
Doctoral programs in mathematics education were provided worldwide to prepare mathematics educators with doctorates [29,30,31]. The U.S. had the first mathematics education doctoral programs in the 1900s, and the number of people with a doctorate in mathematics education is increasing [32]. Countries in Asia have also witnessed an increase in the number of mathematics education doctoral graduates, though this number is always limited (e.g., twenty a year in China). The Indonesian government has been making efforts to increase the number of researchers with doctorates in mathematics education. In recent years, each Indonesian university has admitted 15–20 doctoral students in mathematics education every year. The length of doctoral programs in Indonesia is 3–4 years, and students generally need a master’s degree in a relevant major and proficiency in at least one foreign language, such as English or Mandarin to obtain admission to the program. The students should also have good analytical skills and the ability to collaborate with teams. Moreover, every doctoral student needs to obtain at least 72 credits and satisfy the requirement of research activities for graduation. These activities include assistantship in research projects, presentations at international conferences, and at least 2 Scopus-indexed journal publications. Mathematics education doctoral students in Indonesia are required to report to the supervisor regarding proposal writing, the progress of data collection, and the presentation of results. Before advancement to graduation, the research outputs and dissertations need to be reviewed by the academic committee, which consists of three professors in mathematics education. Most of the mathematics education doctoral students in Indonesia are married, and some of them are employed by universities or government agencies with tight schedules. A few of them graduated in three years, but on average it took 4 to 5 years to finish their programs. However, funding is provided for four years at most. In this case, the main problems commonly encountered by these students are expensive tuition fees if they are delayed in achieving the doctoral degree, and publications in Scopus-indexed journals.
This study aims to explore and determine the factors affecting the academic performance of mathematics education doctoral students in a developing Asian country, as well as investigate the underlying mechanism. Based on the questionnaire data obtained from 147 Indonesian doctoral students in mathematics education, the structural equation modeling approach was used to explore how the pre-identified factors can affect their academic achievement. This statistical evidence would suggest the power of different influential factors, as well as be useful in the construction of their interactive paths toward influencing academic success at the doctoral level. Moreover, the results obtained are expected to contribute to the theoretical framework of doctoral students’ academic success and its link with multiple personal and environmental factors. These contributions could provide practical implications for stakeholders regarding how to better support mathematics education doctoral students in their academic careers.

2. Theoretical Background and Hypothesis Development

In this section, we first specify indicators of doctoral academic performance. It follows by reviewing prior studies on factors affecting doctoral students’ academic performance. The review results are synthesized according to the seven individual and environmental factors we identified from past studies. Finally, we developed our hypotheses to build the empirical model of influential factors.

2.1. Doctoral Students’ Academic Performance Indicators

Great efforts have been made by higher education studies to investigate the quality of doctoral education and the academic performance of Ph.D. students. Recent research adopted the rates of attrition [33], retention [34], completion [35], or on-time graduation [20] as indicators of doctoral education quality. These indicators separately portrayed the academic achievement of doctoral students based on the following two perspectives: continuous enrollment in their doctoral study and completion of their degrees (in time). For doctoral success, the use of these indicators is rational, considering the high dropout rates of doctoral students across different cultural backgrounds. However, Olehnovica et al. [36] suggested that the success of doctoral study should be more than “all but dissertation” (ABD) and be highly concerned with the competencies of doctorates as a scholar, including knowledge of research in specific areas and critical interpersonal skills [36]. Although obtaining a doctoral degree is counted as a great achievement, key indicators of doctoral students’ achievement also include performance in coursework, mastery over subject content knowledge, academic writing and oral communication skills, self-learning ability, critical thinking ability, as well as valuable personal characteristics (e.g., perseverance and commitment to excellence) [37]. These studies have highlighted doctoral success as a combination of internal and external achievement, despite the huge differences in the academic performance of doctoral students across disciplines.
Multiple indicators were used to comprehensively delineate doctoral students’ academic performance rather than simply measuring their completion of degrees. In the field of education, one of the most practice-oriented subjects, there are more requirements to prepare education doctoral students (e.g., epistemological diversity [27] and the ability as a practitioner researcher [28]). On the basis of literature and theory review, Olehnovica and colleagues [36] divided the academic competence of the students into three categories according to the context and the level of comprehension. The first one is informative competence (F1), which concerns decisions on the structure, content, and strategy of research. Secondly, communicative competence (F2) refers to the ability to become involved in local and global research environments. The last indicator is instrumental competence (F3), which concerns collection procedures and interpretations of the research data. The comprehensive framework they proposed to specify doctoral students’ competence was proven to be valid among students who participated in the “Pedagogy” doctoral program. This validation also justifies our reference to this framework to conceptualize mathematics education doctoral students’ academic performance.

2.2. Factors Affecting Doctoral Students’ Academic Performance

Previous studies have explored multiple factors affecting the academic achievement of doctoral students, and exposed the multifaceted nature of doctoral success [4,21,33,38]. According to Leijen and colleagues [38], the factors contributing to the progress of doctoral students can be categorized into three groups: personal characteristics, supervisory arrangements, and the wider learning community. As the nature of the doctoral study is an arduous process, individuals’ efforts, physical health, and psychological well-being were the premises of their success [7]. Castelló et al. [4] investigated the institutional and personal variables influencing the dropout of doctoral students. Besides the significance of support from supervisors, the family was proven as another important source of social support that positively affects doctoral students’ academic achievement. Support from family is more important in East Asian countries, whose students had high levels of family support [39]. Such support is more necessary for education Ph.D. students, as they may face greater difficulties in receiving funding than their peers in nature sciences [15]. In this study, we focused on several predictors found in previous research, including fear of delay, student engagement, parental support, teacher support, facilitating conditions, stress level, and well-being. These factors will be comprehensively explained in the following sections.

2.3. Fear of Delay

Fear is a basic human emotion that may cause negative consequences, for example, academic failure. It could also lead to stress, excessive anxiety, and other psychological or physical disorders [40]. According to previous studies, fear negatively influenced academic performance and was linked to poor performance during examinations [40,41,42]. However, other studies emphasized the positive effects of fear, such as motivating efforts and self-introspection [43]. In this case, fear as the feeling of being afraid of academic failure encouraged students’ effort to achieve goals. In this study, doctoral students in Indonesia were, generally required to complete their degrees within a maximum of 5 years, with scholarships guaranteed for no more than 4 years. Since most students were married, and some of them employed, they felt the duration was too short for fulfilling doctoral study. In this case, a delay in doctoral academic progress may bring detrimental effects on their career, finance, and family. Therefore, the fear of delay is supposed to significantly increase their stress levels, and, further, significantly impose a negative influence on their academic performance.

2.4. Student Engagement

Student engagement is the willingness to invest time, energy, and intellectual efforts in learning activities [44,45]. Student engagement can be divided into three categories, namely behavioral, emotional, and cognitive [46,47]. It was recognized as an important factor that catalyzes students’ efforts and further contributes to students’ learning and achievement across different educational levels [48,49,50]. Student engagement was also found to be related to their well-being [45,46,49,51]. In this study, student engagement is defined as the willingness of mathematics education doctoral students to engage in doctoral learning activities such as reviewing the literature, seeking research opportunities, collaborating with colleagues, developing research instruments, discussing with supervisors, conducting studies, and publishing results. This definition leads to the prediction that mathematics education doctoral students’ academic performance can be influenced directly by student engagement. In addition, higher engagement is predicted to reduce their stress levels.

2.5. Parental Support

In past studies, parental support was often proven to be positively associated with students’ academic achievement and was identified as an important factor in academic success [41,52]. Strong support from parents commonly has positive effects on motivation for learning, involvement in education [53], and student attitudes toward learning [54]. Such support can also be divided into two categories, namely, academic and emotional support.
Results from studies that focused on the effects of paternal support on students’ academic achievement were inconsistent. A recent meta-analysis study suggested that parental support has a significant positive effect on student achievement [55]. However, another study showed that over-supportive families in East Asian countries were not significantly associated with educational outcomes [56]. From this result, parental support did not always significantly influence learning progress. In this study, parental support is predicted to significantly reduce stress levels and increase the academic performance of mathematics education doctoral students.

2.6. Teacher Support

Support from parents and teachers are considered of equal importance in students’ learning [57]. Previous research suggested a positive relationship between teacher support and students’ academic performance at different educational levels [19,58]. This positive relationship was also found at the doctoral level, and the supervisor (or advisor) was proven to be critical in doctoral students’ mental health status and academic performance [2,18,20]. Considering the importance of collaboration skills in the 21st century, teacher support also motivates and facilitates doctoral students’ opportunities to become involved in the research community [59,60,61]. The opportunities for learning from leading scholars in the field can significantly improve the research ability of doctoral students. Indonesian teachers are always considered as an important source of knowledge for students when they encounter educational difficulties. In this study, teacher support is defined as the in-time assistance provided by supervisors and other institutional members to all mathematics education doctoral students. Therefore, teacher support is predicted to influence the academic performance and well-being of mathematics education doctoral students in a significantly positive way.

2.7. Facilitating Conditions

Facilitating conditions are conditions where mathematics education doctoral students pursue a degree and discuss research problems with their peers. In this case, the institution needs to provide necessary educational facilities, such as seminars and training, to improve the research abilities of doctoral students. It has been shown that facilitating conditions influenced individual behaviors [57,62,63], indicating the factor indirectly affected student academic achievement during a pandemic [64]. For our analysis, facilitating conditions are predicted to positively influence student well-being and effectively improve their academic performance.

2.8. Stress Level

Stress is a feeling of emotional or physical tension, and it is common among doctoral students who usually face numerous difficult tasks [44,65]. This factor was found to negatively influence the psychological health of students, and thus attracted several scholars to consider and assess its relationship to academic performance [66,67]. Interestingly, several analyses found that stress is rarely beneficial for individuals [41,68]. This is different from other studies, where stress was found to commonly motivated people to learn and improve their academic performance. It was also suggested that strategies to deal with stress are likely to become essential skills for future citizens. Therefore, this study predicted that stress level has a significant negative effect on the academic performance of mathematics education doctoral students. It is also predicted that parental support and student engagement are likely to reduce the stress level of doctoral students.

2.9. Well-Being

Students’ well-being affects various aspects of their academic performance, including learning abilities, engagement [69], achievement [49], and teamwork capability [70,71]. Besides relieving students’ mental problems, stress, and frustration, well-being could also inspire doctoral students’ innovative ideas for education research problems [72,73]. From this context, well-being is more defined as the capacity and resources to handle negative emotions, as well as being continuously active and efficient during learning.
Well-being has also been explored as another important indicator of doctoral education quality, except for academic performance [74]. It is believed that maintaining doctoral students’ well-being is an important responsibility for both institutions and supervisors [13,45]. Reducing stress levels and an increase in students’ engagement may increase students’ well-being [49]. On the one hand, overwhelming stress can cause mental health disorders and further affect students’ sleep quality and concentration at work, which can be detrimental to their well-being [41]. On the other hand, students’ increased engagement in the environment can enable productive interactions with peers and supervisors that will bring positive effects on their well-being [49]. Therefore, this factor is predicted to be influenced by facilitating conditions, teacher support, students’ stress level, and their engagement. It is also predicted to be significantly and positively associated with the academic performance of mathematics education doctoral students.
Based on the literature review, 14 initial hypotheses containing five independent variables, two intermediated variables, and one dependent variable are displayed in Table 1 and Figure 1.

3. Methodology

This study aims to investigate factors that would significantly affect the academic performance of mathematics education doctoral students in Indonesia and how these factors can work together to affect their academic performance. We identified fear of delay, student engagement, parental support, teacher support, facilitating conditions, stress level, and well-being as foci of this study. Based on the empirical model developed from a literature review, we collected data by a self-designed questionnaire. This questionnaire was answered by 147 Indonesian mathematics education doctoral students. We performed quantitative analyses of key elements that affect their academic performance in order to inform stakeholders on how to support doctoral students in their academic careers.

3.1. Instrument Development and Data Collection

To obtain more accurate data for our research, we designed an online questionnaire via Google Docs for distribution instead of using publicly available online data. The questionnaire was constructed using a 5-point Likert scale ranging from strongly disagree (1) to strongly agree (5). Additionally, all items in the questionnaire were adapted from previous similar research and modified to fit the context of this study. After the initial design of the questionnaire, and before the questionnaire was distributed to the participants, three experts were invited to review the questionnaire, and changes and refinements were made based on their feedback.
The final version of the questionnaire contained two sections. The first section consisted of the basic demographic information about the doctoral students, including gender, age, marital status, employment, and academic year. The second section focused on the seven pre-identified factors that might contribute to mathematics education students’ academic performance. There were 31 items that focused on the fear of delay, engagement, parental support, teacher support, facilitating conditions, stress level, well-being, and academic performance. These items were adapted from previous research, and the average time required to complete the questionnaire was found to be 9 min. The complete questionnaire with the original sources of items is shown in Appendix A.
Then, the questionnaire was formally distributed to the target group, Ph.D. students majoring in mathematics education, via email, WhatsApp groups, and university professors, in August, September, and October 2022. The validity and reliability of the questionnaires were tested to be good. Also, it was clarified that filling out the questionnaire was voluntary. Participants did not need to fill in their names so that the anonymity of the data could be maintained. The data obtained were analyzed only for the study purpose, without any disclosure. Table 2 showed the detailed demographic data of the participants.
After removing invalid responses, such as incomplete responses and abnormal speed of completing the questionnaire, the final sample consisted of 147 mathematics education doctoral students. A total of 59 (40.14%) participants were male and 88 (59.86%) were female, which is consistent with the result that there are more female Ph.D. students than male Ph.D. students, as indicated by world statistics. The 25–29-year-old students were the highest proportion of all the doctoral students collected, at 58.50%, while 27.89% were 20–24 years old, and 13.61% were 30 years old or older. In addition, the distribution of academic years to which these participants belonged was relatively even, with 15.65%, 27.89%, 35.37%, and 21.08% of students in their first, second, third, and fourth and higher years of doctoral study, respectively. Most of the students were married, at about 60%, while only a very small number of students had already been employed; about 80% of students had not worked yet. Since not many doctoral students were admitted yearly in Indonesia, a total of 147 was considered sufficient to explore the doctoral students majoring in mathematics education.

3.2. Data Analysis

We used SPSS 23 and SmartPLS4 to analyze the questionnaire data. Firstly, data cleaning and descriptive analysis were performed by SPSS 23. Then, we decided to use SmartPLS4 to carry out our partial least squares structural equation modeling (PLS-SEM) to study the effects of fear of delay, engagement, parental and teacher support, facilitating conditions, stress level, and well-being on the academic performance of doctoral students.
According to Hair et al., PLS-SEM is a causal-predictive approach to SEM, which overcomes the apparent dichotomy between explanation and prediction by emphasizing prediction in estimating statistical models and having structures designed to provide causal explanations [75]. It performs its estimating function of partial model structures by combining principal components analysis with ordinary least squares regression. Unlike other models that only consider common variance for estimation, PLS-SEM estimates parameters by the total variance, which is referred to as variance-based estimation. Additionally, since the PLS-SEM computes measurement and structural model relationships separately, it succeeds in providing solutions for small sample sizes when the model consists of many constructs and a large number of items. Meanwhile, it is also suitable for analyzing large data sets, including secondary data.
However, as with other multivariate methods, PLS-SEM cannot change sample quality to perform a valid model estimation [75]. Although PLS-SEM results may be affected by nonnormal data under a limited number of situations [76], the robustness of PLS-SEM shown in limited data sets tested as nonnormal contributes to the reason for using PLS-SEM. PLS-SEM also contains high statistical power, which increases the possibility to identify relationships as significant when they are indeed present in the population. Moreover, it has some user-friendly software packages that can be directly and easily used in software environments such as R. Additionally, the evaluation of PLS-SEM results starts with the examination of the measurement models, and the relevant criteria can vary according to the construct type—reflective or formative—and once the measurement models meet all the criteria, the next step is to assess the structural model. The rules of thumb that serve as guidelines to evaluate PLS-SEM results vary depending on the context. For example, the minimum reliability for exploratory research is 0.60 while the minimum reliability for research is 0.70. Finally, the researchers have to run one or more robustness checks, depending on the research context, to support the stability of the results.
The PLS-SEM approach is more suitable for predicting and building new empirical models [77]. It was also verified as valid for analyzing and identifying factors on the academic performance of doctoral students and explaining theoretical constructs in complex models [78,79], which are aligned with our research questions. Therefore, we decided to use SmartPLS4 to carry out our partial least squares structural equation modeling (PLS-SEM) to study the effects of fear of delay, student engagement, parental support, teacher support, facilitating conditions, stress level, and well-being on the academic performance of mathematics education doctoral students.
In the specific use of PLS-SEM for this study, we performed two steps. For the first step, we focused on the analysis of the measurement model [75], which was conducted to confirm the reliability and validity of the model, mainly based on CR (composite reliability) and Cronbach alpha values, as well as the estimation of outer loadings and AVE. Then, Fornell–Larcker [80] and HTMT values were assessed for discriminant validity. For the second step, the structural model was evaluated to test the initial hypotheses and draw conclusions. In this case, a bootstrap method with 5000 subsamples was used in the SmartPLS4 to calculate path coefficients, t-values, and p-values.

4. Results

After analyzing the descriptive statistics and applying the measurement model, our results showed that the academic performance of mathematics education doctoral students was directly affected by student engagement, teacher support, and well-being. The results also showed that the fear of delay can largely increase students’ stress levels, while parental support can significantly decrease their stress levels. Additionally, student engagement, teacher support, and facilitating conditions significantly increased the well-being of doctoral students. However, high levels of stress significantly decreased students’ well-being. Furthermore, the structural model analysis and preliminary hypothesis testing were conducted to determine the factors significantly affecting the academic performance of mathematics education doctoral students in Indonesia.

Analysis Measurement Model

After examining the indicator loadings, assessing internal consistency reliability, and the convergent validity of each construct measure, the results show that all the indicator loading values were higher than 0.708, except AP1 (0. 651) and AP4 (0.694), and the lowest average variance extracted (AVE) value was 0.556, which is higher than 0.50. Hence, according to Hair et al. [75], the outcome indicates that the construct explains more than 50% of the indicator’s variance and thus can prove acceptable reliability and convergent validity. Besides, the Composite Reliability and Cronbach’s Alpha estimations exceeded the 0.60 limits [75]. Detailed results of outer loadings, reliability, and convergent validity are provided in Table 3.
Then, we assessed the discriminant validity by observing the Fornell–Larcker value [80] and calculating the heterotrait–monotrait ratio (HTMT) of correlations, which is the mean value of the item correlations across constructs relative to the (geometric) mean of the average correlations for the items measuring the same construct, and both results showed that the data we used were good enough to pass the discriminant validity testing. For Fornell–Larcker, Table 4 shows the correlation matrix with AVE values, where all bold representations are higher than the squared estimates of the corresponding variables, which means the data passes the discriminant validity testing. For the HTMT, Table 5 shows that the highest HTMT value was 0.864, which indicates that all values are below 0.90, and according to Hair et al. [75], the discriminant validity is ensured and can be declared to be good.
After the satisfaction of the measurement model assessment, we then evaluated the structural model, and here we conducted the examination of collinearity, R2 value, and significance of path coefficients. A significance level of 0.05 was also used with subsamples of 5000, according to the development and recommendation of Hair et al. [75].
Based on the collinearity test, the VIF value was analyzed, with Table 6 showing that all the estimations were not higher than 5. This proved that a multicollinearity problem was not found in the PLS-SEM approach.
Regarding the results, the R2 values of academic performance, stress level, and well-being were 0.651, 0.298, and 0.592, respectively (Figure 2). This indicated that more than 65% power was observed and used to explain the factors significantly affecting the academic performance of mathematics education doctoral students, and we can say that it is sufficient to explain the variance within the academic performance of mathematics education doctoral students, as the estimation of the values is higher than 0.1.
Based on Table 7, 9 of the 14 hypotheses were supported. This proved that fear of delay and parental support significantly affected stress levels. Meanwhile, student engagement did not significantly reduce these levels. From the results, student engagement, teacher support, and facilitating conditions significantly influenced the well-being of mathematics education doctoral students. Student engagement, teacher support, and well-being also significantly affected academic performance. The final model with R2, path coefficients, and p values is shown in Figure 2.
According to these results, student engagement and parental support were the biggest factors significantly influencing well-being and reducing stress levels, respectively. Meanwhile, teacher support was the biggest factor significantly improving the academic performance of mathematics education doctoral students.
Based on these results, fear of delay, parental support, facilitating conditions, and stress level did not directly affect the academic performance of mathematics education doctoral students. This was different from several previous studies, where parental support, stress level, and facilitating conditions significantly and directly influenced individuals. In addition, student engagement, teacher support, and stress level significantly and indirectly affected mathematics education doctoral students’ academic performance (Table 8).

5. Discussion

This study is intended to explore the factors that can affect the academic performance of mathematics education doctoral students in Indonesia. We first identified several individual and environmental factors from a literature review, including fear of delay [16], student engagement [22,26], parental support [21,74], teacher support [2,7], and facilitating conditions [38,81]. Then we built a theoretical model of influential factors on doctoral students’ academic performance. The PLS-SEM approach was used to analyze questionnaire data from 147 mathematics education doctoral students and test the theoretical model with hypotheses. Despite the theoretical model being literature-based, our study has suggested findings that are either consistent or inconsistent with past empirical evidence.
Our study suggested that fear of delay could increase mathematics education doctoral students’ stress levels, but could not significantly improve their academic performance. This result is inconsistent with previous studies that revealed the capability of fear of failure and stress in motivating people toward the best goal achievement [42,82]. According to Daniel [83], students’ anxiety increased when fear was experienced, and the increased level of anxiety often motivated individuals toward better performance. However, students often had difficulties concentrating and achieving their best performance when excessive fear and high levels of stress were experienced. This was in line with many previous studies, where people performed better when not under excessive stress and fear [40,41,42]. As doctoral students are always facing a great fear of failure to obtain a doctoral degree, more negative feelings such as fear and stress cannot improve and increase their performance and learning interest. In this case, doctoral students were more able to produce excellent performance when they felt less stressed and learned in a supportive environment. Indonesian mathematics education doctoral students tend to attach great importance to their learning and their high stress levels can impede their achieving maximum learning outcomes. Despite these conditions, supervisors and faculties in Indonesia tend to scare students with the word, “drop out”, as a stimulus to encourage them to complete their studies and achieve their best performance. Results of this study suggested that increasing students’ fear and stress were ineffective and inappropriate to improve the academic performance of doctoral students. The results also suggested that universities should care for the mental well-being of the students, as overwhelming negative feelings such as fear and stress are common in pursuing a doctoral degree. Subsequently, Indonesian doctoral supervisors need to encourage doctoral students in their learning and convince them that the doctoral program can best prepare them for their future.
It is highlighted that student engagement directly and positively affected the academic performance of mathematics education doctoral students. The higher the level of engagement, the better they conceived their achievement in academia. This was in line with previous studies that showed that students, with more enthusiasm for inputting their time and energy into their education, tend to achieve better academic performance [47,84,85]. From this context, institutions and supervisors should endeavor to motivate the engagement of doctoral students majoring in mathematics education. In addition, the statistical results showed that the level of student engagement was capable of significantly increasing their well-being, and indirectly increasing their academic performance, of students pursuing a doctoral degree. This is probably because a strong engagement in academic activities would enable their active involvement and quicken their progress in the doctoral program, which could make them feel more joyful and fulfilled. The results were supported by previous theories, where engagement had a relationship with one’s level of well-being [45,46,49,51] although did not directly reduce stress.
Despite the substantial evidence for the importance of parental support for doctoral students [9,19,86], our study did not find similar evidence among those students majoring in mathematics education. However, parental support was proven to be the most significant factor in reducing their stress levels. According to the mathematics education doctoral students in Indonesia, emotional support from parents was only likely to reduce stress levels when they encountered problems in learning. This is aligned with the Asian culture, where children are always eager for positive feedback from their parents on their achievements [87]. Our study also found that reducing stress levels can increase the well-being of mathematics education doctoral students. In addition, a high level of well-being will increase the academic performance of mathematics education doctoral students. However, compared with parental support, other individual factors such as engagement, internal motivation, and well-being were more important in achieving academic performance when pursuing a doctoral degree. Although parental support did not significantly improve the academic performance of these students, the connection with parents was still important in reducing their stress levels and motivating their learning [53]. This improvement indirectly facilitates them to achieve the best performance while pursuing a doctoral program.
The significant positive effect of support from advisors and faculties on academic performance suggested by past studies was echoed in our study on mathematics education doctoral students. Past research has emphasized the role of the supervisor (or advisor) in doctoral students’ development as a researcher [2,20], as well as how faculty motivated them differently according to doctoral students’ needs [17,88]. The student–supervisor relationship becomes more critical in students’ success in doctoral programs because most Indonesians believe that supervisors are often able to determine students’ success at the institutional level. They also believe that the faculty members are influential academically and emotionally. Furthermore, Indonesian students usually consider their teachers (or supervisors at the doctoral level) as the only people who can provide advice and support when they meet difficulties during doctoral study. In this case, students could mostly become emotionally satisfied, gain valuable experience, and develop academically when their supervisors maximally support them. Several previous studies indicated that other faculty members’ support was another main key to learning success [57,89,90]. In this context, universities need to provide training for supervisors and other teaching staff regarding how to effectively support doctoral students’ studies and emotions. In addition, it was suggested that the supervisors could encourage doctoral students to collaborate during research projects and that the improvement of their cooperation skills significantly affected their academic performance. The ability to collaborate is an important skill in the 21st century [91,92,93]. A successful cooperative research project is likely to lead to better academic outputs [94,95]. These results emphasized the maintenance of communication and collaboration among students and the faculty. This should also be accompanied by listening to the problems of the students and releasing their mental problems to improve their academic achievement.
Facilitating conditions, namely the institutional environment where mathematics education doctoral students conduct research, did not directly affect their academic performance. This was due to the common inadequacy of these conditions in improving educational skills and efficiency in the local universities. In this case, the students were unable to effectively use existing facilities, collaborate, discuss with supervisors, or participate in seminars and training. However, the mathematics education doctoral students in Indonesia believed that facilitating conditions increased their level of well-being. This is also verified in other studies that show that facilitating conditions can also be a strong positive factor in increasing the well-being of doctoral students [49,96]. Furthermore, institutions with advanced facilitating conditions would receive more funding resources, which are important to students’ academic progress. Moreover, each supervisor is supposed to determine the forms of assistance, facilities, and support according to the current doctoral students [97].

6. Conclusions

By using the PLS-SEM approach, this study revealed that the academic performance of mathematics education doctoral students was affected by individual, parental, and institutional factors in a complex mechanism. In this study, an empirical model was developed to predict the significant factors affecting the academic performance of mathematics education doctoral students in Indonesia. Examination of the results of the empirical model led to the verification of student engagement, teacher support, and well-being as the significant variables directly influencing the academic performance of these students. Student engagement, teacher support, and stress level also significantly affected their academic performance in an indirect way. Therefore, the results obtained contributed to the present understanding of doctoral students’ academic performance. In this case, each factor and the relationship between these factors should be further evaluated and demonstrated in other contexts. The results also provided important implications to parents, lecturers, doctoral supervisors, and policymakers regarding the improvement of doctoral education quality.

7. Overall Contributions

7.1. Theoretical Implications

This study was inspired by several limitations of the previous studies on factors significantly affecting the academic performance of doctoral students: (1) an oversimplified conceptualization of doctoral students’ academic performance; (2) limited knowledge of how different factors can contribute to doctoral students’ academic performance together; (3) little attention to doctoral students in developing countries and who major in a specific specialization field in education. Therefore, several theoretical contributions are provided to research students’ academic performance at the higher education level.
Firstly, we developed an empirical model capable of explaining how individual, institutional, and parental factors can affect doctoral students’ academic success. This model distinguished that five independent factors (namely, fear of delay, student engagement, parental support, teacher support, and facilitating condition) can significantly influence two intermediated factors (namely stress level and well-being), and further influence the academic performance of mathematics education doctoral students. The results obtained can enlighten how to improve students’ academic performance in doctoral programs, especially in the major of mathematics education. This output is capable of filling the research gap in the previous analysis of doctoral students’ performance, where factors were examined separately [65,98].
Secondly, a new technique, namely the PLS-SEM approach, was proven valid to predict doctoral students’ academic performance. This was different from previous studies, where educational achievement was mostly investigated through the pretest-posttest paradigm and CB-SEM approach, or at the K-12 level.
Thirdly, this study contributes to the limited evidence of the factors affecting the academic performance of doctoral students in developing countries, namely Indonesia. In this specific educational and cultural context, student engagement, teacher support, and well-being are the main factors directly influencing doctoral students’ academic achievement.

7.2. Practical Implications

Based on the results, practical implications are provided to institutions, supervisors, and parents regarding the improvement of doctoral students’ academic performance. The results show that the success of doctoral students is inseparable from the role of parents, lecturers, and student’s level of engagement. Therefore, collaboration is needed among these motivators, to reduce stress levels, improve well-being, and support doctoral students’ academic achievement. The campus should develop enhancement programs for the well-being of doctoral students, leading to the mindset that the acquisition of a doctoral degree is the appropriate step. For faculty in the institution and doctoral students’ supervisors, many suggestions regarding the improvement of students’ well-being and engagement were provided, including the following: (1) checking students’ mental health status regularly, (2) maintaining enthusiasm for learning but with regular breaks, (3) improving connections and mutual support among doctoral students, (4) providing sufficient resources and in-time support to doctoral students in their academic journey, and (5) improving the curriculum, and training according to students’ needs.
From the results, parental support reduced the stress level of doctoral students. This is very important information for parents, whose assistance is critical to reduce the stress of doctoral students, even though most of them are over 25 years old and married. For parents of doctoral students, it is of great importance to understand the students’ situations and provide emotional support for them to continue their academic career. Faculty members and supervisors also need more adequate knowledge of the family background of each student, and to cooperate with their family to support the doctoral student.

8. Limitations and Future Directions

The limitations of this study lie in the following aspects. Firstly, the conclusions are based on a voluntary sample of mathematics education doctoral students in Indonesia. This limited sample leads to limited generalizability of conclusions in other higher education systems in other countries. Secondly, the study solely concentrated on the factors at the individual, institutional, and parental levels, implying the need for subsequent investigation of more variables, such as support from friends or wider learning communities. For instance, Grevholm et al. [99] studied a group of doctoral students, supervisors, scholars from other universities, and policymakers, indicating the effectiveness of interactions among them in improving students’ achievement. A more detailed analysis of factors at each different level is worthwhile by studying successful cases of doctoral education in mathematics education around the world. Thirdly, a quantitative paradigm has dominated the analysis. This leads to the need for rich qualitative knowledge of the nuanced mechanisms by which these factors can contribute to the academic progress of mathematics education doctoral students.

Author Contributions

Conceptualization, T.T.W., B.Y. and M.M.; methodology, M.M. and F.X.; software, Z.Y.; validation, Z.Y., B.Y. and F.X.; formal analysis, Z.Y. and T.T.W.; investigation, M.M. and B.Y.; resources, F.X.; data curation, M.M. and Z.Y.; writing—original draft preparation, T.T.W., B.Y. and F.X.; writing—review and editing, All authors.; visualization, F.X.; supervision, M.M. and Z.Y.; project administration, T.T.W. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

The data in this study can be provided upon request by sending an e-mail to the corresponding author.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Table A1. Measurement items in the questionnaire.
Table A1. Measurement items in the questionnaire.
ConstructsCodeIndonesian VersionEnglish VersionReferences
Fear of delayFOD1Saya takut saya tidak dapat lulus tepat waktu 3 tahunI’m afraid I can’t graduate in 3 years
FOD2Saya takut saya tidak dapat menyelesaikan doctoral saya sampai 7 tahun yang menyebabkan saya harus drop outI’m afraid that I won’t be able to finish my doctoral education until 7 years which will cause me to drop out
Student engagementSE1Saya sangat focus pada Pendidikan doctoral sayaI am very focused on my doctoral education[100]
SE2Saya pikir saya sudah melakukan yang terbaik during belajar doctoral saat iniI think I did my best during my doctoral education
SE3Saya tidak mempunyai planning untuk drop out dari doctoral sayaI have no plans to drop out of my doctoral education
SE4Overall saya menikmati kuliah doctoral saya saat iniOverall I am enjoying my current doctoral course
Parental supportPS1Orang tua saya memenuhi kebutuhan materi doctoral sayaMy parents provide for my doctoral material needs[19]
PS2orang tua saya selalu mensupport saya secara emosional saat saya menempuh doctoralMy parents have always supported me emotionally while pursuing my doctoral education
PS3Overall, orang tua saya mendorong saya untuk meraih pencapaian tertinggi saat saya doctoralOverall, my parents encouraged me to achieve the highest achievement during my doctoral education
Teacher supportTS1Dosen kami menginginkan seluruh mahasiswa respek terhadap ide orang lainOur lecturers want all students to respect other people’s ideas[41,101]
TS2Dosen kami adil terhadap seluruh mahasiswaOur lecturers are fair to all students
TS3Dosen kami mendorong mahasiswa bekerjasamaOur lecturers encourage students to work together
TS4Dosen kami mengerti perasaan dan situasi setiap mahasiswaOur lecturers understand the feelings and situations of each student
TS5Dosen kami mensupport setiap ide dan keputusan kamiOur lecturers support our every idea and decision
Facilitating conditionsFC1Saya mempunyai kondisi yang memungkinkan untuk menempuh doctoralI have the conditions necessary to pursue a doctorate[102]
FC2Ketika saya mempunyai kesulitan saat menempuh doctoral saya tahu harus mencari siapaWhen I have difficulties while pursuing my doctorate, I know who to look for
FC3Kampus mempunyai banyak pelatihan dan seminar untuk meningkatkan academic performance mahasiswaThe campus has a lot of training and seminars to improve student academic performance
Stress LevelSL1Tugas dan tanggung jawab doctoral membuat saya Lelah secara mosionalDoctoral duties and responsibilities make me emotionally depressed[103]
SL2Saya merasa kelelahan sepanjang saya menempuh doctoral sayaI felt exhausted throughout my doctoral education
SL3Pendidikan doctoral membuat saya stressDoctoral education makes me stressed
SL4Saya kehilangan antusias belajar saya saat sudah menempuh doctoralI lost my enthusiasm for learning when I took my doctorate
SL5Saya mempunyai pemikiran untuk drop out dari doctoral sayaI have thoughts of doctoral education dropping out
Well-beingWB1Doctoral membuat saya mempunyai relasi yang luasDoctorate made me have wide relations[104]
WB2DOCTORAL membuat saya dapat memiliki banyak pengalaman dan skill baruDoctorate allows me to have a lot of new experiences and skills
WB3Secara keseluruhan, saya merasa percaya diri dan positif saat saya menempuh doctoralOverall, I feel confident and positive while pursuing my doctoral degree
WB4Saya enjoy merencanakan pengetahuan apa yang akan saya pelajari saat doctoral dan bagaimana cara mewujudkannyaI enjoy planning what knowledge to learn during my doctorate and how to make it happen
Academic performanceAP1Saya mendapatkan nilai yang memuaskan untuk setiap mata kuliah selama doctoralI got satisfactory grades for every course during my doctoral degree[105]
AP2Tidak sedikit ilmu yang saya dapatkan untuk masa depan saya saat saya menempuh doctoralI got a lot of knowledge for my future while studying for my doctoral degree
AP3Kemampuan saya dalam menulis paper meningkat selama doctoralMy ability to write papers increased during my doctorate
AP4Kemampuan saya untuk melakukan presentasi di conference nasional atau international meningkat selama saya menempuh Pendidikan doctoralMy ability to make presentations at national or international conferences increased during my doctoral education
AP5Saya merasa kemampuan berpikir kritis saya meningkat saat saya menempuh doctoralI feel that my critical thinking skills have increased while pursuing my doctoral degree

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Figure 1. A proposed model for exploring factors affecting mathematics education doctoral students’ academic performance.
Figure 1. A proposed model for exploring factors affecting mathematics education doctoral students’ academic performance.
Ijerph 20 04518 g001
Figure 2. Structural model evaluation results with R2, path coefficients, and p values.
Figure 2. Structural model evaluation results with R2, path coefficients, and p values.
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Table 1. Hypotheses in this study.
Table 1. Hypotheses in this study.
CodeHypothesis
H1Fear of delay positively influences doctoral students’ stress level.
H2Fear of delay negatively affects doctoral students’ academic performance.
H3Student engagement negatively impacts the stress level of doctoral students.
H4Student engagement positively influences doctoral students’ well-being.
H5Student engagement positively influences doctoral students’ academic performance.
H6Parental support negatively affects doctoral students’ stress level.
H7Parental support positively impacts doctoral students’ academic performance.
H8Teacher support positively influences doctoral students’ well-being.
H9Teacher support positively affects doctoral students’ academic performance.
H10Facilitating conditions positively impact doctoral students’ well-being.
H11Facilitating conditions positively influence doctoral students’ academic performance.
H12Stress level negatively affects doctoral students’ academic performance.
H13Stress level negatively affects doctoral students’ well-being.
H14Well-being positively impacts doctoral students’ academic performance.
Table 2. Demographic information of participants.
Table 2. Demographic information of participants.
Demographics NPercentage
GenderMale5940.14%
Female8859.86%
Age20–24 years old4127.89%
25–29 years old8658.50%
30 years old and above2013.61%
Academic yearFirst2315.65%
Second4127.89%
Third5235.37%
Fourth year above3121.08%
Marital statusMarried9161.90%
Not yet Married5638.10%
Job statusNot Yet Working11980.95%
Already Working2819.05%
Table 3. Outer loadings, reliability, and convergent validity.
Table 3. Outer loadings, reliability, and convergent validity.
ConstructsIndicatorOuter LoadingsCronbach’s AlphaComposite ReliabilityAverage Variance Extracted (AVE)
Fear of
Delay
FOD1: Delay in graduation0.8810.7270.7280.786
FOD2: Dropout after the delay0.892
Student
Engagement
SE1: Focus on learning0.8460.7860.7910.699
SE2: Efforts in learning0.841
SE3: Retention in learning0.821
Parental
Support
PS2: Emotional support0.9690.9320.9330.936
PS3: Motivational support0.966
Teacher
Support
TS1: Respect for other people’s ideas0.8180.8770.8860.669
TS2: Fairness to students0.797
TS3: Encouraging collaborations0.868
TS4: Emotional support0.809
TS5: Support for student decisions0.796
Facilitating ConditionsFC1: Necessary conditions0.7470.6000.6000.556
FC2: Helpful people0.765
FC3: Training and seminars0.724
Stress LevelSL1: Emotional depression0.7220.8400.8610.600
SL2: Exhausted feelings0.778
SL3: Stressful feelings0.801
SL4: Lost enthusiasm0.804
SL5: Thoughts about dropout0.765
Well-beingWB1: Wide connections0.8080.8540.8590.695
WB2: New experiences and skills0.819
WB3: Confident feelings0.873
WB4: Enjoyable learning0.834
Academic PerformanceAP1: Course grades0.6510.8110.8230.571
AP2: Career plan0.817
AP3: Paper writing0.81
AP4: Research presentation0.694
AP5: Critical thinking0.792
Table 4. Results of the Fornell–Larcker test for assessing discriminant validity.
Table 4. Results of the Fornell–Larcker test for assessing discriminant validity.
Academic PerformanceFacilitating ConditionsFear of DelayParental SupportStress LevelStudent EngagementTeacher SupportWell−Being
Academic Performance0.756
Facilitating Conditions0.5240.746
Fear of Delay−0.148−0.2340.886
Parental Support0.3080.309−0.250.968
Stress Level−0.269−0.2720.501−0.2780.775
Student Engagement0.6590.599−0.1580.289−0.260.836
Teacher Support0.6870.522−0.0750.424−0.2160.5180.818
Well−being0.7110.611−0.150.326−0.3680.6830.5830.834
Table 5. Results of the HTMT test for assessing discriminant validity.
Table 5. Results of the HTMT test for assessing discriminant validity.
Academic PerformanceFacilitating ConditionsFear of DelayParental SupportStress LevelStudent EngagementTeacher SupportWell-Being
Academic Performance
Facilitating Conditions0.738
Fear of Delay0.2040.358
Parental Support0.3470.4160.304
Stress Level0.2960.3910.6420.322
Student Engagement0.8090.8640.2070.3240.27
Teacher Support0.7980.7290.1280.4680.2390.619
Well-being0.8280.8340.180.3620.3920.8190.668
Table 6. Variance inflation factor value for all constructs.
Table 6. Variance inflation factor value for all constructs.
Academic PerformanceFacilitating ConditionsFear of DelayParental SupportStress LevelStudent EngagementTeacher SupportWell-Being
Academic Performance
Facilitating Conditions1.914 1.753
Fear of Delay1.421 1.076
Parental Support1.316 1.145
Stress Level1.528 1.101
Student Engagement2.121 1.1 1.733
Teacher Support1.818 1.517
Well-being2.481
Table 7. Results of the initial hypothesis test.
Table 7. Results of the initial hypothesis test.
RelationshipsPath Coefficients(β)Sample MeanStandard DeviationT-Statisticsp-ValuesResult
H1: Fear of Delay −> Stress Level0.4460.4510.0637.0670Supported
H2: Fear of Delay −> Academic Performance−0.051−0.0530.0640.8030.422Not Supported
H3: Student Engagement −> Stress Level−0.154−0.1590.0811.9130.056Not Supported
H4: Student Engagement −> Well−being0.3960.390.0964.1380Supported
H5: Student Engagement −> Academic Performance0.2490.2420.0713.5160Supported
H6: Parental Support −> Stress Level−0.122−0.1220.0592.0580.04Supported
H7: Parental Support −> Academic Performance−0.04−0.0430.0750.5370.592Not Supported
H8: Teacher Support −> Well−being0.2350.2390.0733.2280.001Supported
H9: Teacher Support −> Academic Performance0.3920.3960.0745.3350Supported
H10: Facilitating Conditions −> Well−being0.2080.2120.0972.1410.032Supported
H11: Facilitating Conditions −> Academic Performance−0.036−0.0320.0730.4990.617Not Supported
H12: Stress Level −> Academic Performance0.0110.0120.0660.1690.866Not Supported
H13: Stress Level −> Well−being−0.157−0.1590.0542.9390.003Supported
H14: Well−being −> Academic Performance0.3440.3450.0794.3370Supported
Table 8. Results of indirect effect analysis.
Table 8. Results of indirect effect analysis.
RelationshipsPath Coefficients (β)Sample MeanStandard DeviationT-Statisticsp-ValuesResult
Student Engagement −> Stress Level −> Academic Performance−0.002−0.0020.0120.1470.883Not Supported
Fear of Delay −> Stress Level −> Academic Performance0.0050.0060.0310.1630.871Not Supported
Student Engagement −> Stress Level −> Well−being0.0240.0250.0161.5430.123Not Supported
Student Engagement −> Stress Level −> Well−being −> Academic Performance0.0080.0080.0061.50.134Not Supported
Student Engagement −> Well−being −> Academic Performance0.1360.1360.052.7040.007Supported
Parental Support −> Stress Level −> Well−being −> Academic Performance0.0070.0070.0041.610.107Not Supported
Parental Support −> Stress Level −> Academic Performance−0.00100.0090.1550.877Not Supported
Teacher Support −> Well−being −> Academic Performance0.0810.0810.0292.8240.005Supported
Stress Level −> Well−being −> Academic Performance−0.054−0.0550.0222.430.015Supported
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Wijaya, T.T.; Yu, B.; Xu, F.; Yuan, Z.; Mailizar, M. Analysis of Factors Affecting Academic Performance of Mathematics Education Doctoral Students: A Structural Equation Modeling Approach. Int. J. Environ. Res. Public Health 2023, 20, 4518. https://doi.org/10.3390/ijerph20054518

AMA Style

Wijaya TT, Yu B, Xu F, Yuan Z, Mailizar M. Analysis of Factors Affecting Academic Performance of Mathematics Education Doctoral Students: A Structural Equation Modeling Approach. International Journal of Environmental Research and Public Health. 2023; 20(5):4518. https://doi.org/10.3390/ijerph20054518

Chicago/Turabian Style

Wijaya, Tommy Tanu, Boran Yu, Fei Xu, Zhiqiang Yuan, and Mailizar Mailizar. 2023. "Analysis of Factors Affecting Academic Performance of Mathematics Education Doctoral Students: A Structural Equation Modeling Approach" International Journal of Environmental Research and Public Health 20, no. 5: 4518. https://doi.org/10.3390/ijerph20054518

APA Style

Wijaya, T. T., Yu, B., Xu, F., Yuan, Z., & Mailizar, M. (2023). Analysis of Factors Affecting Academic Performance of Mathematics Education Doctoral Students: A Structural Equation Modeling Approach. International Journal of Environmental Research and Public Health, 20(5), 4518. https://doi.org/10.3390/ijerph20054518

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