1. Introduction

Interest in a subject matter can increase the likelihood of educational success. Interest is often described as two different experiences: (1) a momentary experience of being captivated by an object or topic (situational interest), and (2) an enduring inclination to reengage with an object or topic over time (individual interest) [1]. Individual student interests in education are often shared with societal, institutional, and instructional interests (Figure 1) [2]. Students need to take required courses, which are often outside their specific interests. Although instructors may presume that students do not have any interests in required courses, research by Mikhailova et al. (2019) [2] showed that this is not always true. Connecting student interests with a learning context in a required course is particularly challenging and requires knowledge of prior student interests associated with the required course. Mikhailova et al. (2019) [2] examined the role of prior student interests in creating various interest interventions such as attention-getting settings, context personalization, project-based learning, utility value, and technology-based learning (Figure 1).

Traditional interest research includes three approaches: (1) characteristics of the person (personal interest as a disposition), (2) characteristics of the learning environment, context, and situation (the interestingness of the learning environment), and (3) psychological state within the person (situational and actualized interests within the person) (Figure 2) [4,5]. The original concepts [4] only included personal interest as a disposition that ignores, or at least does not differentiate, prior interest gained from earlier education and life experience. Experience and disposition are different concepts, where disposition is associated with the inherent qualities of the individual, while experience, including educational experience, is linked to prior events in a student’s life. Some researchers link the dispositional characteristics of the person to the learning environment, while others ignore this relationship [4,5].

Although several studies have examined the theory and practice of increasing student interest in a topic [3,6], there has been limited discussion of the interests that students bring to a course and how that could be used to improve student engagement with a particular subject. While the subject matter for a STEM exercise is often derived from a series of societal, institutional, and instructional interests (Figure 1), it is possible to evaluate prior students’ interests related to an assigned subject matter to help improve and customize how the subject is organized and delivered as an exercise.

This study examines methods to connect students’ prior interests to a learning context (Figure 2) in a required soil science course by expanding the scope of the already existing laboratory exercise on soil reaction (pH) with the concept of soil inorganic carbon (SIC) and ecosystem goods and services/disservices (Table 1). This modified exercise is developed to expand the relevance of the laboratory by improving the meaning and characteristics of the learning environment by linking to students’ prior interests.

Soil reaction (pH) is a measure of hydrogen ion (H⁺) concentration/activity in soil solution, which is related to the acidity or alkalinity of a soil. The presence of SIC (naturally occurring liming material) makes the soil more alkaline. Measurement techniques for soil pH are analogous to other pH measurement exercises that most students are exposed to multiple times in their secondary and early college education. Despite these previous experiences in measuring pH in a more general context, soil pH is a vital concept in an introductory soil science course because it relates to soil nutrient availability and other key concepts. It is a challenge for instructors to make a previously experienced subject matter on pH relevant and interesting. Ecosystem services/disservices provide an example of how to expand the learning context of a subject, in this case, soil pH, by providing a biophysical as well as a new socio-economic context. Ecosystem services are defined as benefits provided by ecosystems to humans, which are opposite to ecosystem disservices. Ecosystem services are divided into three categories: provisioning (e.g., food), regulation/maintenance (e.g., carbon sequestration), and cultural (e.g., recreation).

The objectives of this study were to evaluate prior students’ soil science-related interests and use them to expand the learning context of a laboratory exercise on soil pH with SIC, and ES/ED in an online introductory soil science course (FNR 2040: Soil Information Systems) taught at Clemson University. The topics of soil reaction (pH), SIC, and ES/ED fit well with soil science course objectives, included in lectures and laboratory exercises.

2. Materials and Methods

2.1. Design

Prior to the beginning of the course, students were asked to complete a survey that included questions about education, demographics, familiarity with ecosystem services, geospatial technologies, and an open-ended question about soil science interests. Data from this survey were used to classify students’ interests which were used to develop the laboratory exercise. The laboratory exercise consisted of a series of reusable learning objects (RLOs) in the Canvas Learning Management System (Instructure) (Table 2). The laboratory exercise consisted of identifying ES/ED provided by soil pH, calculating the avoided social cost of carbon (SC-CO₂), and liming replacement costs from soil inorganic carbon (SIC) stocks in one of the horizons of the assigned soil. The experimental design of the study is presented in Table 2, Table 3 and Table 4. Table 3 and Table 4 show instructions provided to the students for the laboratory exercise.

2.2. Background of “Test” Course

“Test” course: Soil Information Systems (FNR 2040) is a 4-credit course in the Department of Forestry and Environmental Conservation at Clemson University, Clemson SC [14]. FNR 2040 is “an introductory soil course that focuses on the input, analysis, and output of soil information utilizing geographic information technologies (Global Positioning Systems, Geographic Information Systems, direct/remote sensing) and soil data systems (soil surveys, laboratory data, and soil data storage). Soil Information Systems course is a required course for forestry, wildlife and fisheries biology, and environmental and natural resources majors” [14]. The course was taught online because of COVID-19. General information about the course based on the survey is presented in Table 5.

3. Results

3.1. Pre-Testing Student Interests in Soil Science and Ecosystem Services

Knowledge of student interests in a subject matter is essential in creating effective laboratory exercises. This study assessed students’ interests in soil science and ES using an online questionnaire/survey at the beginning of the course/semester. Information about students’ interests in soil science was acquired using an open-ended request: “Please, write a short paragraph about your interests in soil science using space below.” Students’ responses were classified based on interest types, which showed that most students had personal interest and utility value in soil science (Figure 3).

Student interests were also classified based on the phases of interest development, with most of the students having triggered situational interest (“the subject is new”) (51%) and maintained situational interest (“the subject is somewhat new”) (38%) (Figure 4).

Students’ familiarity with ES was tested using a question: Are you familiar with the concept of ES with an option to elaborate: “If yes, please, describe how you learned about it.” Familiarity with the concept of ES had a wide distribution with most of the students being “not at all familiar” with ES (Table 6).

Student interests were also classified based on their interests in ES, with most students expressing a general interest in ecosystems, and provisioning ES in particular, which can be explained by students’ majors (forestry; wildlife biology), which tend to be focused on provisioning ES (Table 7).

Table 8 presents pre-testing responses to the survey questions about familiarity with ES/ED, which reveal that most students were “not familiar” (32.8%) and “slightly familiar” (24.1%) with this concept (Table 8). Students were familiar with pH, with most students learning about pH in high school and college (Table 8). More than half of the students measured pH more than four times in the past (Table 8). Most of the students were “not at all familiar” (33.3%) and “slightly familiar” (42.1%) with SIC (Table 8). More than 90% of students were not familiar with the relationship between SIC and pH (Table 8).

3.2. Expanding the Learning Context of a Laboratory Exercise Based on Student Interests

Traditionally, soil science pH laboratories have focused on physically measuring pH, which most students in this course had learned and experienced in both high school and college before taking this soil science course (Table 8). The student survey of general interest in soil science and ES/ED showed that student soil science interests fall in the category of personal interest and utility value, with ES-related interests revolving around provisioning ES (Figure 5). Based on these results, it was concluded that problem-based learning and utility value interest interventions were the most appropriate in this case. Student interests in provisioning ES helped to focus the topic on soil pH and SIC (CaCO₃), which is a naturally occurring liming material listed in the table of soil chemical properties. The new assignment included a laboratory exercise using the SIC values (or a default value when not present) to identify the related ES/ED, calculate the avoided social cost of carbon (SC-CO₂), and liming replacement costs from soil inorganic carbon (SIC) stocks in one of the horizons for each student’s unique soil which is part of their semester-long State/Representative Soil Project. This exercise linked students’ prior personal and utility value interest types in soil science with their provisioning ES interests (Figure 5).

3.3. Quiz Results and Comparison of Pre- and Post-Testing Responses to the Web-Based Survey

After the laboratory exercise, students were asked to complete a quiz to assess the learning outcomes. The quiz consisted of different questions, which tested students’ understanding of connections between soil pH, various forms of carbon in the soil, and ES. Analysis of individual question scores revealed that the concept of ES was still confusing to some students. Despite this confusion, the overall quiz scores were excellent, which demonstrates knowledge retention by the students after completing this laboratory exercise (Table 9).

Post-assessment results found that the lecture and laboratory exercise effectively educated students about the types of ES/ED with an increase in the number of students classifying their familiarity as “moderately familiar” (+33.8% increase from pre-assessment) and “extremely familiar” (+39.4% increase from pre-assessment) (Table 8). Students increased their familiarity with pH and SIC, as indicated by increases in the percent of “moderately” and “extremely” familiar categories. Most students agreed that the laboratory was an effective way to learn about ES/ED with examples from soil science (Table 8).

Detailed student comments were grouped by theme, with some examples shown in Table 10. Students enjoyed (T1. Enjoyment of learning) learning about soil pH, ecosystem services, and doing calculations. They appreciated the value of multimedia (T2), such as video and PowerPoint presentations. Completing individual easy-to-follow steps on their own time presented students with the flexibility of learning (T3). Students, in most cases, recognized the “applicability of content” (T4) when calculating the value of different ES/ED for their state/representative soils [12]. Students’ critical comments (T5) included requests for more explanation in both definitions and laboratory instructions.

Students’ answers to the open-ended request to write about their favorite experience in the exercise were used to create a word cloud, which shows the most frequently used words by the students (Figure 6). Such words included “soil”, “learning”, “calculations”, “values”, “services”, “ecosystem”, and “provisioning” (Figure 6).

4. Discussion

The results of this study demonstrate the importance of evaluating students’ prior interests when developing effective teaching methodologies. Most studies on interests ignore and do not evaluate students’ prior interest in a subject [6]. The implied assumption is that students are a “blank slate” independent of their prior education and life experiences. Mikhailova et al. (2019) [2] reported that students can have prior interests in subject matter, which can be used to create a wide range of effective interest interventions and learning experiences across the soil science course topics.

This study is different from Mikhailova et al. (2019) [2] because it is focused on using prior student interests in soil science to expand and make more relevant the “context of learning” (Figure 2) of a laboratory exercise on soil pH using ES/ED framework (Table 1). According to Kirk and MacDonald (1998) [16], context is formed by the learning environment and task. Jonāne (2009) [17] proposed the implementation of the contextual approach for promoting STEM sciences (Figure 7). The model of a didactical fractal can be used to improve STEM education [17]. This model offers a way to organize the educational process using its major categories (context, learner, content, and teacher) [17], which can also be used to discuss the findings of this study.

This study found that although a soil pH exercise is a typical component of an introductory soil science course, students come to the course with many similar previous experiences around measuring pH which can limit their interest in this topic. This study found that information about students’ prior interests can be very useful to identify a learning context to help engage the students in the learning process (Figure 7). Although prior interest varies, it is possible to assess interest types using open-ended questions as part of a beginning of course questionnaire. Student feedback can be grouped and quantified into categories that include interests most linked to it being a required course, prior experience, personal interest, and/or utility value (Figure 1) to find areas of commonality in student interest. Furthermore, asking students about both their interests and prior knowledge can help inform multiple interest interventions.

Development of interest has been linked to positive learning outcomes; however, it is important to consider students’ prior interests as well as the necessity to create student interest. A unique aspect of our exercise was that each student performed calculations for a different soil type that they had evaluated as part of an ongoing project, which may have also supported student interest while removing opportunities for sharing answers.

There are many studies on increasing students’ interests in STEM fields in middle school and high school to encourage students to select STEM career paths [6,18,19,20]. For example, LaForce et al. (2017) [19] evaluated survey responses from high school students attending STEM schools and found that problem-based learning experiences were linked to greater STEM career interest. Wyss et al. (2012) [20] found that showing middle school students video interviews of STEM professionals increased student interest in STEM fields. Shahali et al. (2017) [18] saw an increase in student interest for STEM subjects in students that participated in an informal STEM education program that included engineering design.

Studies on student interest in STEM fields in higher education are almost non-existent [2]. Research on interest development in high education STEM fields can seem paradoxical because STEM students have already selected a STEM major, which indicates a strong prior STEM interest. This may help explain the lack of research in this area. Teaching from the assumption that STEM students must have an inherent interest in their STEM fields does not necessarily imply that students actually have an interest in any particular STEM course or subject (especially required courses). This assumption ignores the wide range of experiences and interests that students may bring to a course, which is a lost opportunity to engage students at the beginning of a course to learn about their course-related interests and prior experiences. Therefore, this study argues that there is an opportunity to develop course content using these prior interests to create learning experiences. Better student engagement in STEM courses may help address the serious retention issue for STEM fields in higher education [21].

With so few studies on student interest in higher education STEM fields, this research provides a methodology for connecting students’ prior interest to interest intervention types (Figure 5) that can be used to develop exercises. This methodology can be applied to other STEM disciplines. Although this study used a specific course management system that is licensed at Clemson University (Canvas LMS) with a freely available survey system (Google Forms), the methodology could use a range of other systems which are often specific to educational institutions. This study shows that the assessment of the efficacy of a teaching innovation (e.g., a newly developed laboratory exercise) can be evaluated using various tools including quantitative (e.g., graded quiz) and qualitative (e.g., post-assessment survey) instruments.

5. Conclusions

This study discussed the need to connect students’ interests to a learning context to increase the effectiveness of STEM education. It used the results from a survey of students’ prior interests in soil science to expand the laboratory exercise on soil reaction (pH) with SIC and ES/ED concepts. Most of the students who had personal and utility value interests in soil science were interested in provisioning ES, which was used to create a problem-based interest intervention in the laboratory exercise on soil pH and SIC. Students were not familiar with the relationship between soil pH and SIC. The soil laboratory exercise involved learning about soil pH, SIC, calculating the provisioning (liming replacements costs), and regulating ES/ED (e.g., social costs of carbon, SC-CO₂) provided by SIC. The efficacy of this teaching innovation was evaluated using a pre- and post-testing web-based survey and quiz. An online quiz was used to assess students’ learning outcomes, which were successful for most of the questions. Students increased their knowledge of soil pH, SIC, and ES/ED, which can be helpful in their personal lives and professional careers. The results of the study were used to develop applied recommendations for utilizing prior knowledge of students’ interests in developing effective teaching interventions using various resources (e.g., interest theory; approaches to interest research; didactical fractal, etc.). This study proposes a new didactic form of teaching where students’ experiences and interests are accounted for by selecting and customizing learning exercises to make them more relevant and impactful for the students.

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Figure 1. Conceptual model showing the integration of prior student interests with a topic to create interest interventions to improve student learning outcomes (adapted from Harackiewicz et al., 2016 [3]; Mikhailova et al., 2019 [2]).

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Figure 2. Conceptual diagram describing three approaches to interest research (adapted from Krapp et al., 1992 [5]).

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Figure 3. Distribution of student interest types based on student comments from the start-of-semester questionnaire/survey asking students to write a short paragraph about students’ interests in soil science. Soil science was required for 46/58 (79%) of students.

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Figure 4. Distribution of phases of interest development [1] based on student comments from the start-of-semester questionnaire/survey asking students to write a short paragraph about students’ interests in soil science.

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Figure 5. The process of choosing interest interventions by understanding students’ interest types (soil science, ecosystem services) using the current study as an example. By identifying the common and predominant student interest types (the highest proportion in red) in both soil science and ecosystem services, it is possible to select the interest interventions (in green) based on the intersection of soil science and ecosystem service interests.

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Figure 6. Word cloud based on the students’ comments about their experience with the laboratory exercise on soil ecosystem services (ES) in the FNR 2040: Soil Information Systems course based on soil pH and soil inorganic carbon (SIC). The larger the word in the word cloud, the more frequent the word is in the students’ comments.

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Figure 7. Didactical fractal and its application to this study with examples (in red) of ecosystem services/disservices (ES/ED) as a context (adapted from Jonāne (2009) [17]). Soil reaction (pH) and soil inorganic carbon (SIC) are used as content.

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