1. Introduction
Attention towards energy and energy security over the last decade increased as the efficient military energy usage is considered to be one of the key enablers of military operational capabilities. This trend is reflected in European Union (EU) and NATO strategic priorities and initiatives that underline the importance of ensuring energy security for military operations as well as reducing the environmental impact of military operations [
1,
2,
3]. In addition, a portion of research, technology, and innovation (RTI) projects in military and defense are focused on energy and particularly on renewable energy solutions. In general, three key factors that affect energy usage can be listed: energy generation technologies, energy management, and energy data collection and analysis systems together with energy behavior at military units [
4,
5]. Resonating with an overall trend in energy transition towards pro-environment energy usage [
6,
7,
8], military RTI initiatives stress on technological solutions. Meanwhile, the energy behavior remains an inadequately explored factor in reducing the energy usage and thus increasing military energy security [
9] and energy efficiency [
10]. Even though energy behavior in the military is gaining more attention, overall attempts in changing energy behavior of military personnel remains a managerial challenge.
The Capability-Opportunity-Motivation-Behavior (COM-B) model proposed by Michie et al. [
11] and tested in numerous research projects is applied in this paper to investigate the energy-saving behavior in the military. The application of COM-B model to energy behavior leads to a better understanding of pro-environmental behavior in the military and facilitates a detailed analysis of the factors affecting this behavior. The model works in a context where three factors of the behavior (capability, opportunity, and motivation) are surrounded by managerial interventions, organizational policies, and limitations.
In the military context energy behavior is rooted into the trilemma of: (i) how to assure energy security for the military operations, (ii) how to use energy efficiently, and (iii) how to reduce the environmental impact of the operations [
1]. In this context, energy behavior plays a critical role after the energy policies and standard operating procedures are introduced and related technologies are deployed. All three considerations are gradually translated into the requirements for the United Nations (UN) peacekeeping operations as well as EU and NATO military environment promoting not only technological development but also energy behavioral changes. Specifically, the UN peacekeeping forces had implemented environmental policies in all peacekeeping missions since 2009 [
12]. This includes the requirements for environmental management systems that include energy, water, and waste management. As a new step in promoting pro-environmental energy usage in the military, the UN introduced its Environment Strategy of the UN Department of Field Support (DFS) which came into effect in January 2017. Its energy related objective “to reduce overall demand for energy through efficiencies” is planned to be realized by 2023 [
2] (p. 2). This includes not only the requirements for energy efficient infrastructure but also the behavioral incentives where “awareness-raising and behavioral change” [
2] (p. 2) play an important role. In general, the UN initiatives complement NATO’s approach on energy security, energy resilience, and the protection of critical energy infrastructure. The improvement of energy efficiency becomes one of the key priorities [
10,
13], therefore NATO’s approach is also focused on the military by “reducing the energy consumption of military vehicles and camps, as well as minimizing the environmental footprint of military activities” [
14]. At the Brussels Summit in 2018, those priorities were emphasized to the Member States underlining the importance of “more education and training opportunities” [
3]. This highly resonates with energy priorities in security and other sectors [
15]. Energy and energy security as the strategic priority was elaborated through the activities of NATO Energy Security Center of Excellence that was established in Lithuania in 2012 in order to assist Strategic Commands, other NATO bodies, nations, partners, and other civil and military entities by supporting NATO’s capability development process, mission effectiveness, and interoperability by providing comprehensive and timely subject matter expertise on all aspects of energy security.
Given the situation where the energy policies and standard operating procedures are already introduced, and energy related technologies are deployed the COM-B model explaining the behavior change factors becomes an effective tool for the further research of military energy behavior. According to the model’s designers Michie et al. [
11], three factors heavily influence the behavior: capability (C), opportunity (O), and motivation (M) (
Figure 1). The model explores individual’s behavior in the organizational context and provides the basis for managerial interventions [
16], as well as includes main steps for behavioral change [
17]. According to this model, all three conditions must be met in order to make an influence on individual’s energy behavior: the individual’s physical and social capability, individual’s social and physical ability to explore new opportunities, and self-motivation as the crucial part of the behavior change [
18]. This model was theoretically grounded and applied in a wide variety of contexts: nutrition [
19], smoking [
20], physical activity [
21], as well as for energy use by households [
22] and other end-users [
23]. The COM-B model was applied to improve energy behavior in the military too [
14,
24]. However, those behavioral interventions in military and defense were purely practical and lacked intrinsic validity. This suggests that the COM-B model should first of all be tested as a solution/construct in the military context.
Assuming that a military context differs from a civilian context, the COM-B model needs to be validated and factors influencing the pro-environmental energy behavior in the military need to be identified. Studies showed that military members are indoctrinated already at the beginning of their military career [
25]. Consequently, military culture penetrates attitudes and behavior, whereas individuals report strong identification with the military [
26,
27,
28]. The military’s impact on an individual increases along the duration of the military service [
29]. Based on this evidence it could be assumed that the awareness of energy criticality in the military is increasing over the years of service, as shown by research in military energy efficiency [
10]. Capability, opportunity and motivation affecting pro-environmental energy behavior are positively strengthened with the understanding that energy in military is considered to be a critical combat’s “tooth” [
1]. These considerations are taken into account when planning and conducting military operations for professional soldiers as well as for military conscripts. It is also assumed that the conscripts’ perception of the importance of energy in the military differs from the professional soldiers. The conscripts are serving for a short term and they can be not yet fully indoctrinated [
30]. Their capabilities, opportunities, and motivation to behave in a pro-environmental way could be linked to their civil life experiences of a green lifestyle [
31] and not to the military service.
Efficient usage of military equipment and infrastructure is perceived as a potential for the freedom of action and an opportunity for enhanced capabilities of the military operations [
1]. Consequently, important parts of the military’s RTI are directed at addressing those issues. For example, new technologies that are used in expeditionary environment as well as in fixed military installations are focused on improving energy supply and reducing the usage [
32,
33], but the awareness of energy behavior remains limited. Despite the emphasis on technical solutions related to energy, the call for behavioral change at a unit level remains a priority [
10,
34]. Considering that at military bases soldiers are semi-isolated from their existing ties as well as their life outside the military, their bond with a military unit rises [
35], and therefore, pro-environmental energy behavior must be analyzed not only from an individual’s behavioral perspective, but also from the individual’s social identification with the military unit. During the demanding military training, professional soldiers as well as conscripts are trained in order to increase their awareness of their own behavior in the context of the unit and their peers [
35]. Therefore, COM-B model must focus not only on the individual’s behavior, but also include the collective military behavior of the military unit.
The unique feature of our research is that we disaggregate two groups of energy behavior: individual energy behavior (“my” behavior) and unit energy behavior (“our” behavior). While the former follows the COM-B traditional paradigm used and validated in a series of studies (e.g., [
11,
16,
21,
36]), the latter relies exclusively on military research that puts a stress on soldier’s bond with a military unit [
28,
37].
The purpose of this study is to explore how a politically and institutionally favorable environment that forces military transition towards the pro-environmental energy behavior is reflected at a military unit level. The rest of the paper proceeds as follows. First, we outline our research instrument and measurement model by extending the construct of COM-B model for behavioral change in the military. Next, we perform data analysis using a series of statistical tests. By applying the COM-B model we investigate energy behavioral factors and postulate that the three behavioral change factors—capability, opportunity, and motivation—are positively linked not only with individual soldier’s behavior, but also with a collective energy behavior of the unit. Finally, discussion and conclusions are presented in the last section.
2. Materials and Methods
To measure the relationships between energy behavior in the military and affecting factors we collected data by making an annual survey for two consecutive years. The research was performed using traditional paper questionnaires at a selected Lithuanian military unit (fixed installation). The first survey was executed in October 2018 followed by the second survey in October 2019. During the first stage of data collection, 235 soldiers, non-commissioned officers, and officers were surveyed, while during the second stage the number of respondents was 219 soldiers, NCOs, and officers. Most respondents were conscripts (70 percent), followed by professional soldiers, NCOs, and officers (30 percent). Hence, the total sample was N = 454. Detailed demographic information of the respondents is presented in
Table 1. In some categories, the sum of all answers is less than 100% due to some missing responses. They were eliminated from further analysis.
The questionnaire consisted of Likert one-to-five scale questions where value 1 corresponded to “strongly agree” and value 5 to “strongly disagree”. In total there were 18 randomly listed statements related to COM-B measuring three latent variables: Motivation to save energy, Capabilities of the respondents, and available opportunities to exhibit the energy-saving behavior. Five statements were related to the capability category, seven statements to the opportunity category, and four to motivation. Two questions were attributed to the behavior category; they are analyzed later in the text. The ordinal scale of Likert questions limited statistical comparisons, and therefore several questions were included to measure the same variable, e.g., if three questions are used then the sum of the answers to these questions goes from 3 to 15, therefore it can be treated as an interval variable. We used Cronbach’s alpha (CA) coefficient to measure the internal consistency of the composing questions. During the process, one motivation-related question and two capability-related questions were eliminated from further analysis due to their detrimental effect on the CA coefficient of the corresponding variables. In other words, they were independently measuring something else than intended.
The three latent variables, their questions, and reliability (the CA coefficients) are presented in
Table 2. Observed variables were also validated individually: none of them have more than 5% of the missing values. Average values of all questionnaire answers are presented in
Figure 2.
Additionally, we performed the principal component analysis on all answers of the questionnaire using SPSS software in order to assess its internal consistency. Sum of eigenvalues of the main five components covered almost 60% of the variance. The first component corresponded exactly with the motivation questions, explaining their high CA coefficient and the reliability of measurement. The questions have high loading factors above 0.7 (see
Table 2) and their contribution to other latent variables is negligible. The second component grouped questions C1 and C3, with the C2 question also having a large load (0.71) in the third component and therefore significantly decreasing the reliability of capability measurements—it is the lowest among the latent variables. The remaining seven questions were grouped into three components separated in
Table 2 by horizontal lines, where O5, O6 and O7 constituted the strongest component of the three, O1 went together with O4, and the last component consisted of O2 and O3. Together the seven questions were assigned to the opportunity variable as initially intended. Overall, the analysis validated the independence of the three latent variables and the reliability of their measurement.
According to the COM-B model [
38] the behavior is determined by the three constituting factors: the previously defined latent variables Capability (
C), Opportunity (
O), and Motivation (
M). For the purposes of further analysis of the data, the three variables were combined into a single
COM variable:
where the scale of each variable is shifted to zero and normalized to 1 so that their contribution has the same weight, and then the normalized sum value is inverted to produce the combined
COM variable with values from 0 (worst) to 1 (best).
Variable B (behavior) was tested using two separate questions that represent connotations related to “My” versus “Our” energy behavior. It differs from the original COM-B construct presented in
Figure 1 where only one behavioral indicator is foreseen. We took into consideration the uniqueness of the military culture where collective behavior and soldiers’ psychological bond with his/her unit is manifested and adopted the COM-B model to the military context. “My” behavior (B1) was measured using a statement “I turn off the electricity when I stop using it”. For “Our” energy behavior (B2) we used a statement that represents a commitment to unit’s performance: “We manage energy well in the unit”. All together these two statements created a We-I behavioral construct for measuring energy behavior in the military (
Figure 3). These statements were measured using the Likert scale. Taking into consideration that COM-B model works in a context, we additionally tested an overall workplace satisfaction (see variable “S” in
Figure 2) of the soldiers using one 10-point Likert scale question.
3. Results
Using the
COM variable, we performed a series of tests for different groups of respondents at the 0.05 level of confidence. We found a statistically significant
COM increase of 12% among those who had participated in some energy-saving initiatives (
COM = 0.64) versus the other group (
COM = 0.57), see
Table 3. It is important to note that the number of those who had participated in energy-saving initiatives is relatively low and does not differ between the years.
Similarly, respondents who reported energy-saving behavior had a statistically significant 9% higher COM (average COM = 0.59) than their colleagues who do not exhibit energy-saving behavior (average COM = 0.53). The results stand well with the COM-B theory where higher capabilities, opportunities and motivation influence a better behavior.
To determine the context of COM-B we measured how an overall satisfaction with the military service is influencing
COM. The satisfaction (see
Figure 4) measured from 1 (lowest) to 10 (highest) has a 0.49 correlation coefficient with the
COM variable (at the 0.01 significance level). This is not surprising as we expected the satisfaction to be related with the motivation variable.
Considering the uniqueness of our sample that consists of professional soldiers and conscripts we checked whether there are any differences between these two groups of respondents one year apart. There was no statistically significant difference in average COM value indicating independent groups of responders as a large part of the professional soldiers was rotated and all the conscripts were replaced over that year. Meanwhile, the T-test of independent samples suggested a statistically significant although quite small difference in energy-saving behavior between the professional soldiers and conscripts: the average COM value of professional soldiers (0.60) exceeded the corresponding value of conscripts (0.57) by 5%.
In testing our main statement that
COM is positively linked not only with individual soldier’s behavior, but also with collective energy behavior of the unit, we measured the impact of the behavioral factors on an individual’s behavior (“my” behavior) in relation to collective energy behavior of the unit (“our” behavior). For this reason, we split the respondents into 6 different subgroups based on their responses about their own behavior and the collective energy behavior of the unit. The groups and their corresponding
COM values are presented in
Table 4. The first column shows the energy-saving behavior of the unit as reported by a respondent: a plus sign is given when the respondent positively evaluated the collective energy behavior, a minus for the negatively reported behavior, and a zero when the respondent reported a neutral behavior. The second column has two values depending on whether the respondent herself/himself exhibits energy-saving behavior (either a plus or a minus). One-way analysis of variance (ANOVA) showed a significant difference in mean
COM values between all groups. The results show a much stronger effect of
COM value on “our” behavior than on “my” behavior.
Individually, each of the behavior variables positively correlates with the
COM variable—the correlation coefficient is 0.45 for “our” behavior and 0.16 for “my” behavior. This can be observed in
Figure 5, where the behavior becomes more positive as the
COM variable grows.
4. Discussion
This study fills the gap in the research on military energy behavior and suggests that pro-environmental energy behavior in the military is linked not only with an individual soldier’s attitudes and intentions, but also with its military unit. Institutionally favorable environment that forces military transition towards the pro-environmental energy behavior is reflected as a collective action. So far, many studies focused on technical solutions for reducing energy usage [
33,
39,
40] and enabling decision makers [
5,
14,
41] and individual soldiers [
10,
24] to save energy. It appears that this research for the first-time underlines collectivity and connects individual and collective pro-environmental energy behavior into one measurable construct.
Pro-environmental energy behavior in the military should be considered in a special way as military culture penetrates attitudes and behavior [
26,
28]. Respectively, our conceptual construct that includes a collective energy behavior goes in line with other studies designed for communality in the military. Transformation from “I” to “We” is unique to the military as it serves as a protective psychological construct in difficult exercises and war situations [
35]. According to our findings, in the case of pro-environmental energy behavior, this transformation makes a positive impact on both the collective and the individual behavior. These findings go in line with the findings where macro influences on energy behavior are discussed. According to the comprehensive review of studies about energy behavior in organizations, energy behavior is driven by broad social and institutional considerations [
7,
42]. In response to this statement, our research findings indicate that in the military unit communality acts as the factor of sustaining pro-environmental behavior, i.e., when the change factors decrease, the unit still exhibits a positive behavior even if individual’s pro-environmental energy behavior might falter.
The segregation of collective and individual behavior is a fundamentally new approach in COM-B model testing. These results can be explained by the fact that the COM-B model was not tested before in organizations or communities where communality (strong sense of belonging) is more important than individual contribution. At the same time, the results are consistent with research results from various fields in the military and shows that a collective identity becomes more important than an individual soldier’s identity [
1,
27,
43]. For example, the collective identity was found dominating in the research on military innovations [
27], where a unique military culture was found manifesting. Similarly, studies on leadership in the military [
44] are predominately concerned about the function of military leaders to create subordinates’ emotional attraction to the organization which in turn increases commitment and resilience of soldiers.
Despite the segregation of the behavioral element, energy behavior in the military unit follows the classical COM-B model. Just like other researchers, we adopted the construct to the context of the organization. Thus, the results of this study resonate with the evidence of other studies using the COM-B model: the model is constructed with three statistically reliable indicators: capabilities, opportunities and motivation [
11,
21,
45]. In addition, the overall variance of the variables compares to the other energy behavioral models (e.g., [
15,
46,
47,
48]).
Furthermore, our research goes in line with the findings of research that energy-saving behavior is a learned behavior [
49]. In our study, those who participated in prior energy-saving initiatives reported a more positive energy-saving behavior. Energy behavior is a learned entity, thus prior experience increases the level of capability and splits energy users into groups according to this component. These findings are in line with the COM-B approach where the capability is one of three behavioral change factors [
11,
45].
Although the results of this study test behavioral change factors of energy behavior at a military unit, certain limitations need to be considered. Firstly, the data was collected at a unit located in a fixed installation only. To overcome this limitation, data was collected twice for two consecutive years to level out the operational tempo at the unit. The relative consistency of behavioral data suggests that these differences are minimal.
Secondly, the behavioral indicators of individual and collective behavior are measured using only a few questions. This is since the questionnaire response time was shortened to 10 min so as not to distract soldiers from their tasks. Therefore, the behavioral indicator was measured only with two measures: one for the individual and one for the collective behavior. Separation of individual and collective behavior was not foreseen from the start of this study—it became evident only during the data analysis. Despite this limitation, the relationship between COM and behavioral factors is statistically strong. However, in future research, we suggest using several measures for individual and for collective behavior.
Based on this discussion, the research has a few practical implications:
For practitioners in the military, these results are interesting for gaining statistically tested model for pro-environmental energy behavior change. Our findings point out that pro-environmental energy behavior in the military unit follows the classic COM-B model with one exception: behavior (element B) is segregated into two components: collective and individual behavior. This revised model can be applied in practice and used to measure behavioral change when behavioral interventions are applied in the unit.
For practitioners in other than military organizations, this analysis demonstrates the duality of collective and individual factors in energy behavior. Our findings point to an importance of communality in the organization. Communality makes an impact on capability, opportunity, and motivation in pro-environmental energy behavior in an organization. Specifically, the findings indicate that in the organization with a strong sense of belonging, collective pro-environmental behavior remains active even if an individual behavior indicates low-involvement.
5. Conclusions
This study addresses personal and collective factors emerging in energy behavior in a military unit. These are the main conclusions from the study:
First, collective and individual behavior has to be segregated while testing energy behavior in a military unit. The research findings justify this conceptual segregation and show that the dependence between the behavior change factors and the collective energy-saving behavior is pronounced more than the dependence between the factors of the individual’s behavior. The segregation of collective and individual behavior is a fundamentally new approach when testing the Capability-Opportunity-Motivation-Behavior (COM-B) model.
Second, an extended COM-B model can be used while measuring pro-environmental energy behavior in the military. The model validation process led to a construct with three statistically reliable indicators representing the three independent COM variables. In this construct, the three indicators were formed of a different number of measures, respectively: Capability was defined by three levels of knowledge (I receive information, I know, I understand). Opportunity was defined by seven measures and composed the largest indicator in the construct. Motivation, composed of three measures, was the strongest component of the model.
Third, positive energy behavior is linked with an overall satisfaction with the military service. This finding indicates that the three COM-B model variables—Capability, Opportunity, and Motivation—need to be understood more broadly than only in conjunction with pro-environmental energy behavior. Motivation is the dominant variable of the COM-B model in this study and it is, therefore, linked with the satisfaction too. Military service satisfaction through motivation is said to influence energy behavior in the military unit.
Fourth, there is only a small difference in energy behavior between the professional soldiers and conscripts. This finding demonstrates that while collective behavior prevails over the individual one in the military unit, the time and nature of the military service does not make a significant impact on energy behavior. This confirms the theoretical statements that energy behavior is a learned entity and therefore, further research on energy behavior in military organizations should incorporate this insight.