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Article

Determinants with Impact on Romanian Consumers’ Energy-Saving Habits

by
Violeta Mihaela Dincă
1,*,
Mihail Busu
1,* and
Zoltan Nagy-Bege
1,2
1
Department of Business Administration in Foreign Languages (UNESCO Chair), Faculty of Business Administration in Foreign Languages, Bucharest University of Economic Studies, 010371 Bucharest, Romania
2
Romanian Energy Regulatory Authority (ANRE), 020995 Bucharest, Romania
*
Authors to whom correspondence should be addressed.
Energies 2022, 15(11), 4080; https://doi.org/10.3390/en15114080
Submission received: 2 May 2022 / Revised: 26 May 2022 / Accepted: 30 May 2022 / Published: 1 June 2022
(This article belongs to the Special Issue Advances in Marketing Researches for Sustainable Development of Energy Economic)
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Abstract

:
Due to the population’s growing need for energy and the increasing impact of the phenomena of global warming and climate change on a global level, it becomes imperative to diminish energy consumption worldwide. For this reason, a deeper understanding of factors that encourage energy-saving habits and overall lifestyle is required. This research examined the factors that hold an impact on the adoption of energy-saving habits in Romania. It used eight constructs that were checked to see if they influence the individuals’ intentions to save energy. The research used a quantitative analysis approach, with primary data assembled through a survey of the population from six developed counties in Romania. In order to investigate and assess the data, structural equation modeling (SEM) was used. The results show that environmental awareness, perceived consumer effectiveness and a collectivistic perspective affect individuals in implementing energy-saving habits (in their life) in a significant and positive way. However, resistance to change and perceived costs were identified as having a negative and significant impact on the individuals’ implementation of such habits within their households. The outcomes of this research play a part in raising awareness of what could determine a more energy-saving lifestyle, and therefore it is essential that stakeholders within the energy sector in Romania consider the aspects of environmental awareness, perception of consumer effectiveness, perceived costs, collectivism and resistance to change during the development of programs of energy efficiency.

Graphical Abstract

1. Introduction

The availability of energy has changed the course of humanity over the last few centuries. Various sources of energy have been put to use—first fossil fuels, followed by diversification to nuclear, hydropower and renewable technologies. Moreover, the quantity of energy that the population can produce and consume grew over time, and this triggered environmental problems on an international scale such as global warming and climate change. Simultaneously, the worldwide energy demand has increased because of the economic progress but also due to the growth of the global population. If this increased demand is not offset by improvements in energy efficiency, then the global energy consumption will continue to grow year on year [1,2].
Following the EU’s ratification and joining of the Paris Agreement and with the EU 2030 climate and energy framework, the Union has taken a leading role in the fight against climate change by five dimensions: energy safety, decarbonization, energy efficiency, the energy internal market, and research, innovation and competitiveness. In order to meet this commitment, the European Union has established energy and climate targets for 2030 as follows:
  • The target of at least 40% domestic reduction in greenhouse gas emissions by 2030, compared to 1990;
  • The target of 32% renewable energy consumption in 2030;
  • The target of 32.5% for improvements in energy efficiency in 2030;
  • The 15% electricity interconnection target by 2030.
Romania’s 2021–2030 Integrated National Energy and Climate (ENCP) Plan is a ten-year integrated document mandated by the European Union in order for the EU to meet its overall greenhouse gas emissions targets [3], and it addresses all five dimensions of the EU Energy Union [4]. Understanding the human dimensions of a sustainable energy transition is one of the first steps to take in this complex process. Since a large proportion of energy in Romania is used by households, determining them to lower their use can benefit society and bring solutions to the environmental problems, especially since Romania is a country that has the potential to achieve energy independence.
In order to cut down on energy consumption in households, the population should adopt energy-saving habits and try to lower general energy (electricity) consumption in their home routines [5,6]. Illustrations of these kinds of actions and habits involve conservation and efficiency behaviors on the part of the consumers within their own homes. These behaviors are characterized by tendencies to conserve energy such as turning off the lights if they are not necessary at that specific moment or downsizing the use of different devices and gadgets [7,8]. Efficiency behaviors assume implementing structural changes that involve financing and expenses, which lead to sustainable energy-saving effects. Patterns of efficiency behaviors suppose buying and installing energy-efficient equipment, for example, LED light bulbs, smart windows, learning thermostats or energy usage monitoring apps [9]. This article incorporates conservation and efficiency behavioral tendencies toward energy within the general concept of energy-saving behavior. The preoccupation for such a study intersects with the 2021 increase in wholesale energy prices all over Europe which naturally prompted the Romanian government as well (similarly to many other European countries) to put into effect initiatives in order to shield consumers from the immediate and personal impact of climbing prices (such as different laws destined for vulnerable consumers or compensation and protections schemes) [10].
Since energy conservation is important for helping the environment, prolonging the existence of fossil fuels and saving money, this research concentrated on the potential factors with impact on creating energy-saving habits within the framework of households. Therefore, the article emphasizes the main research question: “Which factors are determining citizens’ energy-saving habits in households?”

2. Literature Review and Creation of Conceptual Model and Hypotheses

In the effort to discover what prompts citizens to develop energy-saving habits and, in the end, a general lifestyle, it is fundamental to recognize which factors and theoretical models could enhance or, on the contrary, lower it. Past studies have applied various stimuli and agents to reveal energy-conservation habits. These studies are commented on within this section as understanding the energy-saving habits of citizens could provide an important reference for predicting their future energy-saving behavior. This is particularly important for economic and social development, as well as for the potential improvement in the quality of life in all countries.
First of all, for ordinary people to diminish their energy consumption within their household, their perceptions, habits and eventually lifestyles have to evolve in a certain direction. Throughout history, various technologies that are practically and economically suitable in a certain situation could not be effectively applied due to social resistance. Resistance to change can affect the degree of energy-saving habits within domestic establishments [11]. The background behind resistance to change is that people feel a personal fear of a loss of quality of life and they connect energy-saving habits with abandoning a comfortable lifestyle [12]. A substantial amount of energy in households is spent on lifestyle or luxury gadgets—cooling and heating equipment (air conditioning, central heating furnace), water heater, lighting, washer and dryer, refrigerator, digital cable or satellite DVRs, computers (laptops use more energy than desktops), printers, routers, modems, phones, gaming consoles (keeping multiple consoles plugged in still costs), TVs (the larger the screen, the more energy used). Perceptions of comfort in the home are frequently associated with consumption related to thermal and air conditioning systems, household appliances and especially electronic (entertainment) devices [13]. When considering an energy-saving mindset, if a change appears and it disrupts the perceived comfort, individuals will respond with a behavior that inclines them to re-establish that comfort [14]. This reinstatement of comfort could lead to backfire effects or resistance to change altogether, which could impact the energy-saving habits of citizens in a negative way. These insights lead us to the formulation of:
Hypothesis 1:
Resistance to change is negatively related to developing energy-saving habits in the citizens’ households.
So that people become involved in actions such as saving energy in their domestic establishments to tackle environmental problems, the extent to which people believe in scientists and in environmental changes and evolution could influence their intent to save energy. Many research studies from the scientific community showed that if the public became more knowledgeable about the issues behind global warming, climate change and energy consumption, people would cultivate points of view similar to those of scientific specialists [15]. Science is not just for the few; on the contrary, it is for everyone and can be used by anyone. Believing in science was important throughout history in order to connect the practice and use of science, to inform and shape society, the countries and the world overall [16].
Trust in science is a factor often regarded and highlighted in research as necessary for stimulating an energy-saving behavior and promoting successfully renewable energy projects [17]. A study carried out by Mezger et al. [18] developed a model that helped explain the switching behavior of private consumers toward green electricity suppliers and strengthen an energy-saving behavior. The respective model was focused on factors such as trust in scientific information and perceived environmental impact. Liu, Bouman, Perlaviciute and Steg [19] connected the public’s trust in information to successful actions of mitigating climate change, saving energy through different methods and enforcing renewable energy sources for society. The study showed how the implementation of renewable energy projects and getting used to an energy conservation routine around the house as a citizen largely depend on public acceptability and belief in technology and science. As expected, higher trust and belief in scientists and research overall not only in the energy domain led to higher acceptability and understanding that energy-saving habits are needed. These views are concluded in the formulation of:
Hypothesis 2:
Belief in science is positively related to energy-saving habits within the household.
An aspect recognized in multiple studies confirmed that fundamental for determining better methods and policies to conserve energy is the fact that individual habits and perceptions of energy usage need to be taken into account. One such consideration is a household’s perception of energy usage habits and the perceived consumer effectiveness, a notion that can be outlined as an individual’s assumption that his or her capabilities could enrich and upgrade solutions for environmental and social problems [20,21]. Kim et al. [22] showed that people with more evolved perceived consumer effectiveness were more inclined to get involved in ecological consumption compared to those with a less developed degree for the same indicator, and this could be interpreted that individuals are more predisposed to act if they discern that their actions can influence a context or a conjuncture.
Lee et al. [23] also settled that perceived consumer effectiveness is favorably linked to environmental activism, which can lead to a higher energy-saving behavior within households. Consistently, Yang et al. [24] recognized that consumer effectiveness works as an arbitrator between information and the aspiration to act in a more energy-saving way. These assumptions enumerated above lead to phrasing:
Hypothesis 3:
Perceived consumer effectiveness has a positive influence on enhancing energy-saving habits in domestic establishments.
Another essential element influencing consumer adoption of energy-saving habits deals with awareness. Lately, more and more scholars recognize the importance of reducing energy consumption in terms of people’s energy-saving awareness and behavioral perspective [25]. Within this article, the term awareness encompasses aspects that are connected to people’s energy choices, such as familiarity with environmental information and news, consciousness of the repercussions of people’s activities on the environment or judgments about greenhouse gases and effects, fossil fuels, ecosystems or ecology overall [26]. Even though the citizens’ perception and appreciation of environmental problems are generally moderate, several studies asserted that an advanced degree of awareness makes it possible for people to decide attentively in a more environmentally friendly way [27]. It was revealed that being knowledgeable of environmental trends can change individual energy-related choices and that citizens would attempt to cut down on the use of gas and electricity at home in reaction to the menace of the environmental impact of the energy industry [28]. At the same time, attention to the side effects caused by pollution and resource depletion has been shown to motivate individuals to accept the use of an electric vehicle [29] or to shorten their regular energy consumption [30].
Another study carried out on students from a less developed country—Nigeria—concluded that the level of awareness of energy-saving measures of electricity end users was very low and consequently a lot of energy could be wasted. This analysis concluded that the energy-saving potential of students could be boosted if national or local authorities in higher education try to raise the awareness of all stakeholders by implementing energy efficiency awareness programs that could help universities to become sustainable from an energy point of view and reduce waste [31].
Hypothesis 4:
Environmental awareness positively affects consumer adoption of energy-saving habits.
The cost of adopting an energy-saving lifestyle plays the role of another noteworthy aspect that affects the consumers’ decision of implementing energy-saving habits in their daily routine. This variable puts forward a more complex discussion because even though energy saving is broadly regarded to be cost-effective and many times described as a low-cost method to contribute to energy efficiency within the community, the cost-efficiency aspect appears during a certain period of time—longer or shorter depending on the case [32]. This fifth variable of our model deserves particular consideration on the background of the first months of 2022 when Europe is facing continued volatility in its wholesale gas markets, prompting concerns across the region since the energy price could affect the economy altogether. It is worth briefly mentioning a few causes for the 2022 surge in wholesale power and gas prices, which are: low gas storage levels, high European Union carbon prices, fewer liquefied natural gas tanker deliveries due to higher demand from Asia, lower than normal Russian gas supplies and infrastructure outages [33]. Gaglia et al. [34] remarked that decreasing energy use in households helps people cut costs in time, increase the energy security of their home and lower the level of pollution that is released from non-renewable sources, but there are ways to reduce the consumed energy that suppose a particular investment at first. Various studies put forward different methods that can successfully reduce electricity use in homes such as energy-efficient products and appliances, such as light bulbs, windows, smart thermostats, etc., energy-efficient space heating and cooling systems, electric water heating, and reducing the “always-on” appliances, and some of these upgrades can range from low-cost to high-cost [35]. We should acknowledge the fact that in Romania’s case (uniformly with many other European countries), until the second half of 2021, energy prices were rather low, and therefore many consumers were not feeling motivated to take energy efficiency measures. Such various measures (apart from the behavioral ones) suppose a certain financial effort from the consumers who are already discontented and even confused about the soaring energy bills [36].
Hypothesis 5:
The perceived cost of becoming more energy-efficient influences the final decision of consumers to adopt energy-saving habits within their daily routine and their domestic establishments.
There are many studies that took into consideration the protection motivation theory when researching energy-saving behavior. This theory advances the idea that people protect themselves on the basis of two criteria: threat appraisal and coping appraisal. If threat appraisal weighs the austerity of the context and investigates how severe it is, coping appraisal represents how a person reacts to a specific context. From this perspective, the protection motivation theory accounts for how individuals discern their expectations of their own potential environmentally friendly habits regarding the costs and rewards involved in showing a pro-environmental behavior [37]. The theory has the underlying assumption that two cognitive processes impact protection motivation in reaction to a threat such as climate change [38].
These two processes, as can be deduced from above, are named in many publications as “threat and coping”. Threat appraisals—frequently associated with “worry”, “concern” or “perceived seriousness”—have been given extensive research regard, relating to the examination of people’s perceptions of energy efficiency [39]. Individuals assess and decide their threat and coping for energy efficiency and determine if an action is necessary or not. For threat, they judge if environmental problems are too intense and challenging and if they think they can be personally and directly compromised by the damaging effects of these environmental problems. For coping, we can refer to the individuals’ points of view and capability of keeping themselves away from the threat by performing (recommended) actions [40]. Another study by Hanss and Böhm [41] is particularly meaningful because it emphasized that the capacity of people to cope with environmental problems could lead to persuading and motivating other people to do the same. Therefore, the individuals’ beliefs on threat and coping can generate certain habits or patterns of actual attitudes and/or behavior.
For ecological issues such as climate change, green gas emissions or the decline of nuclear plants in different countries, citizens not only feel threatened by unfavorable or pessimistic news about environmental changes but also by the likelihood of readjustment of their own lives as well [42,43]. It is underlined in previous research that the significance of people’s perceptions of ecological change is related to the threat and coping appraisals concerning habit change. In these ways, the theory mentioned above suggests that threat and coping processes shape the approach that an individual can consider their position regarding environmental problems and might accordingly persuade and induce energy-saving habits in the household. Therefore the following hypotheses can be formulated:
Hypothesis 6:
The recognized threat (seriousness andacuteness) represents a precursory element of enhancing energy-saving habits within domestic establishments.
Hypothesis 7:
The recognized coping (self-efficacy and response handling) is positively linked to the enhancement of energy-saving habits within domestic establishments.
Alongside people’s judgment that they could correct their behavior, it is necessary to investigate if citizens are distinct in their energy-saving customs when they take into consideration the society/community’s points of view or their own beliefs. In this sense, some people could think that their actions might not be a remedy for noteworthy environmental problems, but other individuals who hold a wider view of collectivism could integrate into their daily routine more pro-environmental habits [44]. People who hold a more collectivistic worldview think that the community’s and even humanity’s concerns and benefits should overthrow the individual ones, and simultaneously, the central point of collectivism falls on mutual dependence, majority opinion, general agreement and emphasizing group objectives over individual aspirations [45]. This element was given attention because various research has distinguished that being oriented toward individualism or collectivism has consequences on multiple public or civil attitudes; there is a recognized straight effect of a collectivistic view on civic canons, and thus it is anticipated that the more elevated the standing of society’s collectivism is, the deeper the preoccupation and worry for the environment will be [46]. Citizens who hold a collectivistic world perspective are more predisposed to concern themselves with environmental degradation and the risk of emission of greenhouse gases while those who predominantly account from an individualistic angle tend to be more mistrusting of environmental threats. The quality of the environment is looked upon as a joint or public good that can only be maintained if citizens combine forces for this collective resource [47].
If the results of energy-saving behaviors are expected to be helpful for society as a whole more than for the individual, collectivism could represent a relevant trigger for pro-environmental behaviors and energy-saving habits incorporated in the daily routine [48,49]. Xiang et al. [50] showed that community-focused individuals reflect more on the impact of their actions and behaviors on society, which makes them more connected to an environmental perspective. Collectivism-oriented people are more predisposed to take part in pro-environmental activities as a result of them being more supportive and more inclined to cooperate with others and highlight collective purposes compared to personal ones [22,51]. Considering that environmental issues embody risks for the whole world, concentrating on joint objectives could influence the degree of energy-saving in domestic establishments.
Hypothesis 8:
A collectivistic perspective of society is positively related to developing energy-saving habits within households.
A summary of all hypotheses is provided in Figure 1 below.

3. Description of Research Methods

Research Tools, Data Selection and Data Investigation

Energy efficiency has enormous potential in Romania, where most existing buildings were built before the 1990s and have energy losses 2–3 times higher than modern buildings. Simple energy efficiency measures can reduce a building’s energy consumption by up to 40% [52]. Therefore an investigation of Romanian consumers’ inclination to integrate energy-saving habits into their daily routine is necessary. In order to obtain data from respondents, a structured and closed-ended questionnaire was implemented with respondents coming from six important counties in Romania: (Munic.) Bucharest, Iași, Cluj, Timiș, Brașov and Constanța. These counties were chosen as they are developed and among those with the largest consumers of residential electricity. The data were gathered between September 2021 and February 2022. Convenient random sampling was applied to settle on the participants in this study. In total, 884 filled-in questionnaires were collected, but after polishing the data, only 647 responses were used for the study.
The demographic details covered questions about the participants’ age, gender, degree of education, occupation and household size. Afterward, the partakers of the study had to provide information about various constructs. More specifically, eight different constructs were appraised: resistance to change, belief in science, perceived consumer effectiveness, environmental awareness, perceived cost of change, threat of and coping with environmental problems and collectivistic perspective of society. To measure the constructs of our model, most scales used a five-point Likert-type scale spanning from (1) “Strongly disagree” to (5) “Strongly agree”. For the “energy-saving habits” construct (the dependent variable), a five-point Likert scale ranging from (1) “Never” to (5) “Always” was applied. The first step was to assess the data by performing descriptive statistics of the demographic features of the participants of the study. The next action was to evaluate the reliability and validity of the data with procedures such as Cronbach’s alpha, average variance extracted (AVE) and convergent reliability (CR). Included in the statistical analyses that were conducted was confirmatory factor analysis (CFA) which assessed the model fitness. Afterward, in order to review the hypotheses of the research, the technique of structural equation modeling (SEM) was used to illustrate the correspondence between the constructs. The investigation was carried out applying the software AMOS version 26 and SPSS version 23.

4. Results and Examination

4.1. Descriptive Statistics of Participants

Table 1 shows the information about the participants’ demographics. As mentioned before, the total sample contained 884 participants, but partial or deficient answers were removed, and the final sample consisted of 647 participants. The participants were: 339 females (52.4%) and 308 males (47.6%) between the ages of 18 and 71. The age category with the biggest spread within the sample was 30–41 years counting for 314 participants (48.5%) followed by the 42–53 years old category (29.2%). It is also worth mentioning that all respondents were of Romanian nationality. When it comes to their education level, 22 (3.4%) had completed high school, 406 (62.7%) had graduated with a bachelor’s degree, 199 (30.8%) with a master’s degree, and 20 (3.1%) held a Ph.D. A total of 593 participants had a full-time job (91.7%), 43 participants had a part-time job (6.6%), and 11 were retired from activity (1.7%).
In total, 480 (74.2%) mentioned they were employed within a company (273 (42.2%) in the private environment, 207 (32%) in the public environment), while 156 (24.1%) were self-employed, and the 11 mentioned previously were retired (1.7%). Moreover, 77.4% of the participants had a domicile in the urban environment while 22.6% were rural residents. Regarding the household size, the most numerous category was the one of three persons (253 participants—39.1%), followed by the one of two persons (234 participants—36.1%).

4.2. Assessing the Model Fitness

In order to move on to the step of performing the concrete statistical investigation to test the hypotheses, the fitness of the advanced model was assessed. Therefore, assessment of the reliability and validity, on one hand, and confirmatory factor analysis, on the other hand, were used. The two tools to measure the reliability were Cronbach’s alpha and convergent reliability (CR), and the validity of the model was assessed with the average variance extracted (AVE). The CFA scores exposed the significance of the model given by the chi-square statistic (χ2 [859] = 958.35, p < 0.01), examining the minimum discrepancy function divided by degrees of freedom (CMIN/df); the value recorded was 2.218, and it was regarded as good since a CMIN/df value lower than 3 indicates an acceptable fit between a hypothetical model and sample data [53], with a CMIN/df value lower than 5 indicating a reasonable fit [54]. To confirm the significance of the model, supplementary indices were calculated: the normed fit index (NFI) valued at 0.857, also called the Bentler–Bonett index (the NFI ranges from 0 to 1, where 1 is a perfect fit) and the root mean squared error approximation (RMSEA) valued at 0.026 (in general, threshold values of less than 0.01, 0.05 and 0.08 for RMSEA indicate an excellent, good or mediocre fit, respectively) [55].
To show the reliability or the internal consistency of the model, the constructs with all factor loadings of their items can be observed in Table 2 together with the composite reliability (CR) and the Cronbach’s alpha of all the constructs. The CR and Cronbach’s alpha outputs of all the advanced constructs were higher than the recommended threshold of 0.7 [56]: CR values extended from 0.85 to 0.96 while Cronbach’s alpha spanned from 0.805 to 0.983. The (discriminant) validity of the model’s constructs was assessed by applying average variance extracted (AVE), which reached values between 0.561 and 0.664, and for adequate convergent, an AVE of at least 0.50 is highly recommended [57]. It is also necessary to mention that factor loading is essentially the correlation coefficient for the variable and factor or that factor loading shows the variance explained by the variable on that particular factor [58]. In the SEM approach, as a rule of thumb, a factor loading of 0.7 or higher represents that the factor extracts sufficient variance from that variable [59], and this is valid for our model as well (as can be seen below in Table 2).

4.3. Structural Equation Modeling

In order to assess the eight hypotheses of this research, structural equation modeling (SEM) was applied, and it gave a clearer representation of the links between variables of the study. The SEM method was applied as it is similar but more powerful than regression analyses, and it gives the chance to examine linear causal relationships among variables, while simultaneously accounting for measurement error [59]. The computation of the SEM model is presented in Figure 2 with the constructs (the latent variables) indicated with ovals and the items of the constructs (the observed variables) shown in rectangles. Residuals and variances are drawn as single arrows and a circle {(for each item (observed variable)}.
The fitness of the SEM model was weighed as mentioned before on page 9 of this article, and the outcomes of the chi-square statistic (χ2), CMIN/df ratio, NFI and RMSEA reached values that proved that the model fitted strongly with the data and corroborated to the decision that the model was adequate to move on to testing the research’s hypotheses. The results of the path analysis for the hypothesized model are reviewed in Table 3 and within the text below where a detailed explanation of the path coefficients encountered in Figure 2 is given (the numbers appearing above the arrows between each item and the construct to which it belongs to).
The generally agreed interpretation of standardized path coefficient (β) acknowledges that standardized path coefficients with absolute values less than 0.10 may indicate a “small” effect, values around 0.30 indicate a “medium” effect, while values greater than 0.50 indicate a “large” effect [60]. Hence, the results unveil that five hypotheses (their path coefficient is highlighted in the table with ***) were accepted as follows: The path coefficients of “Resistance of change (RES)” H1 (β = −0.584, p < 0.01)—line 1 of Table 3—demonstrated that the way individuals face change negatively and significantly influences the incorporation of energy-saving habits for Romanian residents. Consequently, H1 was accepted. Similarly, the path coefficients for “Perceived consumer effectiveness (CONS)” H3 (β = 0.682, p < 0.01)—line 3 of Table 3—showed that individuals perceiving that they are able to save energy in their households influences positively and significantly the incorporation of energy-saving habits in their lifestyle in Romania, and this conclusion led to the acceptance of H3. This research accepted H4 as well on the basis of the results for the path coefficients of “Environmental Awareness (ENVIAW)” (β = 0.527, p < 0.01)—line 4 of Table 3—meaning that awareness of environmental problems positively and significantly influences the incorporation of energy-saving habits in the individuals’ lifestyle in Romania. The path coefficients for “Perceived cost (COST)” of saving energy (β = −0.401, p < 0.01)—line 4 of Table 3—negatively and significantly influences the incorporation of energy-saving habits in Romania, and this resulted in the acceptance of H5. At the same time, the path coefficients of “Collectivistic perspective (COLL)” H8 (β = 0.721, p < 0.01)—line 8 of Table 3—denoted that individuals’ collectivistic perspective positively and significantly influences the incorporation of energy-saving habits in Romania.
Nevertheless, three hypotheses were not accepted because the values of their respective path coefficients were not significant: “Belief in science (BEL)” H2 (β = 0.089, p > 0.01), “Threat (TH)” H6 (β = 0.054, p > 0.01) and “Coping (COP)” H7 (β =0.073, p > 0.01)—lines 2, 6 and 7 of Table 3. Subsequently, we can conclude that the belief in science, the perceived threat of environmental problems and the perceived capacity of coping with environmental problems do not significantly influence the incorporation of energy-saving habits in the lifestyle of individuals in Romania.

5. Debates

5.1. Relationship between Resistance to Change and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

This study’s results reveal a significant and negative association between resistance to change and developing energy-saving habits within the households of Romanian citizens. This suggests that all sub-factors—“looking upon changes like they are a negative thing”, “developing a stable and steady routine in the home”, “getting stressed out when informed of a change of plans”, “feeling uncomfortable when pressured to change something even if that could benefit” and “having a consistent perspective and a vision”—influenced Romanian individuals’ decision to incorporate energy-saving habits in their lifestyle. These findings are in line with the results of the study developed by Sovacool [61] which investigated the cultural barriers to energy efficiency technologies and devices in the United States and showed that the psychological resistance of American citizens constitutes a major cause for them not to fully embrace energy-saving or efficiency measures.

5.2. Relationship between Belief in Science and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

This research’s outcomes showed a positive but non-significant association between belief in science and the development of energy-saving habits within the homes of Romanian citizens. The background of the COVID-19 pandemic could have contributed as well to diminishing trust in public authorities, institutions, politics and science overall in Romania due to an ensemble of fake news, conspiracy theories and uncertainty about the future of the country [62], which, in our opinion, provided a weaker role for the variable “belief in science” to exert influence over the dependent variable in our study as well. Based on the personal viewpoint of the authors, it is not unexpected to obtain these results on the background of the confluence of mixed messaging, misinformation and increasing politicization in Romania which created a convenient setting for eroding trust in science [63].

5.3. Relationship between Perceived Consumer Effectiveness and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

This study found a positive and significant influence of perceived consumer effectiveness on the Romanian citizens’ intention to incorporate energy-saving habits in their daily routine. It shows that the items of this construct included in this study, namely “contributing to the improvement of natural resources problems by saving energy and water”, “deciding on purchases of products by taking into consideration the energy efficiency labels on them as a way to protect the environment”, “willingness to recommend environmentally friendly products as a way to protect the environment” and “interest in buying energy-saving appliances”, all have an effect on adopting energy-saving habits by Romanian citizens in their lifestyle. It reinforces the idea that the perception of the effectiveness of individual action to protect the environment determines the assimilation of various pro-environmental habits. These results concur with the research developed by Arias and Trujillo [64] whose findings indicate that perceived consumer effectiveness influences the adoption of recycling behavior. This stands in line also with a more “classical” paper on the subject developed by Ellen, Wiener and Cobb-Walgren [65] who underlined the importance of perceived consumer effectiveness in stimulating environmentally conscious behaviors.

5.4. Relationship between Environmental Awareness and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

Environmental awareness was also identified as positively and significantly influencing the Romanian citizens’ intention to incorporate energy-saving habits in their daily routine. This confirms the findings of Otto et al. [66] which accentuate that attention and consideration for the environment should be cultivated at an early age so that children develop awareness and a capability to refine certain environmental values, hence channeling pro-environmental behaviors. These results are reinforced by those of Nikitha et al. [67] who indicated that environmental awareness and values contribute in a decisive way in predicting energy-saving behavior.

5.5. Relationship between Perceived Cost of Saving Energy and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

This research found a negative and significant effect of the perceived cost of energy-saving habits on the real situation of actually adopting such habits, and these results attest to the 2022 context when, among all the determinates mentioned above, the costs related to energy consumption are one of the most concerned determinates in relevant empirical studies [68]. This study’s relevance of the cost perceived by individuals when it comes to adopting energy-saving habits corroborates the findings of Boukkaz et al. [69] which state that an optimal energy strategy directed to the consumers for the current context of substantial increases in energy prices should include: on one hand, collective measures applied by public institutions from the sector but, on the other hand, also individual changes made by each citizen. These changes are taking place because the individuals’ interest and willingness for energy efficiency measures and avoiding large costs are continuously increasing. It is also becoming a powerful motivation for lifestyle change but also for investment in order to reduce consumption in the long run. The increasing impact of monetary reasons over a more energy-saving lifestyle is based on our personal observations but also on the study of Keller et al. [70] or the one of Quaranta et al. [71] which address the fact that the rising problems caused by climate change have a cost that needs to be covered by changes within the energy consumption behavior of citizens around Europe.

5.6. Relationship between Threat of and Coping with Environmental Problems and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

A positive but non-significant association was found between the threat of environmental issues and developing energy-saving habits for Romanian citizens. This indicates that a higher threat level does not induce a higher level of energy-saving habits. In addition to that, a positive but also non-significant association was identified between coping with environmental issues and energy-saving habits. This indicates that a higher feeling of coping with environmental issues does not translate into higher expectations of more energy-saving habits for Romanian individuals.

5.7. Relationship between a Collectivistic Perspective and Individuals’ Incorporation of Energy-Saving Habits in Their Lifestyle

A positive and significant relationship was found between a collectivistic perspective and the intention of adopting energy-saving habits by Romanian individuals. This denotes that the higher the feeling of collectivism is, the more energy-saving lifestyle can be expected, and it asserts that the willingness to take action against environmental problems may be shaped by cultural orientations. It corresponds with the conclusions drawn by Shi, Visschers and Siegrist [72] who stressed the relevance of knowledge and cultural worldview for the public perception of climate change.

6. Conclusions and Recommendations

Many academic studies have debated energy-related issues, especially on human behavior changes, as these can help smooth the effects of major environmental problems. Therefore the objective of this study was to explore the factors influencing the individuals’ adoption of energy-saving habits in their daily routine in Romania. A series of different variables were analyzed to evaluate those that hold a positive/negative and significant impact on the individuals’ incorporation of energy-saving habits in their routine and those with an insignificant impact. This research incorporated various theories, and the final variables taken into account to be investigated were: resistance to change, belief in science, perceived consumer effectiveness, environmental awareness, perceived cost of becoming more energy-efficient, recognized threat of and coping with environmental problems and collectivistic perspective of society.
This research applied a quantitative analysis, and the data were gathered from six developed cities in Romania. The methods of CFA and SEM were used to analyze the data. The outcomes of this research showed that perceived consumer effectiveness, environmental awareness and a collectivistic perspective have a significant and positive effect on people’s intention to incorporate energy-saving habits in their lifestyle while resistance to change a significant and negative effect. The perceived cost of becoming more energy efficient was identified to have a negative and also significant influence on individuals’ incorporation of energy-saving habits in their routine, while belief in science, the recognized threat of and the recognized capacity to cope with environmental problems were detected to have a positive but non-significant influence on individuals’ incorporation of energy-saving habits in their routine.

6.1. Implications

This research offers notable knowledge about the incorporation of energy-saving habits in the citizens’ lifestyle which could be useful for different stakeholders, government agencies, institutions and NGOs that are interested and involved in the topic of energy efficiency. Parties of interest should put more emphasis on the aspects of resistance to change, perceived costs of more energy-saving habits, perceived consumer effectiveness, environmental awareness and collectivistic perspective when developing intervention strategies or running campaigns to forward the benefits of an energy-saving behavior in Romania. Unfortunately, until 2022, for decades in a row, the expenses with energy were not high for household consumers, and as a consequence, few domestic establishments were preoccupied with energy conservation. However, in 2022, the clean energy transition, the volatility of the gas and electricity markets, the liberalization of the Romanian energy market and the escalation of the Russo-Ukrainian war are all factors that affected the energy prices for the Romanian consumers. This paper acknowledges that improving energy efficiency is a key priority of the national energy policy, and it provides a glimpse into the factors that can change Romanian citizens’ lifestyle into one that could bring more benefits to the environment, as well as for the preservation of non-renewable resources.

6.2. Policy Suggestions

Reckoning with the results of this study, and relating to the context of energy efficiency in Romania, a few policy suggestions can be formulated. Energy use is a leading catalyst for environmental challenges, such as global warming, climate change and greenhouse gas emissions. To tackle these problems, it is going to take a global commitment, and every single individual needs to contribute while businesses will also have to commit. At the same time, governments and concerned stakeholders will have to invest time, money and effort to increase the population’s consciousness of the danger and risks emerging from too much energy consumption and/or consumption of energy originating from non-environment-friendly sources. A few examples can be provided: to seek mechanisms to evaluate the levels of environmental awareness among the population, to allow energy interventions, to effectively use tools such as social marketing, to organize community-based media campaigns that could raise energy awareness, to establish platforms that allow the public to communicate face to face with various stakeholders (educators, building industry professionals and energy specialists). Another policy recommendation could be formulated in the sense that environmental awareness should be reinforced through appropriate educational programs at all three primary, secondary and higher education levels. This would foster and encourage a favorable attitude toward consuming and conserving less energy and a willingness from homeowners to make small changes that, even if they seem non-significant, can make a difference and change the levels of energy consumption of the population as a whole.

6.3. Limitations of the Research

Some limitations of the study can be mentioned here. First of all, this research was conducted in Romania, taking into account Romania’s social and cultural characteristics. These aspects are not similar to those from other states, and consequently, exploiting the results in other geographical areas should be done carefully. Another limitation is that the study omitted the inclusion of some variables which would have made the model richer and more interesting such as the political orientation of the respondents (because we wanted to keep the study more focused on behavioral/psychological and economic factors and because previous studies carried out by the authors showed that questions related to politics can be perceived as sensitive by some respondents) or the perception of the benefits coming from energy conservation. We will look at involving these variables in further studies. Furthermore, this research was conducted less in rural areas, the final proportionality favoring the participants from urban areas, participants from villages not being so easy to target, on one hand, and not being sufficiently informed about the topic, on the other hand. However, future research should be developed to involve more energy users from rural communities and the factors that may impact their incorporation of energy-saving habits.

Author Contributions

All authors have contributed substantially to the entire work reported. Conceptualization, V.M.D. and Z.N.-B.; methodology, V.M.D., M.B. and Z.N.-B. writing—drafting, V.M.D. and M.B.; writing—input, all authors; writing—reviewing and editing, V.M.D. 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

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Overview of the hypotheses including the determinants with influence on the adoption of energy-saving habits by Romanian citizens.
Figure 1. Overview of the hypotheses including the determinants with influence on the adoption of energy-saving habits by Romanian citizens.
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Figure 2. Assessment of the SEM model.
Figure 2. Assessment of the SEM model.
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Table
Table 1. Demographic details of the participants.
Table 1. Demographic details of the participants.
GenderFrequencyPercentEducationFrequencyPercent
Male30847.6High school223.4
Female33952.4Bachelor40662.7
AgeFrequencyPercentMaster19930.8
18–29517.9Ph.D.203.1
30–4131448.5Employment environmentFrequencyPercent
42–5318929.2Private27342.2
54–658112.5Public20732
65–71121.9Self-employment15624.1
Employment timeFrequencyPercentRetired111.7
Full-time59391.7Domicile areaFrequencyPercent
Part-time436.6Urban50177.4
Retired111.7Rural14622.6
Monthly income/pensionFrequencyPercentHousehold sizeFrequencyPercent
<RON 2.500456.919214.2
2.501–4.50020331.5223436.1
4.501–10.00029144.9325339.1
10.001–30.0008312.84619.4
30.001–100.000253.9571.2
Table
Table 2. Reliability and validity analysis of the hypotheses.
Table 2. Reliability and validity analysis of the hypotheses.
ConstructItemCronbach’s AlphaCRAVELoading
Resistance to change
(RES)		RES 1—I typically look upon changes as a negative thing0.8770.880.5610.763
RES 2—I developed a stable routine in my domestic life0.775
RES 3—If I am informed of a change of plans, I feel a little stressed0.784
RES 4—If I feel pressured to change something I feel uncomfortable even if I sense that change will benefit me0.721
RES 5—My perspective and my vision have been consistent during the time0.805
Belief in science (BEL)BEL 1—Scientific theories are reliable0.8050.850.5730.714
BEL 2—Science and scientist are to be trusted to uncover answers which explain the natural world0.787
BEL 3—I believe that scientists can develop solutions for the world’s primary technological issues0.792
BEL 4—Scientists can be biased in their viewpoints0.821
BEL 5—Science can sometimes advance too slowly0.836
Consumer effectiveness (CONS)CONS 1—I can contribute to the improvement of natural resources problems by saving energy and water 0.9830.920.6320.887
CONS 2—I decide on my purchases of products by taking into consideration the energy efficiency labels on them as a way to protect the environment0.854
CONS 3—I am willing to recommend environmental friendly products to others if I am satisfied with them as a way to protect the environment0.841
CONS 4—I am interested in buying energy-saving appliances0.863
Environment awareness (ENVIAW)ENVIAW 1—I am aware about the environmental problems caused by different types of energy sources0.8570.910.6640.822
ENVIAW 2—I am aware of the benefits of energy saving actions0.803
ENVIAW 3—I believe awareness of environmental problems can contribute to finding solutions for them0.789
ENVIAW 4—I hold an emotional affinity towards nature0.774
ENVIAW 5—It is important to be aware not only of environmental problems but also of environmental regulations and policies.0.721
Perceived cost (COST)COST 1—I am aware that there are ways to reduce the consumed energy that do not cost anything and other ways which suppose an investment0.8810.930.5820.801
COST 2—I am willing to make low-cost, energy-efficient upgrades in my home0.824
COST 3—I am willing to pay more for energy-saving appliances with higher energy efficiency0.805
COST 4—I am willing to make a more costly investment for a more complex upgrade on my home that will save energy and money over time 0.747
Collectivistic perspective (COLL)COLL 1—Before taking a decision I always consult other people (family, coworkers)0.9080.900.5970.784
COLL 2—I prefer to work in a group than individually0.773
COLL 3—The well-being of my community is important to me0.719
COLL 4—I feel good when I cooperate with others0.755
Threat (TH)TH 1—Environmental issues could represent a menace for me and my future0.8920.870.6310.707
TH 2—It is very likely for me to experience side-effects of environmental issues0.724
TH 3—Current environmental problems constitute severe threat for humanity0.768
TH 4—Current environmental problems will have serious negative consequences for future generations0.736
Coping (COP)COP 1—Energy-saving in domestic establishments can prevent environmental issues 0.8770.850.6420.702
COP 2—I have the ability to save energy within my domestic establishment0.753
COP 3—My actions to contribute to resolve environmental problems will encourage others to do the same0.837
Energy-saving habits (ENSAV)ENSAV 1—How frequently do you switch off the lights in your home when leaving the room?0.8940.960.6380.887
ENSAV 2—How frequently do you switch off the TV in your home when leaving the room?0.865
ENSAV 3—How frequently do you shut down your computer when you leave your desk for a break? 0.894
ENSAV 4—How frequently do you totally unplug devices instead of leaving them in a “standby” mode?0.883
ENSAV 5—How frequently do you cut back on air conditioning to control energy use?0.880
ENSAV 6—How frequently do you restrict your shower time so that water is saved?0.872
ENSAV 7—Do you wait to have a full contents washing machine to use it?0.868
ENSAV 8—How frequently do you keep devices connected to a plug, even they already fully charged?0.871
Table
Table 3. Appraisal of the research hypotheses.
Table 3. Appraisal of the research hypotheses.
Hypothesis(Path) Relationshipβ (Estimation)Decision (Accept?)
1RES→ENSAV−0.584 ***Accept
2BEL→ENSAV0.089Not Accept
3CONS→ENSAV0.682 ***Accept
4ENVIAW→ENSAV0.527 ***Accept
5COST→ENSAV−0.401 ***Accept
6TH→ENSAV0.054Not Accept
7COP→ENSAV0.073Not Accept
8COLL→ENSAV0.721 ***Accept
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Dincă, V.M.; Busu, M.; Nagy-Bege, Z. Determinants with Impact on Romanian Consumers’ Energy-Saving Habits. Energies 2022, 15, 4080. https://doi.org/10.3390/en15114080

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Dincă VM, Busu M, Nagy-Bege Z. Determinants with Impact on Romanian Consumers’ Energy-Saving Habits. Energies. 2022; 15(11):4080. https://doi.org/10.3390/en15114080

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Dincă, Violeta Mihaela, Mihail Busu, and Zoltan Nagy-Bege. 2022. "Determinants with Impact on Romanian Consumers’ Energy-Saving Habits" Energies 15, no. 11: 4080. https://doi.org/10.3390/en15114080

APA Style

Dincă, V. M., Busu, M., & Nagy-Bege, Z. (2022). Determinants with Impact on Romanian Consumers’ Energy-Saving Habits. Energies, 15(11), 4080. https://doi.org/10.3390/en15114080

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