Abstract
Despite the benefits of sustainable innovations in the agricultural sector being widely recognized, their adoption rate remains below the level designated by the 2030 Sustainable Development Goals. To understand the reasons behind this phenomenon, the current systematic literature review (SLR) provides a comprehensive overview of factors affecting farmers’ innovation adoption behavior in developed countries. A total of 44 studies, published since 2010, were identified, analyzed, and summarized. The analysis revealed that specific innovation characteristics foster the innovation adoption process, together with individual psychological and socio-demographic features. It emerged that the path to adopting sustainable innovations can be driven by environmental values; for example, when comparing organic and conventional farming, organic farmers have a stronger environmental view and are more likely to take less into account economic gains. On the contrary, complexity of innovation, a high degree of innovation aversion, and a low perceived control over innovation are among the core barriers to the innovation adoption. Findings provide important insights on potential research avenues that could further depict farmers’ adoption dynamics of sustainable innovations.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
The adoption of sustainable agricultural innovations offers a promising alternative for mitigating the environmental impacts stemming from agricultural practices (Foguesatto et al. 2020). In recent years, there has been a growing recognition of the urgency to adopt more sustainable strategies in the agricultural sector, driven by a desire to assess their positive environmental effects (D’Amato et al. 2021). MacRae et al. (1990) asserted that the achievement of sustainability in agriculture relies on the pursuit of specific agricultural practices that aim to curtail the long-term repercussions of human activities on natural resources. Among the various options available, organic farming, precision farming, regenerative agriculture, and agroecology undoubtedly stand out as effective approaches (Ferreira et al. 2022; Ndaba et al. 2022; Sachet et al. 2021; Newton et al. 2020). These offer innovative solutions to tackle the challenges of agricultural sustainability, safeguarding the environment while ensuring the production of wholesome, high-quality food. By embracing these modalities, farmers can promote ecological resilience, conserve natural resources, and respond to the pressing need for sustainable agricultural systems. Organic farming, in particular, is widely regarded as the most sustainable and responsive method in the primary sector (Ferreira et al. 2022; Canaj et al. 2021). It emphasizes the adoption of natural techniques and the exclusion of pesticides and chemical fertilizers, thereby promoting soil health and preserving biodiversity (Chiriacò et al. 2017; Lee and Yun 2015).
Even if organic farming has its roots in the 1990s (Kuepper 2010; Joachim 2006), it still represents a true innovation in the agricultural system by incorporating cutting-edge concepts of technology and research (Padel, 1994). This approach places ecological balance as a priority and strives to minimize the environmental impact of agricultural practices through the utilization of organic inputs and sustainable farming methods (Canaj et al. 2021).
Nevertheless, there are still several obstacles that slow down the implementation of sustainable practices that are useful for the ecological transition (Manta et al. 2022). Among them, development and technology transfer capacity and an attitude of resistance of farmers themselves to innovations appear to be the most relevant obstacles (Niggli et al. 2017).
It follows that, despite the recognition of the sustainable practice benefits, the adoption rate of sustainable innovations remains below the level designated by the Sustainable Development Goals (SDGs) identified by the United Nations for 2030, as many farmers are reluctant to adopt innovations (D’Amato et al. 2021; Foguesatto et al. 2020; Zeweld et al. 2017, 2018). To understand where the obstacle to the innovative adoption may lie, several studies and reviews have been proposed to deepen the analysis of the innovation adoption process among farmers and the multiple factors that may influence their behavior (Guerin 2001). It turned out that psychological factors play a strategic role in influencing the process of innovation adoption and diffusion among farmers (Caffaro and Cavallo 2019; Zulfiqar and Thapa 2018; Price and Leviston 2014), as well as socio-economic factors, including farmer’s age, income, and education (Akimowicz et al. 2021; Serebrennikov et al. 2020; Caffaro and Cavallo 2019), and some contextual factors, such as the size of the farm, and the environmental and political context in which it operates (Piñeiro et al. 2020; Foguesatto et al. 2020; Hernandez-Vivanco et al. 2018; Bravo-Monroy et al. 2016). Nevertheless, psychological, socio-demographic, and contextual determinants that influence the farmer’s innovation adoption process are often analyzed separately, producing in some cases conflicting results.
The presence of poorly defined and sometimes contradictory results in empirical studies may stem from the tendency to primarily rely on a variance-based approach, whereas a configurational approach might be more suitable.
The variance-based approach aims to identify the most influential factors on a particular phenomenon or outcome by analyzing correlation or regression coefficients. In contrast, the configurational approach examines complex patterns and configurations of variables that lead to specific results. Indeed, this approach recognizes that the combinations of variables or conditions can produce unique or different outcomes compared to individual variables (Furnari et al. 2021). The configurational approach argues that the different combinations of attributes lead to adoption, thereby explaining the existence of multiple pathways and potentially resolving contradictory findings (David et al. 2021; Fürstenau et al. 2021). Therefore, if this is indeed the case, employing a variance-based approach to analyze innovation adoption becomes futile, as it fails to fully illuminate the phenomenon under investigation. Concentrating solely on measuring correlations or cause-and-effect relationships between individual variables may prove inadequate in achieving a comprehensive understanding (Meyer et al. 1993). Innovation adoption, being a complex phenomenon, necessitates a thorough examination of the interactions between various variables and conditions. This approach acknowledges nonlinearity, where variables that are found to determine the development of a given phenomenon in one situation might yield different results in another situation (Fiss et al. 2013).
In this view, the current SLR uses a configurational theorization: past findings may be contradictory because they acknowledge that a given cause would affect all farmers in the same way, irrespective of its combination with other factors. When this assumption is challenged, it is necessary to revisit and reanalyze previous findings to provide a better account of the paths that lead to adoption.
The configurational approach acknowledges the concept of equifinality, understanding that different paths can lead to success in various contexts. For instance, a company might thrive through business innovation or a niche strategy, whereas the same approaches could result in failure for another organization. This approach recognizes the significance of disorder, diversity, and nonlinear relationships in shaping outcomes (Meyer et al. 1993).
Bearing in mind this scenario, the current SLR challenges the idea that there can be only one path to success during the innovation process, rather it sets out to identify all the factors that might come into play, aware that these may interact with each other in a multitude of ways and for a multitude of reasons. In doing so, the variables found in various studies will be categorized around two major reasons driving adoption: desirability and feasibility (Gatewood et al. 1995). Both dimensions are relational so that they result from interplay of agency (what farms can do and what innovations can do) and structure (what regulation or routines allow to do). It is assumed that if an innovation is seen as strongly desirable, farmer may make it feasible, by actively seeking to financial or technical aids. And conversely, if it is not deemed feasible, the desirability will be curtailed.
The results of this review could have both theoretical and policy implications. From a theoretical perspective, understanding the factors influencing the farmer’s adoption of innovations would enrich the current knowledge, providing a valuable addition to the available literature. In terms of policy implications, a clear picture of the factors underlying the dynamics of farmer’s adoption of product and process innovations could be useful in better targeting policy measures tailored to encourage sustainable innovations in the agricultural sector.
Research procedure
Review protocol
Writing an SLR entails the use of a protocol that systematically describes all the steps to be followed, from the definition of the research question to the careful analysis of the selected manuscripts. The study was conducted based on the following research question: “What are the main factors influencing the sustainable innovation adoption process by farmers?” Subsequently, a six-step selection process was followed starting in March 2021, according to the preferred reporting items for systematic reviews and meta-analyses approach-PRISMA (Page et al. 2021). Initially, the search results were manually tabulated in a spreadsheet, and duplicates were removed. Then, filters concerning the type of manuscript, the years and place of publication, and the English language were applied to select the documents, and later the titles and abstracts of the studies have been read. After this step, full texts were analyzed, and further exclusions were made when necessary. Furthermore, a quality assessment of the selected studies was performed in order to critically evaluate scientific studies to determine the quality, reliability, and validity of their results. The main objective of quality assessment is in fact to assess whether a study has been conducted in a rigorous manner and whether the results obtained are reliable and can be considered valid (Tummers et al. 2019). The development of a meta-analysis was excluded because, to make a correlation between variables, it is necessary to use homogeneous samples and results (Pati and Lorusso 2018). Indeed, it synthesizes econometrically the data from various sources to obtain a global estimation of the effect or association between the variables of interest. Instead, this review investigated studies of different nature (qualitative and quantitative) and studies using samples with different numbers of participants and diverse selection modes (mainly random convenience samples). More in depth, an integrative approach was chosen to explore the investigated studies due to their heterogeneity in designs and outcomes preventing quantitative analysis (Torraco 2005). When different studies exhibit significant differences in methodology, samples, outcome measures, or other aspects, conducting a traditional quantitative analysis such as a meta-analysis can be challenging or inappropriate. Instead, the integrative approach aims to obtain a comprehensive view of the results from the included studies, seeking to identify patterns, trends, or common themes that emerge through the analysis of both qualitative and quantitative evidence.
For each study, information about the year and country in which the research was conducted was identified, and information about the methodology used and the main outcomes obtained was extracted. Finally, the factors influencing the innovation process were extrapolated.
The procedure was carried out by three researchers simultaneously, following the suggestion of Pati and Lorusso (2018), and the final outcomes were the results of a common agreement. The SLR was completed in December 2022.
Study selection criteria
Given the aim of the systematic literature review, a Boolean algorithm was applied as follows:
((organic OR sustainable OR green) AND (innovation OR practices OR product) AND (agricult* OR farm* OR entrepr* OR producer OR food) AND (factors affecting OR risk OR driver OR barrier OR attitude OR behavior OR adopt* OR motives))
The Boolean algorithm was launched on the Scopus and Web of Science platforms. Specifically, key terms were searched in the titles, keywords and abstracts of manuscripts contained in the Scopus database and searched in “topic” for the Web of Science database.
The output led to many studies (8167 in Scopus and 5784 in Web of Science). The two databases Scopus and Web of Science were chosen due to their thoroughness and reliability (Page et al. 2021). First, before implementing a manual selection screening, a time constraint was inserted (only papers published after 2009) and only English language studies published in journals were used. It was chosen to investigate this time frame because in the field of social sciences it is important to cover at least a minimum of 10 years for a SLR (Paul and Criado 2020); additionally, this time spam coincides with the recent growth of sustainable innovations in agriculture. Furthermore, book, general reports, and conference proceedings were also excluded as lacking peer review and with more limited availability (Alves et al. 2016). Finally, only studies reporting results from the primary data collection were included in the analysis, as they are suitable for collecting useful information (e.g., sample number, country, methodology, and factors that influenced farmers) to achieve the intended goal.
After applying these filters, the number of papers was reduced to 5746 on Scopus and 2853 on Web of Science (applying the “Advanced Search” window). Of these, the title and abstract were read to make an initial sorting, excluding studies involving consumer behavior, performed in developing countries, and studies not examining factors influencing farmers during the innovation process. In addition, only studies investigating process and product innovations were selected. This resulted in a total of 89 reports assessed for eligibility. The current study explores the adoption of product and process innovations by farmers, as both are essential for a company’s long-term competitiveness (Damanpour and Gopalakrishnan 2001). These innovations drive significant structural changes on farms, necessary for achieving sustainability in the medium and long term (Gaziulusoy 2010). Process innovation, closely linked to product innovation, improves resource efficiency, promotes sustainable product design, and enhances product quality and range (Li et al. 2017; Damanpour 2010). Product and process innovations are interconnected and play a crucial role in driving agricultural development and competitiveness (Xie et al. 2019). Therefore, to have all the factors that may intervene in the process of innovation adoption is important to analyze both product innovations and process innovations. Furthermore, Zanello et al. (2016) pointed out that innovation is costly and risky; thus, pioneering innovation is mainly concentrated in few rich countries. Innovation requires appropriate institutions and policies to drive incentives and facilitate the process, as well as strong local capabilities to identify the right technology and appropriate transfer mechanism and to absorb and make adaptations based on local economic, social, technical, and environmental conditions (Fu and Gong 2011). Therefore, only innovation adoption in developed countries was analyzed, as these countries seem to possess the necessary scientific and technical knowledge to drive incentives and facilitate the process and the possibility to acquire the appropriate technology and transfer mechanism (Zanello et al. 2016).
Following this initial screening, the authors read the full manuscripts and applied the selection criteria, which brought the number of studies to 44. The applied procedure is fully shown in Fig. 1.
Results
Year of publication of the investigated studies
Figure 2 shows the years in which the studies analyzed in current SLR were published. Many of them were performed in recent years, highlighting the growing importance of the topic among scholars.
Countries included in the reviewed studies
The 44 studies in the review were carried out in 15 different countries. Most of the studies were conducted in Italy (9 studies), the USA and Germany (both with 8 studies), followed by the Netherlands and the UK with 7 studies. Four studies per country were conducted in Spain, France, and Australia, followed by Greece and Belgium with three studies, Switzerland, Hungary, and Denmark with two studies, and finally Poland with one study. The main geographical area of data collection was Europe. Six studies applied a multi-country sample, which is why the number of countries investigated is greater than the total number of papers selected. For more details, please see the Appendix (Table 4).
Theoretical backgrounds of the studies
The main theories and models applied by the investigated studies were also detected. It was found that most of the studies were not built on a theory or model, but their reasoning was only supported by previous empirical studies. Indeed, only 19 studies referred to a theoretical strand. There have been many theories used (e.g., the theory of planned behavior, the reasoned action theory, the theory of technology acceptance and diffusion of innovation, the AKAP sequence, and the classification of internal and external barriers and risk management strategies), but always referred in some way to the psychological sphere of the entrepreneur.
Research methodologies of the studies
The methodologies applied by the studies were quite heterogeneous: 25 studies were developed through quantitative research approaches, 12 of the studies presented a qualitative methodology, and 7 studies were based on mixed-method approaches. In particular, the first category included semi-structured questionnaires and the use of national databases, the second involved face-to-face interviews, and the last one consisted of exploratory questionnaires and workshops, or focus groups, or application of experimental economics mechanisms. Almost all studies relied on convenience samples and data collection methods were generally, briefly described.
Quality assessment procedure and outcomes
The 44 studies included in the review were assessed for overall quality. This assessment was carried out by applying the eight quality criteria presented by van Dinter et al. (2021) (Table 1). Each study was evaluated based on the satisfaction of eight different requirements. A score equal to 1 was given when the criterion was fully met, a score equal to 0.5 in the case of incomplete information, and a score of 0 if the criterion was not met in the study. The quality assessment was developed independently by two scholars and all discrepancies were deeply discussed to reach a common final judgment. The concluding scores obtained ranged from the lowest score of 4.5 to the highest of 8. The mean was 6.21 and the median 6. 37.3% of the documents examined received a score below 6, 29.5% were between 6 and 6.5, and 33.2% were between 7 and 8.
Narrative summary of the studies
This section outlines the factors affecting the innovation process found within the analyzed documents.
From each study, the factors affecting the adoption of innovations in agriculture were extrapolated and then, were grouped into the two components of desirability and feasibility (Table 2). Indeed, the intention to innovate, which is considered an important antecedent to the implementation of innovation itself (Krueger NFand Carsrud 1993), is related to attitudes regarding perceived desirability and feasibility (Gatewood et al. 1995). Since intentions have been shown to be a good predictor of behavior (Ajzen 1991), understanding the identity and nature of antecedent factors that influence entrepreneurial intentions is of crucial importance to the study of entrepreneurial innovation behavior (Shane and Venkataraman 2000). However, the relationship between these factors is quite complex (Krueger and Kickul 2006).
Therefore, considering this complexity and drawing on configurational theory, factors influencing the adoption process of sustainable innovations were grouped within these two dimensions to understand what might influence one and/or the other. For comprehensive information regarding the sources of the different factors identified and general details about the selected papers, please refer to Tables 4 and 5 available in the Appendix.
This review underlined that the perceived advantages of using an innovation is among the most influential factors. Indeed, innovation characteristics such as “relative advantage” and “compatibility” significantly increased the probability of adopting sustainable innovations among farmers. If potential adopters do not perceive any relative advantage in the innovation and good compatibility of the innovation with the farm, they generally do not consider it further (Tey and Brindal 2012). Following this reasoning, farmers often have conflicting goals (Dessart et al. 2019), as they want to introduce sustainable innovations while protecting their production activity (Gosling and Williams 2010). Therefore, sustainable innovation is adopted only where farmers expect it to help them achieve their economic goals tolerance (Pannell et al. 2006). These results agree also with Ferlie et al. (2001) and Rogers (1995) as they also found the power of the variables described above. On the contrary, some authors argued that the implementation of sustainable innovations is negatively correlated with economic goals, and positively correlated with pro-environmental attitudes (Greiner 2015; Greiner and Gregg 2011; Kallas et al. 2010). This result may be surprising in that some sustainable practices yield more than conventional ones (Dessart et al. 2019). However, it is possible to assume that if farmers have a strong environmental vision, they may disregard economic gains. Thus, a path to adoption may be guided by environmental values so that farmers are willing to change their routines to adopt. These environmental values are stronger among organic farmers (Siepmann and Nicholas 2018).
The psychological and socio-demographic characteristics of adopters significantly influence their willingness to embrace innovations. According to Piñeiro et al. (2020) and Chams and García-Blandón (2019), farmers with higher levels of education, a proactive approach to staying informed about potential innovations, a positive attitude towards sustainability, adherence to social norms, and a sense of control over adopting new practices are more likely to engage in the adoption process of innovations within the agri-food sector. These factors are crucial in shaping the strategic role of individuals in embracing innovative practices.
Similarly, Pierpaoli et al. (2013) by a selection of 20 studies identified the acquisition of good information and education level as the socio-demographic factors most influencing the adoption of innovations. On the contrary, in accordance with previous studies (e.g., Gupta et al. 2020; Kernecker et al. 2019; Lawrence and Tar 2018; Eastwood et al. 2017), it was found that the complexity of innovation, a high degree of innovation aversion, and the low perceived control over innovation are strong barriers to innovation adoption as they make the adopter insecure (e.g., Bechini et al. 2020; Aubert et al. 2012). At the same time, low education, poor advice support (Lindblom et al. 2017), and unfavorable working conditions (Caffaro et al. 2019; Bijttebier et al. 2018) turn out to be rather common hindering factors. Finally, the change of work routine and the increase in the market cost of the product also negatively influence the innovation process (Ghadge et al. 2020; Al-Rahmi et al. 2019) as it reduces the farmer’s certainty in implementing innovation. In fact, resistance to change in work routines and the personality of the entrepreneur are related (Creissen et al. 2021; Dessart et al. 2019). Farmers who are not predisposed to change in general may be particularly against change in general (Bonke and Musshoff 2020; George and Zhou 2001), as changing routines triggers a high perception of risk in them (Bakker et al. 2021; Trujillo-Barrera et al. 2016). However, high-risk perception can be mitigated by a good risk tolerance (Trujillo-Barrera et al. 2016; Arbuckle et al. 2013). Despite this, a lot of farmers reject the change (Barreiro-Hurle et al. 2018; Hellerstein et al. 2013).
Regarding the age and gender of farmers, the current review has returned conflicting results, and therefore it is still quite problematic to understand the real impact of these personal features on the innovation adoption process. Indeed, different studies have produced contrasting findings regarding the relationship between age and innovation adoption among farmers. While some studies suggest that older farmers are more inclined to embrace innovation (García-Cortijo et al. 2019; Vezina et al. 2017), others highlight the significance of younger farmers in driving agricultural innovation (Jack et al. 2022; Bianchi et al. 2022). Similarly, the influence of sex on innovation adoption varies across studies, with both women and men being identified as active adopters in certain contexts (Aznar-Sánchez et al. 2020; Thorsøe et al. 2019). Finally, contextual factors are also influential. Indeed, this review showed that the possibility of having a comparison with other peers and technical and/or financial support significantly increases the likelihood that the innovation will be adopted (see, among others, De Steur et al. 2020; Bordbar 2014). One of the reasons for this is that policies can enhance the farmers’ confidence and incentivize the adoption of sustainable practices. By offering tangible guidelines and support, policies can help farmers mitigate income volatility and foster a greater sense of security in embracing sustainable approaches. For example, through direct payments decoupled from production decreed by the European CAP, the risk tolerance of European farmers has increased (Koundouri et al. 2009). In addition, the ability to have advisory services can improve the farmers’ awareness, their environmental concerns, and the significance they place on preserving natural environment (Cullen et al. 2018). Likewise, long-term planning and teamwork have been found to help the implementation of innovation. These findings are consistent with Pierpaoli et al. (2013) who state that the observability of innovation results, good work design, and perceived ease of use were ranked as determinants to be considered. Finally, farm size and years of experience have also been found to affect the innovation process, although in literature there are conflicting opinions. For example, regarding the size of the farm, Dalla Corte et al. (2015), Rosenbusch et al. (2011), and Cohen (2010) found that a smaller farm size gives the company a greater agility to change routines for innovation implementation. This agrees with Bonney et al. (2007) who state that small- and medium-sized farms have always adapt and innovate to remain competitive in the market. In contrast, Muzira and Bondai (2020), Serebrennikov et al. (2020), and Borgen and Aarset (2016) found that larger farms are better able to administer the innovation process because they have more funds, more workers, and strategic planning of the work to be done. About years of experience in the industry, García-Cortijo et al. (2019) and Vezina et al. (2017) found that older farms are more likely to adopt new practices or products because the farmer at their helm possess the experience that can guide them on the new path. Conversely, Gütschow et al. (2021) and Rosenbusch et al. (2011), in their study of SMEs, pointed out that younger farms benefit more from innovation because mature farms have already routines that are difficult to change in terms of organizations, cost, and time than new farms that have yet to consolidate their routines.
Type of innovation
The analyzed manuscripts were classified into four innovation categories: organic farming, precision farming, regenerative agriculture, and agroecology. Nine articles were found that investigated the adoption of precision farming by farmers. These studies highlighted the increasing interest in this practice and analyzed its positive effects on agricultural productivity and resource efficiency. Organic farming was examined in ten articles, indicating a growing interest in this sustainable cultivation method. The results of these studies highlighted the benefits of organic farming in terms of soil conservation, biodiversity promotion, and improved food quality. Regenerative agriculture was discussed in thirteen articles, demonstrating the growing attention towards this practice aimed at restoring and enhancing the health of agricultural ecosystems. Studies on agroecology, on the other hand, amounted to twelve, revealing significant interest in integrating ecological and social principles into agricultural practices.
The analysis of the selected studies in this SLR has shown that there are no particular factors influencing the adoption of one type of innovation over another. However, an attempt was made to summarize key factors that could help farmers adopt specific practices for each type of innovation. Table 3 below summarizes the results.
It has been found that the adoption of sustainable agricultural practices is facilitated by some common elements that play a crucial role in promoting change. Education serves as a fundamental starting point by providing in-depth information about specific practices and their benefits. This type of training enables farmers to understand the scientific rationale and positive impacts of sustainable practices. Similarly, technical support is equally important as farmers require hands-on assistance in implementing practices correctly. Expert consultants can provide personalized advice, helping farmers overcome technical challenges and optimize crop management strategies. Furthermore, economic incentives play a key role in motivating farmers to transition to sustainable practices. Subsidies, favorable financing, or tax incentives can reduce initial costs and mitigate financial risks associated with the transition. These incentives provide a financial boost and are an important encouragement for farmers to adopt sustainable practices. The networking structure is another important factor. Interaction and collaboration among farmers, experts, organizations, and research institutions facilitate the exchange of knowledge and mutual learning. Sharing best practices, experiences, and challenges allows farmers to benefit from the expertise of others and adopt more effective approaches. In addition to these elements, adaptation and reinvention are necessary. Sustainable practices require a flexible approach tailored to the specificities of individual farms and different regions. Farmers need to be willing to experiment with new methods, integrate traditional knowledge with innovations, and modify their existing practices to achieve more sustainable outcomes.
Lastly, continuous education is essential in this context. The agricultural sector is constantly evolving, with new scientific discoveries, technologies, and practices emerging regularly. Farmers need to stay informed about the latest trends and update their skills to adopt the best available solutions.
Research agenda
The results of the present SLR highlighted that scholars have detected several core factors influencing the adoption of sustainable innovations among farmers, including innovation characteristics, various socio-demographic and psychological features of farmers, and some contextual elements in which farms operate. Nevertheless, it is clear that this topic has not been completely probed, and there exist some under-explored research areas that require further investigation. Firstly, new studies should aim to investigate farmers’ innovation adoption detecting contextual, psychographic, and socio-demographic characteristics together with innovation-specific features, providing a detailed picture of the factor enabling/hindering innovation adoption, and offering practical insights tailored to distinct typologies of innovation.
Secondly, from a methodological point of view, studies on the subject should be based on established theories or models. Indeed, in the current review, only 19 out of 44 analyzed studies referred to a theoretical model or theory. The literature points to multiple models and theories, and it would be wise to always choose the most appropriate one with respect to the intended goal. Third, future research should aim to achieve greater external and internal validity by involving larger/representative samples of farmers (since almost all studies have relied on limited convenience samples) and applying robust and transparent (and thus replicable) data collection methodologies typical of experimental studies. However, it should be kept in mind that this is quite difficult to do practically, and that the accuracy and reliability of the work also depend heavily on the theoretical models used and from the context of reference. Configurational theory suggests that there is no single path to pursue in implementing sustainable innovations, as there are infinite combinations of factors. In this view, researchers can reduce the possibility of reaching erroneous conclusions by formulating a priori hypotheses that can be pursued in multiple ways and by assessing the sensitivity of study conclusions to bias of varying degrees.
Concerning internal validity, scholars should apply validated data collection methods based on efficient designs and robust data quality control. Finally, data collection procedures (including all variables collected and exact protocols applied) should be fully disclosed in future studies, allowing researchers to replicate the analysis and effectively extend previous results.
Analyzing in detail the results of this SLR, some general considerations can be performed.
Firstly, a low number of studies have considered the socio-demographic characteristics of farmers as factors affecting the adoption of sustainable innovations. Moreover, when these factors were examined, the results were inconsistent. For example, Nastis et al. (2019) investigated the role of older farmers and, consequently, their years of experience on the farm as an important factor affecting the individuals’ innovation adoption strategies. On the contrary, Barnes et al. (2019) found that younger farmers are more likely to adopt innovations due to a greater adaptive capacity to new technologies. Similarly, regarding the sex at birth variable, Aznar-Sánchez et al. (2020) revealed that being female encourages the adoption of innovative practices since women are more predisposed to collaboration with the farm team and/or other farms and companies of the sector. On the other hand, Thorsøe et al. (2019) found that men are more favorable to the adoption of innovations. Furthermore, many of the studies detected in the current review highlighted that educational background is a significant predictor of innovation adoption (Nastis et al. 2019; Mishra et al. 2018; Sassenrath et al. 2010) as it contributes to increasing self-confidence. In contrast with these findings, Barnes et al. (2019) found no effect on educational status. These conflicting results do not allow to depict a clear picture of the socio-demographic characteristics of the adopter. Therefore, to overcome these limitations of the literature, future research must further investigate whether age, gender, and educational status affect the process of innovation adoption into the farm. This finding could be of significant interest for policymakers to build specific incentives to foster the adoption of innovations in the agricultural sector.
Moreover, as emphasized in our results, few studies have studied the role of contextual factors in affecting sustainable innovation adoption. This is an important shortcoming in the literature as today it is essential for farms to develop open innovation strategies to be effectively competitive in the current, dynamic marketplace. Open innovation can lead to a balance between productivity and sustainability (Chesbrough 2003). Indeed, it has been shown that to facilitate the adoption of sustainable innovative practices, companies must collaborate and integrate their knowledge with external sources (Stefan and Bengtsson 2017). Thus, future research should consider the importance of cooperation, as a strategic element for farmers’ innovation adoption, both within the team and with other farms and organizations operating in the same field of interest, by emphasizing the potential benefits of cooperation and its different avenues.
Furthermore, regarding the types of innovation identified in this systematic literature review, it can be stated that all four agricultural approaches have demonstrated significant importance in terms of reducing environmental impact. For each of these approaches, it has been possible to provide a brief guide on the aspects to consider in order to assist farmers in innovating. These factors include education and information on sustainable approaches, financial support, access to specific resources and technical assistance for each practice, as well as collaboration and knowledge exchange among farmers.
Finally, we underline that it was surprising to note that only 10 articles analyzed innovation in organic agriculture. Organic agriculture has been at the forefront of the agricultural revolution in recent years. It is considered a priority by the European Union, primarily due to the significant impact of the agri-food sector in terms of CO2 emissions and soil pollution. As a result, its implementation is among the objectives of the European Green Deal, which aims to gradually lead the continent towards climate neutrality. Therefore, it is crucial to promote further research on innovation in organic agriculture in order to effectively address environmental challenges and achieve sustainability goals.
Organic agriculture requires a constant commitment from farmers. It represents what the literature on innovations might define as a “radical innovation” (Dosi 1988): an almost total break with the knowledge networks of the productive paradigm, replaced by completely new and revolutionary techniques (Morgan and Murdoch 2000). The process of transitioning to sustainability requires farmers to set aside much of the knowledge they have acquired in intensive production and acquire new knowledge (Morgan and Murdoch 2000). In this process, the development of open innovation becomes essential. It is not surprising, therefore, that researchers have found that a lack of knowledge is one of the main obstacles to farmers’ sustainable conversion (Padel 1994). Hence, it would be interesting to explore whether, in addition to stronger environmental values, there are further differences between farmers who are open to innovation and those who are not, concerning socio-demographic characteristics or teamwork skills, for example. Consequently, it is suggested that prospective studies analyze this topic in greater detail to better define possible differences in the adoption process of sustainable innovations.
Conclusions
The current review provided a twofold result: first, the different factors that have an important role in explaining the adoption of product and process innovations by farmers were detected. Second, the methodological gaps among the available studies were highlighted to provide actionable directions for future studies.
Furthermore, findings confirmed that innovation adoption is influenced by multiple factors of various natures that interact with each other during the adoption process and therefore cannot be considered individually. Subsequently, suggestions were formulated for the implementation of more internally and externally robust studies, resulting from a detailed analysis of existing methodological gaps in the investigated documents.
However, despite the relevance of the results, some limitations of the present SLR need to be highlighted. The first limitation deals with the nature of the review. Indeed, although the procedure is systematic, it must be assumed that, having to replicate this work, another group of researchers may give importance to the details that were overlooked in this SLR. A further limitation of this study lies in choosing to use only scientific articles and excluding all other documents (such as books and gray literature). Additionally, it is possible that valuable studies were published on platforms other than Scopus and Web of Science, despite their recognized value and dissemination in the international scientific community. Potentially interesting research may also not have been filtered as it might not have carried the specific search key terms in the text. In addition, the current review included only research performed in developed countries totally overlooking insights from developing nations. However, it should be remembered that these are characteristics of most SLRs and depend, as Paul and Criado (2020) pointed out, on the subjective component intrinsic to the literature review process. Finally, the nature of the studies analyzed did not allow a thorough investigation of the interactions among the various factors influencing the innovation process. In this study we simply investigate which variables influence farmers’ choices; nevertheless, it would be greatly valuable to investigate the relations among factors in further studies. In addition, future research might use different theoretical models and methodologies or might investigate one specific agricultural sector (or compare results across sectors), where farmers are more/less prone to innovations.
Despite these limitations, theoretical, methodological, and practical implications can be drawn from the work. From a theoretical point of view, these findings try to overcome the existing gaps of the literature, which is rather fragmented and incomplete especially regarding the organic farming sector, by providing a complete set of determinants useful to create a general picture of the factors affecting farmers’ innovations adoption. Relatedly, it is important to note that, as Greenhalgh et al. (2004) pointed out, many factors may simultaneously intervene in affecting farmers’ behavior; therefore, both socio-demographic, psychological, and contextual factors need to be considered complementary to each other. Current findings could indeed be a useful guideline for scholars who intend to approach new research in the domain of farmers’ innovation adoption behavior. Notwithstanding, however, there are several alternative robust theoretical models available. At the methodological level, the current SLR provides several practical insights on possible patterns scholars can follow to perform new empirical studies with higher levels of internal and external validity.
Finally, policymakers can take several actions to promote the adoption of sustainable practices. This includes investing in agricultural education to provide targeted training programs that raise awareness, develop technical skills, and enhance understanding of the challenges and opportunities associated with sustainable practices. It is also crucial to provide farmers with adequate technical support by establishing mechanisms that grant access to specialized consultants and industry professionals. Financial incentives, such as grants and tax incentives, can help reduce costs and barriers related to the adoption of sustainable practices. Moreover, policymakers should encourage knowledge sharing and collaboration among farmers to facilitate mutual learning and the dissemination of practical information. Implementing awareness and outreach policies through communication campaigns and promoting successful models of sustainable agriculture can increase awareness among farmers and the general public about the benefits of sustainable practices in addressing environmental and social challenges.
At a practical level, current results provide insights contributing to the ongoing policy debate on the most effective measures to foster sustainable innovation adoption among farmers in developed countries. Truly understanding the factors influencing farmer decision-making would allow for the development of more appropriate and effective agri-environmental policies, as policy interventions based on incomplete information may be insufficient to reduce the negative environmental externalities of agriculture. This may be the case with European CAP, which, relying primarily on traditional policy instruments that do not deepen farmer decision-making understanding, has had a mixed record in achieving environmental goals (Eurostat 2018). Therefore, excluding some factors can lead to unrealistic ex-ante policy assessments. Current outcomes could help policy institutions to better target specific interventions to farmers’ individual characteristics and farms’ needs to promote a wider diffusion of sustainable innovations and thus achieve the United Nations Sustainable Development Goals 2030 (FAO 2016).
References
Ajzen I (1991) The theory of planned behavior. Organ Behav Hum Decis Process 50(2):179–211
Akimowicz M, Del Corso JP, Gallai N, Képhaliacos C (2021) Adopt to adapt? Farmers’ varietal innovation adoption in a context of climate change. The case of sunflower hybrids in France. J Clean Prod 279:123654
Al-Rahmi WM, Yahaya N, Aldraiweesh AA, Alamri MM, Aljarboa NA, Alturki U, Aljeraiwi AA (2019) Integrating technology acceptance model with innovation diffusion theory: an empirical investigation on students’ intention to use e-learning systems. IEEE Access - Inst Electr Electron Eng 7:26797–26809
Alves H, Fernandes C, Raposo M (2016) Social media marketing: a literature review and implications. Psychol Mark 33(12):1029–1038
Arbuckle JGJ, Morton LW, Hobbs J (2013) Understanding farmer perspectives on climate change adaptation and mitigation: the roles of trust in sources of climate information, climate change beliefs, and perceived risk. Environ Behav 47(2):205–234
Aubert BA, Schroeder A, Grimaudo J (2012) IT as enabler of sustainable farming: an empirical analysis of farmers’ adoption decision of precision agriculture technology. Decis Support Syst 54(1):510–520
Aznar-Sánchez JA, Velasco-Muñoz JF, López-Felices B, del Moral-Torres F (2020) Barriers and facilitators for adopting sustainable soil management practices in Mediterranean olive groves. Agronomy 10(4):506
Bakker L, Sok J, Van Der Werf W, Bianchi FJJA (2021) Kicking the habit: what makes and breaks farmers’ intentions to reduce pesticide use? Ecol Econ 180:106868
Barnes AP, Soto I, Eory V, Beck B, Balafoutis A, Sánchez B, Vangeyte S, van der Fountas T, Wal, and Gómez-Barbero M, (2019) Exploring the adoption of precision agricultural technologies: a cross regional study of EU farmers. Land use policy 80:163–174
Barreiro-Hurle J, Espinosa-Goded M, Martínez-Paz JM, Perni A (2018) Choosing not to choose: a meta-analysis of status quo effects in environmental valuations using choice experiments. Economia Agraria y Recursos Naturales – Agric Res Econ 18(1):79–109
Bechini L, Costamagna C, Zavattaro L, Grignani C, Bijttebier J, Ruysschaert G (2020) Drivers and barriers to adopt best management practices. Survey among Italian dairy farmers. J Clean Prod 245:118825
Bianchi MC, Bava L, Sandrucci A, Tangorra FM, Tamburini A, Gislon G, Zucali M (2022) Diffusion of precision livestock farming technologies in dairy cattle farms. Animal 16(11):100650
Bijttebier J, Ruysschaert G, Hijbeek R, Werner M, Pronk AA, Bechini Zavattaro L, Grignani C, ten Berge H, Marchand F, Wauters E (2018) Adoption of non-inversion tillage across Europe: use of a behavioural approach in understanding decision making of farmers. Land Use Policy 78:460–471
Bonke V, Musshoff O (2020) Understanding German farmer’s intention to adopt mixed cropping using the theory of planned behavior. Agronomy for Sustainable Development 40(6):1–14
Bonney L, Clark R, Collins R, Fearne A (2007) From serendipity to sustainable competitive advantage: insights from Houston’s farm and their journey of co-innovation. Supply Chain Manag: An Int J 12(6):395–399
Bordbar M (2014) Solutions for fast development of precision agriculture in Iran. Agric Eng Int CIGR J 16(3):119–123
Borgen SO, Aarset B (2016) Participatory innovation: lessons from breeding cooperatives. Agr Syst 145:99–105
Bravo-Monroy L, Potts SG, Tzanopoulos J (2016) Drivers influencing farmer decisions for adopting organic or conventional coffee management practices. Food policy 58:49–61
Caffaro F, Cavallo E (2019) The effects of individual variables, farming system characteristics and perceived barriers on actual use of smart farming technologies: evidence from the Piedmont region, northwestern Italy. Agriculture 9(5):111
Caffaro F, Roccato M, Micheletti Cremasco M, Cavallo E (2019) An ergonomic approach to sustainable development: the role of information environment and social-psychological variables in the adoption of agri-environmental innovations. Sustain Dev 27(6):1049–1062
Canaj K, Mehmeti A, Morrone D, Toma P, Todorović M (2021) Life cycle-based evaluation of environmental impacts and external costs of treated wastewater reuse for irrigation: a case study in southern Italy. J Clean Prod 293:126142
Chams N, García-Blandón J (2019) On the importance of sustainable human resource management for the adoption of sustainable development goals. Resour Conserv Recycl 141:109–122
Chesbrough HW (2003) Open innovation: the new imperative for creating and profiting from technology. Harvard Business Press, Boston, Massachusetts
Chiriacò MV, Grossi G, Castaldi S, Valentini R (2017) The contribution to climate change of the organic versus conventional wheat farming: a case study on the carbon footprint of wholemeal bread production in Italy. J Clean Prod 153:309–319
Cohen WM (2010) Fifty years of empirical studies of innovative activity and performance. In: Handbook of the Economics of Innovation, vol 1, North-Holland, pp 129–213
Creissen HE, Jones PJ, Tranter RB, Girling RD, Jess S, Burnett FJ, Gaffney M, Thorne FS, Kildea S (2021) Identifying the drivers and constraints to adoption of IPM among arable farmers in the UK and Ireland. Pest Manag Sci 77(9):4148–4158
Cullen P, Dupraz P, Moran J, Murphy P, O’Flaherty R, O’Donoghue C, O’Shea R, Ryan M (2018) Agri-environment scheme design: past lessons and future suggestions. EuroChoices 17(3):26–30
D’Amato A, Mazzanti M, Nicolli F (2021) Green technologies and environmental policies for sustainable development: testing direct and indirect impacts. J Clean Prod 309:127060
Dalla Corte VF, Dabdab Waquil P, Stiegert K (2015) Wheat industry: which factors influence innovation? J Technol Manag Innov 10(3):11–17
Damanpour F (2010) An integration of research findings of effects of firm size and market competition on product and process innovations. Br J Manag 21(4):996–1010
Damanpour F, Gopalakrishnan S (2001) The dynamics of the adoption of product and process innovations in organizations. J Manag Stud 38(1):45–65
David G, Irons TJ, Fouda AE, Furness JW, Teale AM (2021) Self-consistent field methods for excited states in strong magnetic fields: a comparison between energy-and variance-based approaches. J Chem Theory Comput 17(9):5492–5508
De Steur H, Temmerman H, Gellynck X, Canavari M (2020) Drivers, adoption, and evaluation of sustainability practices in Italian wine SMEs. Bus Strateg Environ 29(2):744–762
Dessart FJ, Barreiro-Hurlé J, van Bavel R (2019) Behavioural factors affecting the adoption of sustainable farming practices: a policy-oriented review. Eur Rev Agric Econ 46(3):417–471
Dosi G (1988) The nature of the innovative process. Technical change and economic theory. Pinter, London, pp 221–238
Eastwood C, Klerkx L, Nettle R (2017) Dynamics and distribution of public and private research and extension roles for technological innovation and diffusion: case studies of the implementation and adaptation of precision farming technologies. J Rural Stud 49:1–12
Eurostat (2018) Agri-environmental Indicators. Retrieved December 16, 2021, retrieved from http://ec.europa.eu/eurostat/web/agri-environmental-indicators
Feliciano D (2022) Factors influencing the adoption of sustainable agricultural practices: the case of seven horticultural farms in the United Kingdom. Scott Geogr J 138(3-4):291–320
Ferlie E, Gabbay J, Fitzgerald L, Locock L, Dopson S (2001) In: Ashburner L (ed) Evidence-based medicine and organisational change: an overview of some recent qualitative research. Organisational behaviour and organisational studies in health care: Reflections on the future, Palgrave Macmillan, pp 18–42
Ferreira APAL, de Oliveira L, Talamini E (2022) Land use returns in organic and conventional farming systems: financial and beyond. Org Agric 12(3):353–371
Finger R, Möhring N (2022) The adoption of pesticide-free wheat production and farmers’ perceptions of its environmental and health effects. Ecol Econ 198:107463
Fiss PC, Marx A, Cambré B (2013) Configurational theory and methods in organizational research: introduction. Emerald Group Publishing Limited, In Configurational theory and methods in organizational research
Foguesatto CR, Borges JAR, Machado JAD (2020) A review and some reflections on farmers’ adoption of sustainable agricultural practices worldwide. Sci Total Environ 729:138831
Food FAO (2016) Agriculture: key to achieving the 2030 agenda for sustainable development. Food and Agriculture Organization of the United Nations, Rome
Fu X, Gong Y (2011) Indigenous and foreign innovation efforts and drivers of technological upgrading: evidence from China. World Dev 39:1213–1225
Furnari S, Crilly D, Misangyi VF, Greckhamer T, Fiss PC, Aguilera RV (2021) Capturing causal complexity: heuristics for configurational theorizing. Acad Manage Rev 46(4):778–799
Fürstenau D, Rothe H, Sandner M (2021) Leaving the shadow: a configurational approach to explain post-identification outcomes of shadow IT systems. Bus Inf Syst Eng 63:97–111
García-Cortijo MC, Castillo-Valero JS, Carrasco I (2019) Innovation in rural Spain. What drives innovation in the rural-peripheral areas of southern Europe? J Rural Stud 71:114–124
Gatewood EJ, Shaver KG, Gartner WB (1995) A longitudinal study of cognitive factors influencing start-up behaviors and success at venture creation. J Bus Ventur 10(5):371–391
Gaziulusoy A (2010) System innovation for sustainability: a scenario method and a workshop process for product development teams (Doctoral dissertation, ResearchSpace@ Auckland)
George JM, Zhou J (2001) When openness to experience and conscientiousness are related to creative behavior: an interactional approach. J Appl Psychol 86(3):513–524
Ghadge A, Er Kara M, Mogale DG, Choudhary S, Dani S (2020) Sustainability implementation challenges in food supply chains: a case of UK artisan cheese producers. Prod Plan Control 32(14):1191–1206
Gosling E, Williams KJH (2010) Connectedness to nature, place attachment and conservation behaviour: testing connectedness theory among farmers. J Environ Psychol 30(3):298–304
Greenhalgh T, Robert G, Macfarlane F, Bate P, Kyriakidou O (2004) Diffusion of innovations in service organizations: systematic review and recommendations. Milbank Q 82(4):581–629
Greiner R (2015) Motivations and attitudes influence farmers’ willingness to participate in biodiversity conservation contracts. Agr Syst 137:154–165
Greiner R, Gregg D (2011) Farmers’ intrinsic motivations, barriers to the adoption of conservation practices and effectiveness of policy instruments: empirical evidence from northern Australia. Land Use Policy 28(1):257–265
Groth-Joynt TM, Curtis A, Mendham E, Toman E (2020) Does rural landowner identity shape the adoption of sustainable farming practices? Australasian J Environ Manag 27(3):309–328
Guerin TF (2001) Why sustainable innovations are not always adopted. Resour Conserv Recycl 34(1):1–18
Gupta H, Kusi-Sarpong S, Rezaei J (2020) Barriers and overcoming strategies to supply chain sustainability innovation. Resour Conserv Recycl 161:104819
Gütschow M, Bartkowski B, Felipe-Lucia MR (2021) Farmers’ action space to adopt sustainable practices: a study of arable farming in Saxony. Reg Environ Chang 21(4):1–16
Hellerstein D, Higgins N, Horowitz J (2013) The predictive power of risk preference measures for farming decisions. Eur Rev Agric Econ 40(5):807–833
Hernandez-Vivanco A, Bernardo M, Cruz-Cázares C (2018) Sustainable innovation through management systems integration. J Clean Prod 196:1176–1187
Jack C, Hotchkiss E, Sargison ND, Toma L, Milne C, Bartley DJ (2022) Determining the influence of socio-psychological factors on the adoption of individual ‘best practice’ parasite control behaviours from Scottish sheep farmers. Prev Vet Med 200:105594
Joachim S (2006) Review of history and recent development of organic farming worldwide. Agric Sci China 5(3):169–178
Kallas Z, Serra T, Gil JM (2010) Farmers’ objectives as determinants of organic farming adoption: the case of Catalonian vineyard production. Agric Econ 41(5):409–423
Kernecker M, Knierim A, Wurbs A, Kraus T, Borges F (2019) Experience versus expectation: farmers’ perceptions of smart farming technologies for cropping systems across Europe. Precis Agric 21:34–50
Knutson CL, Haigh T, Hayes MJ, Widhalm M, Nothwehr J, Kleinschmidt M, Graf L (2011) Farmer perceptions of sustainable agriculture practices and drought risk reduction in Nebraska, USA. Renewable Agric Food Syst 26(3):255–266
Koundouri P, Laukkanen M, Myyrä S, Nauges C (2009) The effects of EU agricultural policy changes on farmers’ risk attitudes. Eur Rev Agric Econ 36(1):53–77
Krueger NF and Kickul J (2006) So you thought the intentions model was simple? Cognitive style and the specification of entrepreneurial intentions models. (January 24, 2006)
Krueger NFand Carsrud AL (1993) Entrepreneurial intentions: applying the theory of planned behaviour. Entrep Reg Dev 5(4):315–330
Kuepper G (2010) A brief overview of the history and philosophy of organic agriculture. In: Kerr Center for Sustainable Agriculture. Poteau, OK
Laurett R, Paço A, Mainardes EW (2021) Antecedents and consequences of sustainable development in agriculture and the moderator role of the barriers: proposal and test of a structural model. J Rural Stud 86:270–281
Lawrence JE, Tar UA (2018) Factors that influence teachers’ adoption and integration of ICT in teaching/learning process. Educ Media Int 55(1):79–105
Lee HJ, Yun ZS (2015) Consumers’ perceptions of organic food attributes and cognitive and affective attitudes as determinants of their purchase intentions toward organic food. Food Qual Prefer 39:259–267
Li D, Zheng M, Cao C, Chen X, Ren S, Huang M (2017) The impact of legitimacy pressure and corporate profitability on green innovation: evidence from China top 100. J Clean Prod 141:41–49
Lindblom J, Lundström C, Ljung M, Jonsson A (2017) Promoting sustainable intensification in precision agriculture: review of decision support systems development and strategies. Precis Agric 18(3):309–331
Long TB, Blok V, Coninx I (2016) Barriers to the adoption and diffusion of technological innovations for climate-smart agriculture in Europe: evidence from the Netherlands, France, Switzerland and Italy. J Clean Prod 112:9–21
MacRae RJ, Hill SB, Mehuys GR, Henning J (1990) Farm-scale agronomic and economic conversion from conventional to sustainable agriculture. Adv Agron 43:155–198
Manta F, Morrone D, Toma P, Campobasso F (2022) Determining paths of innovation: the role of culture on the adoption on organic farming management. Bus Strateg Environ 32(1):96–109
Mase AS, Gramig BM, Prokopy LS (2017) Climate change beliefs, risk perceptions, and adaptation behavior among Midwestern US crop farmers. Clim Risk Manag 15:8–17
Meyer AD, Tsui AS, Hinings CR (1993) Configurational approaches to organizational analysis. Acad Manage J 36(6):1175–1195
Mills J, Ingram J, Dibari C, Merante P, Karaczun Z, Molnar A et al (2020) Barriers to and opportunities for the uptake of soil carbon management practices in European sustainable agricultural production. Agroecol Sustain Food Syst 44(9):1185–1211
Mishra B, Gyawali BR, Paudel KP, Poudyal NC, Simon MF, Dasgupta S, Antonious G (2018) Adoption of sustainable agriculture practices among farmers in Kentucky, USA. Environ Manag 62(6):1060–1072
Morgan K, Murdoch J (2000) Organic vs. conventional agriculture: knowledge, power and innovation in the food chain. Geoforum 31(2):159–173
Muzira DR, Bondai BM (2020) Perception of educators towards the adoption of education 5.0: a case of a State University in Zimbabwe. East African J Educ Soc Sci (EAJESS) 1(2):43–53
Nastis SA, Mattas K, Baourakis G (2019) Understanding farmers’ behavior towards sustainable practices and their perceptions of risk. Sustainability 11(5):1303
Ndaba B, Roopnarain A, Haripriya RAMA, Maaza M (2022) Biosynthesized metallic nanoparticles as fertilizers: an emerging precision agriculture strategy. J Integr Agric 21(5):1225–1242
Newton P, Civita N, Frankel-Goldwater L, Bartel K, Johns C (2020) What is regenerative agriculture? A review of scholar and practitioner definitions based on processes and outcomes. Front Sustain Food Syst 4:194
Niggli U, Andres C, Willer H, Baker BP (2017) Building a global platform for organic farming research, innovation and technology transfer. Org Agric 7(3):209–224
Padel S (1994) Adoption of organic farming as an example of the diffusion of an innovation. Centre for Organic Husbandry and Agroecology, Discussion Paper Series 94/1, University of Wales, Aberystwyth
Page MJ, McKenzie JE, Bossuyt PM, Boutron I, Hoffmann TC, Mulrow CD (2021) PRISMA statement: an updated guideline for reporting systematic reviews. Br Med J 372(71):1–9
Pannell DJ, Marshall GR, Barr N, Curtis A, Vanclay F, Wilkinson R (2006) Understanding and promoting adoption of conservation practices by rural landholders. Aust J Exp Agric 46(11):1407–1424
Pati D, Lorusso LN (2018) How to write a systematic review of the literature. HERD: Health Environ Res Des J 11(1):15–30
Paul J, Criado AR (2020) The art of writing literature review: what do we know and what do we need to know? Int Bus Rev 29(4):101717
Payen FT, Moran D, Cahurel JY, Aitkenhead M, Alexander P, MacLeod M (2022) Factors influencing winegrowers’ adoption of soil organic carbon sequestration practices in France. Environ Sci Policy 128:45–55
Pépin A, Morel K, van der Werf HM (2021) Conventionalised vs. agroecological practices on organic vegetable farms: investigating the influence of farm structure in a bifurcation perspective. Agric Syst 190:103129
Pierpaoli E, Carli G, Pignatti E, Canavari M (2013) Drivers of precision agriculture technologies adoption: a literature review. Procedia Technol 8:61–69
Piñeiro V, Arias J, Dürr J, Elverdin P, Ibáñez AM, Kinengyere A, Opazo CM, Owoo N, Page JR, Prager SD, Torero M (2020) A scoping review on incentives for adoption of sustainable agricultural practices and their outcomes. Nat Sustain 3(10):809–820
Ploll U, Arato M, Börner J, Hartmann M (2022) Sustainable innovations: a qualitative study on farmers’ perceptions driving the diffusion of beneficial soil microbes in Germany and the UK. Sustain 14(10):5749
Price JC, Leviston Z (2014) Predicting pro-environmental agricultural practices: the social, psychological and contextual influences on land management. J Rural Stud 34:65–78
Rochecouste JF, Dargusch P, Donald C, Smith C (2015) An analysis of the socio-economic factors influencing the adoption of conservation agriculture as a climate change mitigation activity in Australian dryland grain production. Agr Syst 135:20–30
Rogers EM (1995) Diffusion of innovations, 4th edn. The free Press, New York
Rosenbusch N, Brinckmann J, Bausch A (2011) Is innovation always beneficial? A meta-analysis of the relationship between innovation and performance in SMEs. J Bus Ventur 26(4):441–457
Sachet E, Mertz O, Le Coq JF, Cruz-Garcia GS, Francesconi W, Bonin M, Quintero M (2021) Agroecological transitions: a systematic review of research approaches and prospects for participatory action methods. Front Sustain Food Syst 5:709401
Sassenrath GF, Halloran JM, Archer D, Raper RL, Hendrickson J, Vadas P, Hanson J (2010) Drivers impacting the adoption of sustainable agricultural management practices and production systems of the northeast and southeast United States. J Sustain Agric 34(6):680–702
Schulz N, Breustedt G, Latacz-Lohmann U (2014) Assessing farmers’ willingness to accept ‘greening’: insights from a discrete choice experiment in Germany. J Agric Econ 65(1):26–48
Serebrennikov D, Thorne F, Kallas Z, McCarthy SN (2020) Factors influencing adoption of sustainable farming practices in Europe: a systemic review of empirical literature. Sustainability 12(22):9719
Shane S, Venkataraman S (2000) The promise of entrepreneurship as a field of research. Acad Manage Rev 25(1):217–226
Siepmann L, Nicholas KA (2018) German winegrowers’ motives and barriers to convert to organic farming. Sustainability 10(11):4215
Stefan I, Bengtsson L (2017) Unravelling appropriability mechanisms and openness depth effects on firm performance across stages in the innovation process. Technol Forecast Soc Chang 120:252–260
Tey YS, Brindal M (2012) Factors influencing the adoption of precision agricultural technologies: a review for policy implication. Precis Agric 13:713–730
Thorsøe MH, Noe EB, Lamandé M, Frelih-Larsen A, Kjeldsen C, Zandersen M, Schjønning P (2019) Sustainable soil management-farmers’ perspectives on subsoil compaction and the opportunities and barriers for intervention. Land Use Policy 86:427–437
Torraco RJ (2005) Writing integrative literature reviews: guidelines and examples. Hum Resour Dev Rev 4(3):356–367
Tóth J, Migliore G, Balogh JM, Rizzo G (2020) Exploring innovation adoption behavior for sustainable development: the case of Hungarian food sector. Agronomy 10(4):612
Trujillo-Barrera A, Pennings JM, Hofenk D (2016) Understanding producers’ motives for adopting sustainable practices: the role of expected rewards, risk perception and risk tolerance. Eur Rev Agric Econ 43(3):359–382
Tummers J, Kassahun A, Tekinerdogan B (2019) Obstacles and features of farm management information systems: a systematic literature review. Comput Electron Agric 157:189–204
van Dinter R, Tekinerdogan B, Catal C (2021) Automation of systematic literature reviews: a systematic literature review. Inf Softw Technol 136:106589
Vecchio Y, De Rosa M, Adinolfi F, Bartoli L, Masi M (2020) Adoption of precision farming tools: a context-related analysis. Land Use Policy 94:104481
Verburg RW, Verberne E and Negro SO (2022) Accelerating the transition towards sustainable agriculture: The case of organic dairy farming in the Netherlands. Agric Syst 198:103368
Vezina M, Malo MC, Ben Selma M (2017) Mature social economy enterprise and social innovation: the case of the Desjardins environmental fund. Annals Public Coop Econ 88(2):257–278
Wauters E, Bielders C, Poesen J, Govers G, Mathijs E (2010) Adoption of soil conservation practices in Belgium: an examination of the theory of planned behaviour in the agri-environmental domain. Land Use Policy 27(1):86–94
Xie X, Huo J, Zou H (2019) Green process innovation, green product innovation, and corporate financial performance: a content analysis method. J Bus Res 101:697–706
Zanello G, Fu X, Mohnen P, Ventresca M (2016) The creation and diffusion of innovation in developing countries: a systematic literature review. J Econ Surv 30(5):884–912
Zeweld W, Van Huylenbroeck G, Tesfay G, Azadi H, Speelman S (2018) Impacts of socio-psychological factors on actual adoption of sustainable land management practices in dryland and water stressed areas. Sustainability 10(9):2963
Zeweld W, Van Huylenbroeck G, Tesfay G, Speelman S (2017) Smallholder farmers’ behavioural intentions towards sustainable agricultural practices. J Environ Manage 187:71–81
Zulfiqar F, Thapa GB (2018) Determinants and intensity of adoption of ‘better cotton’ as an innovative cleaner production alternative. J Clean Prod 172:3468–3478
Funding
Open access funding provided by Università degli Studi di Palermo within the CRUI-CARE Agreement. This research is a part of the BioDegraPack project, funded by the Italian Ministry of Agricultural, Food, Forestry and Tourism Policies (MIPAAF).
Author information
Authors and Affiliations
Contributions
Conceptualization: Giuseppina Migliore and Riccardo Vecchio; methodology: Riccardo Vecchio; investigation: Giuseppina Rizzo, Giuseppina Migliore, and Giorgio Schifani; writing original draft: Giuseppina Rizzo; writing—review and editing: Giuseppina Migliore and Riccardo Vecchio; data curation: Giuseppina Rizzo; visualization: Giorgio Schifani; supervision: Riccardo Vecchio
Corresponding author
Ethics declarations
Conflict of interest
The authors declare no competing interests.
Open Practices Statements
The data for all experiments are available via the Open Science Framework at https://osf.io/c6bpy/, and none of the experiments was preregistered.
Additional information
Publisher’s note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Appendix
Appendix
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Rizzo, G., Migliore, G., Schifani, G. et al. Key factors influencing farmers’ adoption of sustainable innovations: a systematic literature review and research agenda. Org. Agr. 14, 57–84 (2024). https://doi.org/10.1007/s13165-023-00440-7
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13165-023-00440-7