Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-22T19:18:15.090Z Has data issue: false hasContentIssue false

Beyond skills and knowledge: the role of self-efficacy and peer networks in building capacity for species conservation planning

Published online by Cambridge University Press:  31 May 2022

Brett L. Bruyere*
Affiliation:
Colorado State University, Campus Delivery 1480, Fort Collins, CO 80523, USA
Jamieson Copsey
Affiliation:
IUCN, Apple Valley, USA
Sarah E. Walker
Affiliation:
Colorado State University, Campus Delivery 1480, Fort Collins, CO 80523, USA
*
(Corresponding author, [email protected])

Abstract

Biodiversity loss is one of the greatest global challenges and requires substantial investment in building the capacity of conservation professionals to design and implement robust conservation plans. In this study, we surveyed 155 past participants of training in facilitating species conservation planning processes given by the Conservation Planning Specialist Group of the IUCN Species Survival Commission. Based on a recently developed theory of change for the training, we examined how and to what extent the training contributed to the desired outcome of increasing trainees’ capacity for leading the design and facilitation of species conservation planning processes. Our results indicate that recall of training content, self-efficacy (an individual's belief they can complete a specific task or behaviour successfully) and peer network participation had significant impacts on the outcome of applying training content in the workplace. Furthermore, our results suggest that self-efficacy played a highly influential role in trainees' participation in species conservation planning post-training. The implications of this research point to designing conservation training that considers not only the skills and knowledge to be gained by learners but also the strategies that enhance trainees' self-efficacy in applying new skills and knowledge and in establishing peer networks to support trainees in turning training objectives into realities.

Type
Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of Fauna & Flora International

Introduction

Greater investment in capacity building for conservation is widely accepted as critical for limiting species loss globally (Rodriguez et al., Reference Rodríguez, Rodríguez-Clark, Oliveira-Miranda, Good and Grajal2006; Elliott et al., Reference Elliott, Ryan and Wyborn2018). This points to a need for capacity-building programmes that link conservation efforts to positive changes in the status of species and systems. However, capacity-building providers often lack clarity and evidence regarding how their training will influence their participants and lead to desired outcomes and impacts (Sawrey et al., Reference Sawrey, Copsey and Milner-Gulland2017). To date, much focus has been placed on measuring the outputs of training activities (e.g. numbers of people trained from different countries or organizations) and less attention has been given to how these outputs lay the groundwork for desired longer-term outcomes or impacts. A useful starting point for rethinking this journey is the development of a theory of change (Taplin et al., Reference Taplin, Clark, Collins and Colby2013) that provides a conceptual overview of the hypothesized causal steps involved in moving from the implementation of some form of capacity-building intervention (e.g. a training course) through to a desired end point (e.g. the recovery of a species).

A theory of change model is at best a coarse approximation of a much more complex truth. In other words, ‘all models are wrong, but some are useful’ (Box & Draper, Reference Box and Draper1987, p. 424). By enabling us to begin to give shape to the change that we envisage a training intervention will achieve, theories of change provide the framework by which we can monitor realities, evaluate outcomes and learn and adapt accordingly. A theory of change helps bridge the gap to previous capacity-building approaches, helping us understand how a particular activity leads to desired long-term impacts. Between the inputs and impacts are a sequence of events and outcomes that are imperative to the process but often undefined or undescribed (Taplin et al., Reference Taplin, Clark, Collins and Colby2013). A theory of change is typically developed by defining the desired impact and then working backwards to define the conditions that must exist for the desired impact to come to fruition (Taplin & Clark, Reference Taplin and Clark2012).

A number of fields, including international development and public health, have long been at the forefront of utilizing a theory of change approach (Vogel, Reference Vogel2012; Valters, Reference Valters2014). More recently, conservation actors have adopted this approach; e.g. The Nature Conservancy's Conservation by Design framework and the Conservation Measures Partnership's Open Standards for the Practice of Conservation. In research, theory of change approaches have been documented in conservation, including in illegal wildlife trade (Biggs et al., Reference Biggs, Conney, Roe, Dublin, Allan, Challender and Skinner2016), conservation and development models (Salafsky, Reference Salafsky2011) and conservation impacts on human well-being (Bottrill et al., Reference Bottrill, Cheng, Garside, Wongbusarakum, Roe and Holland2014). Others have advocated for the importance of similar theory of change approaches in conservation, albeit sometimes using different names such as ‘results chain’ (Margoluis et al., Reference Margoluis, Stem, Swaminathan, Brown, Johnson and Placci2013).

Typically, the desired long-term outcome of many conservation training programmes is that participants learn and then apply new knowledge and skills. Research into the effectiveness of training for gaining new knowledge and skills within conservation is both prevalent and favourable, such as training to build capacity for conservation decision-making (e.g. Johnson et al., Reference Johnson, Eaton, Williams, Jensen and Madsen2015), planning and adaptive management (Redford et al., Reference Redford, Hulvey, Williamson and Schwartz2018) and interdisciplinary thinking (Welch-Devine et al., Reference Welch-Devine, Hardy, Brosius and Heynen2014).

A body of conservation research exists that specifically emphasizes the value of skills and knowledge in collaborative processes and stakeholder engagement, which points to the importance of training on these topics. For example, one study found that stakeholder engagement was a common element amongst successful marine protected area management initiatives, and its omission was a common factor in marine protected area failure (Giakoumi et al., Reference Giakoumi, McGowan, Mills, Beger, Bustamante and Charles2018). Similarly, in a review of 136 community-based conservation projects, local stakeholder participation and capacity were two of only a few factors that strongly influenced the success (or failure) of community-based conservation projects (Brooks, Reference Brooks2016). Specifically, within the discipline of species conservation planning, stakeholder-inclusive approaches to planning can create pivot points for threatened species, facilitating more effective collaborative work (Lees et al., Reference Lees, Rutschmann, Santure and Beggs2021). However, a focus on learning new skills and knowledge such as the ‘how to’ of stakeholder engagement is often not sufficient on its own for the transfer of training to real-world practice (Chauhan et al., Reference Chauhan, Ghosh, Rai and Kapoor2017; Na-nan et al., Reference Na-nan, Chaiprasit and Pukkeeree2017). Further study is needed to better understand the factors that enable individuals to apply new capacities in conservation.

One factor that is known to influence an individual's likelihood to apply new skills and knowledge is self-efficacy. Self-efficacy is an individual's belief that they can complete a specific task or behaviour successfully (Bandura, Reference Bandura, Weiner and Craighead2010), and is linked to a number of performance characteristics, including engagement (Carter et al., Reference Carter, Nesbit, Badham and Parker2016), motivation (Cherian & Jacob, Reference Cherian and Jacob2013), intention to apply new learning (Al-Eisa et al., Reference Al-Eisa, Furayyan and Alhemoud2009) and persistence with difficult tasks (Lunenburg, Reference Lunenburg2011). It is distinct from similar constructs such as self-confidence or self-esteem in that self-efficacy is specific to a behaviour and/or circumstance. Self-efficacy is built through performing a behaviour successfully, observing others perform the behaviour, social persuasion that one has the capabilities for success and a personal interpretation of the emotional states associated with the behaviour (Bandura, Reference Bandura, Weiner and Craighead2010). Within conservation, the number of studies of self-efficacy is limited compared to other sectors. A 2020 study of rural Minnesotan farmers noted that low self-efficacy contributed to a lack of adopting conservation practices (Perry & Davenport, Reference Perry and Davenport2020). Similarly, a 2017 study of zoo visitors found that self-efficacy was a stronger predictor of intention to adopt behaviours that support biodiversity conservation compared to knowledge gain regarding biodiversity conservation (Clayton et al., Reference Clayton, Prévot, Germain and Saint-Jamie2017).

Another factor that is thought to play a role in the effectiveness of training programmes is engagement in peer networks, which are also referred to as learning networks or peer-to-peer networks. Much of what we know about the benefits of peer networks also comes from sectors other than conservation, although there are examples of how such networks enhance conservation practice (Pietri et al., Reference Pietri, Stevenson and Christie2015). Such networks typically consist of individuals from a common sector, connect members using technology that spans geographical locations (e.g. groups on social media or instant messaging platforms) and facilitate learning, discussion and the exchange of information (Bravo-Torres et al., Reference Bravo-Torres, Andrade-Rea, Vintimilla-Tapia, Ordóñez-Morales, López-Nores and Blanco-Fernández2017).

Studies of peer networks have concluded that networks can result in benefits such as further learning (Pietri et al., Reference Pietri, Stevenson and Christie2015), exploring ideas (Hur & Brush, Reference Hur and Brush2009), and increased job satisfaction (Veretennik & Kianto, Reference Veretennik and Kianto2019). However, they can also have unintended consequences, such as overestimating the frequency or intensity of a problem, but these consequences can be overcome with effective facilitation (Naegels et al., Reference Naegels, D'Espallier and Mori2020). Within conservation, studies of peer networks have noted the need for coordination and decentralized structures to promote exchange, as evidenced in a regional network in South-east Asia focused on coral reef conservation (Pietri et al., Reference Pietri, Stevenson and Christie2015).

Research question

Following our review of prior research and in the context of assessing the needs and questions of the Conservation Planning Specialist Group within IUCN, we evaluated numerous variables in the Conservation Planning Specialist Group's theory of change, including self-efficacy, peer networks and others. Overall, the purpose of this study was to determine the theory of change factors that contribute to the likelihood of training participants implementing species conservation planning activities.

Case study

Since 1979 the Conservation Planning Specialist Group (formerly the Captive Breeding Specialist Group) has worked to design and facilitate multi-stakeholder species conservation planning processes for governments, NGOs, zoos and other conservation groups worldwide. The organization is focused on ensuring that every species that needs a plan is addressed by an effective and implemented plan (Conservation Planning Specialist Group, 2020).

The Conservation Planning Specialist Group runs training courses (both in person and online) as one strategy to build capacity for species conservation planning. Doing this requires an understanding of the skills and knowledge that trainees need to develop, as well as the factors that increase the likelihood these individuals will go on to implement more effective planning. In 2019–2020, the Group revisited its capacity-building approach using guidance and analysis prompted by reframing its training around a theory of change. An initial theory of change was developed based largely on known previous inputs and outputs as well as desirable outcomes and impacts. This theory of change was then discussed with internal and external Conservation Planning Specialist Group stakeholders via a series of individual interviews. Following the discussions and a literature review, the theory of change was refined. The Group's theory of change includes four inputs, five outputs, four first-order outcomes, one second-order outcome and two impacts (Fig. 1).

Fig. 1 Theory of change for the Conservation Planning Specialist Group's capacity building to support trainees to lead the design and facilitation of species conservation planning processes.

Methods

The Conservation Planning Specialist Group is one of the thematic specialist groups of the IUCN Species Survival Commission. Its species conservation planning training has traditionally been delivered via a multi-day workshop-style format, with a combination of lectures, simulations and role-playing to facilitate stakeholder processes. In 2018, the Conservation Planning Specialist Group launched a 6-week online training course that includes a mix of pre-recorded lectures and individual activities/readings supplemented with real-time instruction and group discussion. Since 2018, > 700 conservation professionals have attended either the in-person or online versions of this training.

To evaluate the training we developed a 54-item online survey and measured four first-order outcomes from the theory of change (self-efficacy: six items; motivation: four items; knowledge of and skills in 12 training subjects, measured through self-reporting of their recall of the content; and application of the 12 subjects, measured as frequency of application). We also measured the one second-order outcome in the theory of change: the development of conservation plans. In addition, we asked about the establishment of a peer network following training, which is one of the theory of change's outputs, and about the perceived benefits of peer networks in general. We were also interested in participation in other conservation actions, and asked whether participants had engaged in any of 11 such activities. Finally, we asked respondents for basic demographic information such as gender, years working in conservation and years since their Conservation Planning Specialist Group training. See Table 1 and Supplementary Material 1 for survey items.

Table 1 Example survey items from the Conservation Planning Specialist Group survey of former training participants.

We measured many of the dependent variables using a scale approach in which we combined multiple survey items to measure a single construct. For example, we assessed self-efficacy using six items measured on a scale of 1 (strongly disagree) to 5 (strongly agree) that included statements such as ‘I can successfully perform many different tasks related to species conservation planning’ and ‘I have the skills to support others in working toward the species conservation planning goals.’ In addition, we reduced the training topics to three categories by combining four topics to create a communication index, three topics to create a stakeholder engagement index and two topics to create a technical planning skills index. We completed an internal consistency reliability analysis in these instances to assess the statistical rigour of these scales.

We compiled the sample using records from previous Conservation Planning Specialist Group courses conducted during 2015–2019. Record keeping was more robust for more recent years, skewing the sample towards participants from 2018 and thereafter. The total sample included 534 names and e-mail addresses of participants who had completed either the online or in-person training. Data collection occurred during a 30-day period in March and April 2020. The entire sample was e-mailed a notification from the Conservation Planning Specialist Group regarding the forthcoming survey, to encourage participation. An e-mail with the survey link was sent 1 week later. After 1 week a reminder was sent to non-respondents that included the survey link, followed by a final reminder 2 weeks later.

We used SPSS 26.0 (SPSS, Armonk, USA) for all analyses. Analyses included descriptive statistics, reliability of the three scales, (see above), linear regressions to analyse the predictive measures of the application of training skills (communication, stakeholder engagement and technical planning skills) and self-efficacy, and logistic regression to analyse the predictive measures of participation in species conservation planning.

Results

Thirty-two e-mail addresses were invalid and a small number of surveys were started but not sufficiently completed and were therefore excluded. Overall, 155 usable surveys were retained for analysis, giving a response rate from valid e-mail addresses of 30.9%. The responses included 58% females and 42% males, with varying years of conservation experience. Nearly 56% (55.8%) of respondents reported participation in species conservation planning at some point following their training. More than three quarters of respondents reported participation in a peer network (Table 2).

Table 2 Characteristics of the sample from a survey of Conservation Planning Specialist Group former training participants.

We created nine indices from the survey. The indices represent recall of three specific content areas of the training (communication, stakeholder engagement and technical conservation planning skills), frequency of applying each of the three specific content areas, and motivation, self-efficacy and perception of the benefits of peer networks. Each index comprised 2–4 items; we measured how closely they are related using Cronbach's α internal consistency statistic, of which all were acceptable, with a value of at least 0.63 (Table 3).

Table 3 Reliability analysis of the nine indices created from the survey, and the mean ± SD of the variables in the species conservation planning theory of change (Fig. 1).

1 Internal consistency measure of how strongly individual items are related to one another, to determine whether they can be combined into a single measure; Cronbach's α > 0.60 was considered acceptable.

2 Measured on a scale of 1 (recall nothing) to 5 (recall a lot).

3 Measured on a scale of 1 (never) to 5 (applied more than weekly).

4 Measured on a scale of 1 (low self-efficacy) to 5 (high self-efficacy).

5 Measured on a scale of 1 (low motivation) to 5 (high motivation).

6 Measured on a scale of 1 (perception of no benefits) to 5 (perception of numerous benefits).

Mean ratings of recall of the three training content areas varied between 3.63 for technical planning skills and 4.21 for communication skills (Table 3). On the application of training content in the workplace, mean ratings varied between 2.01 for technical species conservation planning skills and 3.00 for communication skills. The mean scores for self-efficacy, motivation, and perceptions of peer network benefits were 4.08, 4.51 and 3.91, respectively.

We conducted three linear regressions, with application of each of the three knowledge/skill content areas as the dependent variable. In each regression we included recall of corresponding training content, self-efficacy, motivation and participation in a peer network as independent variables. For the application of stakeholder skills, the variables self-efficacy, recall of stakeholder engagement content and peer network participation were retained (P ≤ 0.04) and motivation was excluded (P = 0.98). The model explained 22% of the variance (adjusted R2; Table 4). For the application of communication skills, the variables recall of communication content and peer network participation were retained (P < 0.01) and motivation and self-efficacy were excluded (P ≥ 0.09). The model explained 17% of the variance (adjusted R2; Table 4). For the application of technical planning skills, the variables recall of technical planning content, self-efficacy and peer network participation were retained (P < 0.04) and motivation was excluded (P = 0.58). The model explained 23% of the variance (adjusted R2; Table 4).

Table 4 Regression analyses used to examine the variables that influence conservation capacity building in the Conservation Planning Specialist Group Theory of Change.

We also conducted a logistic regression to determine the extent to which six independent variables influenced the leading and designing of species conservation plans. The independent variables included recall of each of the three training topics, motivation, self-efficacy and participation in a peer network. Only self-efficacy was retained (P < 0.01); all other variables were excluded. The regression explained 9% of the variance (Table 4).

Given that self-efficacy was significant as a predictor in several of the regressions, we conducted an additional linear regression to determine the extent to which any of our variables influenced self-efficacy. In a regression model with nine variables, three variables were retained (P < 0.05): motivation, recall of stakeholder engagement content and perception of peer network benefits (Table 4).

Discussion

The Conservation Planning Specialist Group's ultimate goal, as illustrated in its theory of change, is the improvement of the status of species, which it aims to achieve via training individuals in the development of species conservation plans. The theory of change suggests that knowledge/skills, motivation, self-efficacy, peer networks and other factors contribute to the pathways that lead to species conservation plans. This research assesses various elements of the theory of change.

A clear finding was the positive influence of content recall and peer network participation on our theory of change's short-term or first-order outcome of how often an individual applied the training content. However, as we moved through the theory of change to the second-order outcome of developing species conservation planning processes, self-efficacy emerged as an important variable. This is consistent with previous studies indicating that gaining new skills and knowledge is not enough; other factors influence and enable the application of new skills and knowledge (Chauhan et al., Reference Chauhan, Ghosh, Rai and Kapoor2017; Na-nan et al., Reference Na-nan, Chaiprasit and Pukkeeree2017).

Our results also support the general premise that gaining new knowledge and skills via training has a positive effect on the application of new knowledge and skills after training. In our study, recall of content related to stakeholder engagement, communication and technical aspects of species conservation planning predicted how often a trainee applied the content related to these items.

However, recalling new skills and knowledge is only one influential variable. In three analyses to determine the factors that influence the application of the skills and knowledge from the three content areas, recall never acted alone; participation in peer networks and self-efficacy also contributed. This should prompt trainers to build their sessions and workshops to define training outcomes that go beyond the acquisition of knowledge and skills to include support systems (e.g. peer networks) and confidence in the application of new content (e.g. self-efficacy).

Establishment of peer networks, which was one of our theory of change outputs, was statistically significant in all three analyses that assessed the effect of participation in a peer network on the application of training content. What does an effective peer network look like and how does it contribute to the transfer of knowledge to the workplace? Literature from a variety of disciplines points to a number of best practices such as creating environments that build trust between network participants (Backer & Smith, Reference Backer and Smith2011; Worton, Reference Worton2019), promoting opportunities for participants to collaborate (Rhodes & Beneicke, Reference Rhodes and Beneicke2006; Backer & Smith, Reference Backer and Smith2011; Worton, Reference Worton2019), creating subgroups within networks based on narrow topics (Backer & Smith, Reference Backer and Smith2011; Miller et al., Reference Miller, Duron, Bosk, Finno-Velasquez and Abner2016) and providing support to facilitate the translation of abstract thinking into action (Backer & Smith, Reference Backer and Smith2011; Scallan et al., Reference Scallan, Davis, Thomas, Cook, Thomas and Valverde2017; Worton, Reference Worton2019).

Our analyses also indicated that self-efficacy often affected the frequency of the theory of change's first-order outcome of applying training content. However, our theory of change was developed with longer-term outcomes in mind; we want training to contribute to species conservation planning, which we anticipate will lead to improvements in conditions for species. With that outcome as the focus in our analysis, the importance of self-efficacy increased considerably. In analyses assessing the factors that influence participation in species conservation planning, self-efficacy was the only variable retained.

Designing and implementing species conservation plans is an inherently complex task. It requires simultaneously applying the three training content areas (amongst others) that were the focus of our study as well as a multitude of internal and external factors beyond the capacities and assets of an individual. Of the three topics, stakeholder engagement content appears to be particularly important for affecting self-efficacy positively. Given that species conservation often occurs in settings with high potential for conflict and where a lot is at stake for both wildlife and people, this finding is to be expected. Leaders of species conservation planning processes need confidence that they can successfully work with those individuals who are most directly affected, positively and negatively, by species and species conservation. These skills not only contribute substantially to self-efficacy but often determine conservation success (Giakoumi et al., Reference Giakoumi, McGowan, Mills, Beger, Bustamante and Charles2018). When designing training that enhances self-efficacy, the literature indicates that training opportunities should focus on providing participants with opportunities to observe someone modelling a targeted behaviour and allow participants to practice the behaviour themselves and receive feedback on their performance (Mintzes et al., Reference Mintzes, Marcum, Messerschmidt-Yates and Mark2013; Malinauskas, Reference Malinauskas2017).

When we examined variables regarding their relation to self-efficacy, recall of stakeholder engagement training content emerged as having a positive influence on how an individual perceived their ability to conduct species conservation planning effectively. This aligns with previous research that points to the need for local engagement in conservation efforts for projects to be successful (Brooks, Reference Brooks2016; Sterling et al., Reference Sterling, Betley, Sigouin, Gomez, Toomey and Cullman2017; Giakoumi et al., Reference Giakoumi, McGowan, Mills, Beger, Bustamante and Charles2018). When considered concurrently with this research on stakeholder involvement, our finding makes a strong case for ongoing commitment in the conservation sector to building capacity for stakeholder-related skills and knowledge, including building confidence amongst conservation practitioners for conducting such outreach.

With respect to limitations, our study was dependent on self-reported data. We used individual estimates of how often participants applied specific types of training content rather than more objective measures of actual observations of the respondents’ behaviour. Furthermore, unreported analyses in our study showed there was generally no difference in outcomes between online and in-person training participants, but there are opportunities to research how these two learning modalities differ in terms of their effectiveness for capacity building, especially in the area of online training, which is more accessible and cost-effective than in-person training. In addition, our study was based on a sample of participants primarily from 2018 and thereafter. We had few respondents from prior years because of the low response rate from such individuals, e-mail addresses that were no longer valid as individuals moved on from where they had worked at the time of their training, and improved internal recordkeeping of training participants at the Conservation Planning Specialist Group after 2017.

Finally, an area for further research is determining how the contextual characteristics of an individual's specific circumstances affect performance, and assessing the factors in their work and broader environments that enable them to implement species conservation planning. This research points to stakeholder skills, self-efficacy and peer networks as factors that could improve species conservation planning, but there are other variables (both internal and external to an individual) that influence performance. In addition, comparisons based on context as well as individual social and demographic information would help to define further how best to support individuals and organizations to implement species conservation planning.

Conclusion

A theory of change first identifies its ultimate desired impact and works backwards to determine the activities and inputs needed to achieve that impact and the intermediate outputs and outcomes that link activities to the desired long-term impact. This study revealed the importance of peer networks, stakeholder knowledge and skills, and self-efficacy to the Conservation Planning Specialist Group's theory of change, with a particular emphasis on self-efficacy. Conserving biodiversity and reversing trends of species loss require myriad actions, including robust and comprehensive species conservation plans that ensure sufficient stakeholder buy-in so that they are implemented effectively. As our study indicates, training of individuals should go beyond conveying the technical aspects of how to conduct important conservation planning to address additional factors such as self-efficacy, which empowers individuals to apply their technical training in their work. Individuals must feel capable and confident at turning principles into practice and bring with them a network upon which they can lean for support and guidance.

Acknowledgements

This research was partially funded by a private gift to support conservation leadership and capacity building. We thank the participants for their support. The Conservation Planning Specialist Group is grateful to the Global Conservation Network, which supports the work of the organization, including its capacity-building programmes.

Author contributions

Conceptualization: BLB, JC; project management: BLB; data collection and analysis: BLB; data interpretation: BLB, JC, SEW; writing: all authors.

Conflicts of interest

BLB was the primary researcher for the project, acted in an external consultant role to the Conservation Planning Specialist Group, and did not receive any financial or similar support from the Conservation Planning Specialist Group to conduct the research. Data were collected and analysed by BLB alone. JC works for the Conservation Planning Specialist Group in a role of capacity building for conservation practitioners, did not participate directly in data collection or analysis, and decisions regarding the results to include in this manuscript were made in collaboration with BLB. SEW has no affiliation with the Conservation Planning Specialist Group.

Ethical standards

This research abided by the Oryx guidelines on ethical standards. It followed guidelines and protocols that assured and protected the voluntary participation, confidentiality and well-being of survey respondents. The research was approved by Colorado State University's Institutional Review Board (protocol #2291).

Footnotes

Supplementary material for this article is available at doi.org/10.1017/S0030605322000023

References

Al-Eisa, A.S., Furayyan, M.A. & Alhemoud, A.M. (2009) An empirical examination of the effects of self-efficacy, supervisor support and motivation to learn on transfer intension. Management Decision, 47, 12211242.10.1108/00251740910984514CrossRefGoogle Scholar
Backer, T.E. & Smith, R. (2011) Peer networking and community change: improving foundation practice. The Foundation Review, 2, 1229.10.4087/FOUNDATIONREVIEW-D-10-00016CrossRefGoogle Scholar
Bandura, A. (2010) Self-efficacy. In The Corsini Encyclopedia of Psychology, Volume 4 (eds Weiner, B. & Craighead, W.E.), pp. 15341535. John Wiley & Sons, Hoboken, USA.Google Scholar
Biggs, D., Conney, R., Roe, D., Dublin, H.T., Allan, J.R., Challender, D.W.S. & Skinner, D. (2016) Developing a theory of change for a community-based response to illegal wildlife trade. Conservation Biology, 31, 512.10.1111/cobi.12796CrossRefGoogle ScholarPubMed
Bottrill, M., Cheng, S., Garside, R., Wongbusarakum, S., Roe, D., Holland, M.G. et al. (2014) What are the impacts of nature conservation interventions on human well-being: a systemic map protocol. Environmental Evidence, 3, 16.10.1186/2047-2382-3-16CrossRefGoogle Scholar
Box, G.E.P. & Draper, N.R. (1987) Empirical Model-Building and Response Surfaces. John Wiley & Sons, Hoboken, USA.Google Scholar
Bravo-Torres, J.F., Andrade-Rea, P.E., Vintimilla-Tapia, P.E., Ordóñez-Morales, E.F., López-Nores, M. & Blanco-Fernández, Y. (2017) Leveraging Short-Lived Learning Networks to Encourage Collaborative Peer Learning. Proceedings of the 12th Latin American Conference on Learning Technologies, 9–13 October, La Plata, Argentina.10.1109/LACLO.2017.8120884CrossRefGoogle Scholar
Brooks, J.S. (2016) Design features and project age contribute to joint success in social, ecological, and economic outcomes of community-based conservation projects. Conservation Letters, 10, 2332.10.1111/conl.12231CrossRefGoogle Scholar
Carter, W.R., Nesbit, P.L., Badham, R.J. & Parker, S.K. (2016) The effects of employee engagement and self-efficacy on job performance: a longitudinal field study. International Journal of Human Resource Management, 29, 120.Google Scholar
Chauhan, R., Ghosh, P., Rai, A. & Kapoor, S. (2017) Improving transfer of training with transfer design: does supervisor support moderate the relationship? Journal of Workplace Learning, 29, 268285.10.1108/JWL-08-2016-0079CrossRefGoogle Scholar
Cherian, J. & Jacob, J. (2013) Impact of self-efficacy on motivation and performance of employees. International Journal of Business and Management, 8, 8088.10.5539/ijbm.v8n14p80CrossRefGoogle Scholar
Clayton, S., Prévot, C., Germain, L. & Saint-Jamie, M. (2017) Public support for biodiversity after a zoo visit: environmental concern, conservation knowledge, and self-efficacy. Curator: The Museum Journal, 60, 87100.10.1111/cura.12188CrossRefGoogle Scholar
Conservation Planning Specialist Group (2020) Species Conservation Planning Principles & Steps. cpsg.org/sites/cbsg.org/files/documents/CPSG%20Principles%20and%20Steps.pdf [accessed 12 January 2021].Google Scholar
Elliott, L., Ryan, M. & Wyborn, C. (2018) Global patterns in conservation capacity development. Biological Conservation, 221, 261269.10.1016/j.biocon.2018.03.018CrossRefGoogle Scholar
Giakoumi, S., McGowan, J., Mills, M., Beger, M., Bustamante, R.H., Charles, A. et al. (2018) Revisiting ‘success’ and ‘failure’ of marine protected areas: a conservation scientist perspective. Frontiers in Marine Science, 5, 223.Google Scholar
Hur, J.W. & Brush, T.A. (2009) Teacher participation in online communities: why do teachers want to participate in self-generated online communities of K-12 teachers. Journal of Research and Technology in Education, 41, 279303.10.1080/15391523.2009.10782532CrossRefGoogle Scholar
Johnson, F.A., Eaton, M.J., Williams, J.H., Jensen, G.H. & Madsen, J. (2015) Training conservation practitioners to be better decision-makers. Sustainability, 7, 83548373.10.3390/su7078354CrossRefGoogle Scholar
Lees, C.M., Rutschmann, A., Santure, A.W. & Beggs, J.R. (2021) Science-based, stakeholder-inclusive and participatory conservation planning helps reverse the decline of threatened species. Biological Conservation, 260, 109194.10.1016/j.biocon.2021.109194CrossRefGoogle Scholar
Lunenburg, F.C. (2011) Self-efficacy in the workplace: implications for motivation and performance. International Journal of Management, Business, and Administration, 14, 16.Google Scholar
Malinauskas, R.K. (2017) Enhancing of self-efficacy in teacher education students. European Journal of Contemporary Education, 6, 732738.Google Scholar
Margoluis, R., Stem, C., Swaminathan, V., Brown, M., Johnson, A., Placci, G. et al. (2013) Results chains: a tool for conservation action design, management, and evaluation. Ecology and Society, 18, 22.10.5751/ES-05610-180322CrossRefGoogle Scholar
Miller, J.J., Duron, J.F., Bosk, E.A., Finno-Velasquez, M. & Abner, K.S. (2016) Peer-learning networks in social work doctoral education: an interdisciplinary model. Journal of Social Work Education, 52, 360371.10.1080/10437797.2016.1174632CrossRefGoogle Scholar
Mintzes, J.J., Marcum, B., Messerschmidt-Yates, C. & Mark, A. (2013) Enhancing self-efficacy in elementary science teaching with professional learning communities. Journal of Science Teacher Education, 24, 12011218.10.1007/s10972-012-9320-1CrossRefGoogle Scholar
Naegels, V., D'Espallier, B. & Mori, N. (2020) Perceived problems with collateral: the value of informal networking. International Review of Economics & Finance, 65, 3245.10.1016/j.iref.2019.09.008CrossRefGoogle Scholar
Na-nan, K., Chaiprasit, K. & Pukkeeree, P. (2017) Influences of workplace environment factors on employees’ training transfer. Industrial and Commercial Training, 49, 303314.10.1108/ICT-02-2017-0010CrossRefGoogle Scholar
Perry, V. & Davenport, M.A. (2020) An inductive framework of self-efficacy to understand and support farmers in conservation agriculture. Journal of Soil and Water Conservation, 75, 198208.10.2489/jswc.75.2.198CrossRefGoogle Scholar
Pietri, D.M, Stevenson, T.C. & Christie, P. (2015) The coral triangle initiative and regional exchanges: strengthening capacity through a regional learning network. Global Environmental Change, 33, 165176.10.1016/j.gloenvcha.2015.05.005CrossRefGoogle Scholar
Redford, K.H., Hulvey, K.B., Williamson, M.A. & Schwartz, M.W. (2018) Assessment of the conservation measures partnership's effort to improve conservation outcomes through adaptive management. Conservation Biology, 32, 926937.10.1111/cobi.13077CrossRefGoogle ScholarPubMed
Rhodes, C. & Beneicke, S. (2006) Coaching, mentoring and peer-networking: challenges for the management of teacher professional development in schools. Journal of In-Service Education, 28, 297310.10.1080/13674580200200208CrossRefGoogle Scholar
Rodríguez, J.P., Rodríguez-Clark, K.M., Oliveira-Miranda, M.A., Good, T. & Grajal, A. (2006) Professional capacity-building: the missing agenda in conservation priority setting. Conservation Biology, 20, 1340.10.1111/j.1523-1739.2006.00535_1.xCrossRefGoogle ScholarPubMed
Salafsky, N. (2011) Integrating development with conservation: a means to a conservation end, or a mean end to conservation? Biological Conservation, 144, 973978.10.1016/j.biocon.2010.06.003CrossRefGoogle Scholar
Sawrey, B., Copsey, J. & Milner-Gulland, E.J. (2017) Evaluating impacts of training in conservation: a case study in Mauritius. Oryx, 53, 117125.10.1017/S0030605316001691CrossRefGoogle Scholar
Scallan, E., Davis, S., Thomas, F., Cook, C., Thomas, K., Valverde, P. et al. (2017) Supporting peer learning networks for case-based learning in public health: experience of the Rocky Mountain Public Health Training Center with the ECHO training model. Pedagogy in Health Promotion, 3, 5358.10.1177/2373379917697066CrossRefGoogle Scholar
Sterling, E., Betley, E., Sigouin, A., Gomez, A., Toomey, A., Cullman, G. et al. (2017) Assessing the evidence for stakeholder engagement in biodiversity conservation. Biological Conservation, 209, 159171.10.1016/j.biocon.2017.02.008CrossRefGoogle Scholar
Taplin, D.H. & Clark, H. (2012) Theory of Change Basics: A Primer on Theory of Change. ActKnowledge, New York, USA.Google Scholar
Taplin, D.H., Clark, H., Collins, E. & Colby, D.C. (2013) Theory of Change Technical Papers. ActKnowledge, New York, USA.Google Scholar
Valters, C. (2014) Theories of Change in International Development: Communication, Learning, or Accountability? Justice and Security Research Programme Paper 17. London School of Economics, London, UK.Google Scholar
Veretennik, E. & Kianto, A. (2019) The impact of trust and information networks on teachers’ job satisfaction. Kybernetes, 49, 200228.10.1108/K-04-2019-0298CrossRefGoogle Scholar
Vogel, I. (2012) Review of the Use of ‘Theory of Change’ in International Development. UK Department of International Development, London, UK.Google Scholar
Welch-Devine, M., Hardy, D., Brosius, J.P. & Heynen, N. (2014) A pedagogical model for integrative training in conservation and sustainability. Ecology and Society, 19, 10.10.5751/ES-06197-190210CrossRefGoogle Scholar
Worton, S.K. (2019) Examining peer networking as a capacity-building strategy for housing first implementation. Journal of Community Psychology, 48, 11471162.10.1002/jcop.22240CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Theory of change for the Conservation Planning Specialist Group's capacity building to support trainees to lead the design and facilitation of species conservation planning processes.

Figure 1

Table 1 Example survey items from the Conservation Planning Specialist Group survey of former training participants.

Figure 2

Table 2 Characteristics of the sample from a survey of Conservation Planning Specialist Group former training participants.

Figure 3

Table 3 Reliability analysis of the nine indices created from the survey, and the mean ± SD of the variables in the species conservation planning theory of change (Fig. 1).

Figure 4

Table 4 Regression analyses used to examine the variables that influence conservation capacity building in the Conservation Planning Specialist Group Theory of Change.

Supplementary material: PDF

Bruyere et al. supplementary material

Bruyere et al. supplementary material

Download Bruyere et al. supplementary material(PDF)
PDF 69.2 KB