Conceptual model

To begin, we outline a causal chain that highlights how different forms of information exchange impact agricultural practices depending on whether the information is mediated through bridging social capital, bonding social capital, or both (Figure 1). How much information a farmer has access to and the degree to which they trust that information depends on their social capital (i.e. the number and strength of relationships). The greater the social capital, the more likely a farmer is to adopt new resource practices (Wossen et al. Reference Wossen, Berger, Mequaninte and Alamirew2013). Social connections can foster information exchange by facilitating the development of “bonding” social capital (i.e. strong personal relationships) and by facilitating development of “bridging” social capital (i.e. weak, but diverse, personal relationships) (Putnam Reference Putnam2000). Bonding social capital tends to be generated among a small number of people, as many strong relationships are difficult to maintain at once, while bridging social capital most often leads to more, but weaker, ties between individuals. Figure 1 highlights that one-way forms of communication (such as internet, TV and radio) are hypothesized to influence agricultural practices by expanding access to information and networks (i.e. bridging social capital), two-way forms of communication (like cell phones and cooperatives) influence agricultural practices through deeper connections (i.e. bonding social capital) and that social media influences agricultural practices by both expanding and deepening social relationships.

Figure 1. Directed Acyclic Graph (DAG). This figure represents the causal path through which mobile phones, social media, farm cooperatives, and extension impact agricultural practices. Bridging social capital (which is based on weaker ties between individuals) brings together people who don’t know each other well such as colleagues, associates or neighbors. Bonding social capital (which is associated with strong relationships) builds slowly and helps to strengthen connections between family and friends (Tiwari et al. Reference Tiwari, Lane and Alam2019; King et al. Reference King, Fielke, Bayne, Klerkx and Nettle2019). Social media is the only information communication method that is mediated by both bridging and bonding social capital, enabling both weak and strong interpersonal relationships. Cell phones and cooperatives tend to only enable bonding social capital due to the lack of interactions that occur with strangers or acquaintances. Traditional extension visits do not work through bridging or bonding social capital since they generally serve as a one-way transfer of knowledge.

Farmer relationships were once limited by whom they could communicate with in-person. Information communication technologies (ICTs) expanded these farmer networks by allowing for quicker and wider communication, which resulted in access to a large volume of information that requires information-seekers to curate sources (Metzger and Flanagin Reference Metzger and Flanagin2013). Information-seekers thus rely on credibility shortcuts (including familiar sources, sources trusted by others, sources that appear professional) that are often combined with information that is consistent with prior thoughts and beliefs (Metzger and Flanagin Reference Metzger and Flanagin2013).

Early ICTs including newspapers, radio, and television broadcasts are effective one-way sources of information (Zanello, Srinivasan, and Shankar Reference Zanello, Srinivasan and Shankar2014; Aker Reference Aker2011). This form of communication means that these ICTs expose farmers to additional sources of information, but can only contribute to bridging social capital since, on their own, they do not help to develop deeper relationships. It is possible that ICTs that operate primarily as sources of information, more recently including access to the internet, can indirectly support the development of bonding social capital by providing information about community events (Stern, Adams, and Boase Reference Stern, Adams and Boase2011). Mobile phones and farmer cooperatives pose an opportunity to extend social capital development opportunities by introducing two-way communication possibilities that typically strengthen existing relationships by facilitating the development of bonding social capital. Traditional extension visits, on the other hand, generally serve as an individual-to-individual transfer of knowledge in which the credibility of the source is based on their technical qualifications.

The addition of social media to the mix allows for the development of both strong and weak ties because it exposes individual users to a large network of users while enabling participants to easily strengthen connections with existing contacts or develop new relationships through sharing personal experiences (Anderson-Wilk Reference Anderson-Wilk2009). These personal stories and two-way interactions play a vital role in disseminating information that motivates change because these personal connections help to reduce uncertainty regarding the values and variability of potential costs and benefits of new agricultural practices (Nwankwo et al. Reference Nwankwo, Thompson, Bokelmann, Peters and Bett2010).

Farmers are more likely to adopt a new and beneficial agricultural technology if they have easy access to information about the technology that is credible, legitimate, and salient (Baumgart-Getz, Prokopy, and Floress Reference Baumgart-Getz, Prokopy and Floress2012; Liverpool-Tasie and Winter-Nelson Reference Liverpool-Tasie and Winter-Nelson2012; Kassie et al. Reference Kassie, Zikhali, Manjur and Edwards2009; Llewellyn Reference Llewellyn2007; Cash et al. Reference Cash, Clark, Alcock, Dickson, Eckley, Guston, Jäger and Mitchell2003). Thus, the who and how of information dissemination plays an important role in the rate of uptake because information sources must be trusted if farmers are to act on that knowledge. Non-expert information-seekers often rely on the perceived source credibility to determine the degree to which the information can be trusted, where any known agent expertise and the farmer’s social network often play a role in drawing these conclusions (Lucassen and Schraagen Reference Lucassen and Schraagen2013). For example, prior research suggests that extension agents are trusted and positively influence adoption (Kassie et al. Reference Kassie, Zikhali, Manjur and Edwards2009). However, not all farmers in a region have access to extension support, and agents often visit or extend program opportunities to farms they think are already more likely to adopt the practice being tested (zu Ermgassen et al. Reference Ermgassen, de Alcântara and Balmford2018; Aker Reference Aker2011; Wossen et al. Reference Wossen, Abdoulaye, Alene, Haile, Feleke, Olanrewaju and Manyong2017). Therefore, many farmers depend on their social networks and any demonstration of experience with using a technology (Adegbola and Gardebroek Reference Adegbola and Gardebroek2007) to determine information quality and trust (Fisher et al. Reference Fisher, Holden, Thierfelder and Katengeza2018).

Both weak and strong relationships allow new information to be quickly and easily passed between social groups, but the information that is spread among weak ties has a larger footprint. For this reason, bridging social capital can expose farmers to a greater number of unfamiliar perspectives and increase the chances for learning about new technologies. At the same time, both types of connections can fail to result in the adoption of new practices if the social circle becomes insular (i.e. an echo chamber), reducing the possibility of new ideas and innovation (King et al. Reference King, Fielke, Bayne, Klerkx and Nettle2019). Social media is the only ICT that encourages the development of both bridging and bonding social capital, where relationship-based evaluation shortcuts tend to be the most salient due to this combination of social capital, which allows for the development of large, diverse social networks (Tiwari, Lane, and Alam Reference Tiwari, Lane and Alam2019; Abrams and Sackmann Reference Abrams and Sackmann2014) and an increased trust in information (Pan and Chiou Reference Pan and Chiou2011).

The extent to which social media can help to influence the spread of information about farming practices depends on the quality and quantity of information provided by government agencies, private input suppliers and other farmers. We conducted a systemic review of the Facebook pages and profiles of three state extension agencies (IDARON, EMATER and SENAR), a federal extension agency (EMBRAPA) and several Facebook groups interested in rural production in Rondônia to determine the reach and focus of social media in our study region. We build on our conceptual model and this qualitative analysis to inform our quasi-experimental approach. This systematic review revealed that these almost daily posts on events, research, and news provided information that is important to farmers, such as when and how to provide counts of livestock herds and how to record evidence of cattle vaccinations to federal and state agencies (Table 1). The focus of these posts is found to be cattle and pasture management practices such as pasture rotation. Additional services included photos and videos on management techniques, soil treatments, and a tool to assist decision-making on the appropriate stocking rate of cattle. Among Facebook groups interested in rural production in Rondônia, 70% were found to be focused on the purchase and sale of agricultural products and inputs. We therefore match the practices highlighted in these sites and posts with the practices recorded in our survey.

Table 1. Review of social media profiles of agencies and networks

Notes: All data collected by the authors in 2020 over a course of one month. One of the Facebook groups noted that members would switch to a WhatsApp group for discussions, suggesting that this may be the preferred communication tool of farmers in the near future.

Data

We use farm-level survey data collected from agricultural households in three regions of the Amazonian state of Rondônia, Brazil (Figure 2) to test the impact of social media (and three other forms of information communication) on agricultural practices. The majority of the population of the state is located in agricultural colonization settlements established from the 1970s onwards. Following high rates of deforestation over the previous 40 years, the region is now made up of widespread pasture and a small patchwork of mature and secondary forest (Numata et al. Reference Numata, Cochrane, Roberts and Soares2009; Roberts et al. Reference Roberts, Numata, Holmes, Batista, Krug, Monteiro, Powell and Chadwick2002). Family farms (those with less than 200 hectares of land) make up about 80% of agriculture in the state (Brazilian Institute of Geography and Statistics (IBGE) 2017). These farms are largely engaged in milk and beef production, with some perennial crops (Caviglia-Harris, Sills, and Mullan Reference Caviglia-Harris, Sills and Mullan2013; Mullan et al. Reference Mullan, Sills, Pattanayak and Caviglia-Harris2018).

Figure 2. Study Region. The 2009 study region includes the 6 municipalities in the Ouro Preto do Oeste Region (Center) of Rondonia. The 2019 study region includes this six municipality region plus 9 additional municipalities in the northern and southern regions of the state. The DID analysis uses the 2009 and 2019 data from the six municipality region in the center of the state. The propensity score matching includes observations for all three study sites interviewed in 2019.

Internet access in rural Brazil has historically been sparse: As late as 2017, the agricultural census found only 28% of agricultural households in Brazil had internet access (Brazilian Institute of Geography and Statistics (IBGE) 2017). Based on a Regional Center for Studies on the Development of the Information Society survey on the use of ICT in Brazilian households, access to the internet at home was 16% lower in rural regions of the country than in urban regions in 2019 (CETIC 2020). In addition, the North census region (including the Amazonian states of Acre, Amapá, Amazonas, Pará, Rondônia, Roraima and Tocantins) has historically lagged behind the national average but is catching up to the national averages. According to this same source, the use of social network sitesFootnote ² increased in the North by more than 1.7 million users between 2009 and 2019, and of those who used a mobile phones in 2019, more than half used it to access social media, indicating the important role of smartphones in connecting rural households in this more recent time frame. Lastly, none of the millions of respondents in this national study reported using social media via mobile phones in 2009 (the pretreatment year in our study).

We collected household survey data in 2009 and 2019 to estimate the impact of social media and other information sources on adoption of agricultural practices. Survey responses are from a stratified random sample, where the stratification is based on the rural population of each of the 15 municipalities in the three study sites. Our sample represents a spatially dispersed random sampling of approximately 4–6% of the rural population in each municipality (in each of the two years). The survey included questions about household characteristics (such as age and education of household heads, involvement in organizations, and social media use), demographics (including income and wealth), farm characteristics (i.e. land use, soils, and location) and farm production and choices (including crops, yields and practices), among others (Caviglia-Harris, Sills, and Mullan Reference Caviglia-Harris, Sills and Mullan2013; Mullan et al. Reference Mullan, Sills, Pattanayak and Caviglia-Harris2018). Our panel was created by returning to the households interviewed in the previous survey year. We also added new households to the sample using a randomized sampling methodology in each survey year that ensured our interviewed population represented the urban population in this rapidly changing region (IBGE 2024).

The 2009 sample includes household responses in our Central study site (Ouro Preto do Oeste) and is from a panel that began in 1996 (Caviglia-Harris et al. Reference Caviglia-Harris, Hall, Mulllan, Macintyre, Bauch, Harris, Sills, Roberts, Toomey and Cha2012). The 2019 sample includes households from the panel in the Central study site as well as new households in our expanded study region including the North (Ariquemes) and South (Rolim de Moura) study sites. We focus on these before and after time periods in the difference-in-difference estimation (and do not use the full panel that began in 1996) because social media was not adopted by farmers in this region until after 2009.

Our data consist of (1) four information treatments, (2) outcomes, namely use of particular agricultural practices, and (3) controls (Table 2). Our information treatments are those that we outline in our conceptual model (i.e. social media, mobile phones, membership in farmer cooperatives and extension visits). We consider mobile phones and social media as more “modern” sources of information exchange and participation in farmer cooperatives and extension visits to be more “traditional” sources (Varma Reference Varma2018; Desai and Joshi Reference Desai and Joshi2014). The cooperatives in our study region include groups that gather to negotiate prices, socialize and share information about farming techniques. Extension visits are on-site consultation visits by one or more of the state or federal agencies outlined in Table 1.

Table 2. Descriptive statistics for different samples

Notes: Data are from household surveys conducted at the farm properties. Wealth is measured as the value of all vehicles owned, adjusted for inflation and reported in 2019 reais. Risk preference is on a scale of 0-10, 0 is equivalent to no willingness to take risks, 10 is equivalent to being very willing to take risks. Discounting of the future is on a scale of 0-10, 0 is no willingness to take risks, 10 is very willing to give up something to get more benefit in the future.

The household panel suggests that the more “modern” information networks provided by mobile phones and social media appear to be on the rise. 78% percent of the sample had a mobile phone in 2009 and this share increased to 91% in 2019 (Table 2). Social media was not in use in the region in 2009 but by 2019 69% of the sample reported using social media. At the same time, the “traditional” cooperative networks and extension activities are found to be on the decline, with a decrease from 75% of the sample participating in at least one association in 2009 to an average of 46% by 2019, and a decrease from 57% receiving an extension visit to 30% over the same period (Table 2).

When asked in more detail about their social media use, households in our sample indicated that the most common social media platform is WhatsAppFootnote ³ , with 100% of social media users responding they use this app. Facebook is the second most common platform (67% of social media users). Far fewer respondents use Instagram, Twitter or any other social media platform. Of those who say that they use these platforms at all, 54% use them to exchange information about agricultural production. Among those who exchanged information on agriculture, the most common topics are farming techniques (65%), crop prices (64%), and agricultural sales (49%). Other uses include learning about weather, politics, and government programs. Finally, households respond that they use the platforms to receive information on average of 1–2 times per week and share their own information an average of 1–2 times per month (not provided in the table).

Our outcome variables reflect the adoption of different types of technologies and management practices (Table 2). The more traditional Cattle and Pasture Practices include insemination, other reproduction expenditures, the fallowing of pasture, and the use salt licks (for a total of four practices in our count). The use of these “traditional” practices is declining over time according to our survey responses. Farmers used 1.23 of these practices in 2009 and 0.86 on average in 2019. The “novel” practices promoted by state and federal agencies post-2009 include Pasture Reform (which we include as a dummy and as the total area) and Frontier Practices including the use of clonal varieties of grasses for pasture and the use of semi-confinement for cattle operations (for a total of two practices in our count). Almost half of the farmers in our sample (45%) reported reforming their pasture in 2019 with an average area of 4.33 hectares or less than 10% of the total area in pasture. Farmers in our sample used only 0.04 out of a potential total of 2 frontier practices in 2019.

Data in Table 2 suggest that households have an average of approximately three and a half years of education in both years, smaller families by 2019 (4 in 2019 compared with 5.1 in 2009), and that the increase in farming experience by 2019 is less than 10 years (the gap in the survey years) for the panel because some younger generations have inherited these properties and lower still for the larger 2019 matched sample because newer and younger households, who settled in the region after 2019, are included in this sample. Households have aged, as indicated by the 10-year survey gap, but some have also retired and/or passed on the farm to younger household members. Finally, we have three controls that are used in the propensity score matching models: wealth, willingness to take risks, and willingness to discount the future. Wealth (proxied with the value of all vehicles owned by the household) is approximately R$8,600 in 2009. This inflation adjusted value increases by over 300% to over R$36,000 by 2019 for the panel of households and is even greater for the matched sample (over R$52,000). Risk tolerance is not available for 2009, but in 2019, it is recorded as 3.48 on a scale of 0 to 10 in the panel sample and slightly lower at 3.24 in the matched sample, while willingness to discount the future was also not included in the 2009 survey, but stands at 4.43 in the 2019 panel sample and 4.39 in the matched sample. The risk tolerance survey question follows the design of Dohmen et al. (Reference Dohmen, Falk, Huffman, Sunde, Schupp and Wagner2011) in asking, “Please tell me how much you would say you are or are not willing to take risks in general. To answer, use a scale from 0 to 10, where 0 means you are ‘not willing at all to take risks’ and 10 means that you are ‘very willing to take risks’.” This format has been shown to be strongly correlated with the widely used (but more time consuming to elicit) lottery approach used by Holt and Laury (Reference Holt and Laury2002) to elicit risk preferences (Dohmen et al. Reference Dohmen, Falk, Huffman, Sunde, Schupp and Wagner2011; Nielsen, Keil, and Zeller Reference Nielsen, Keil and Zeller2013; Hardeweg, Menkhoff, and Waibel Reference Hardeweg, Menkhoff and Waibel2013). The relative patience question had an equivalent structure and asks about willingness to give up something that is beneficial today in order to benefit more in the future. This has also been experimentally validated and was included in the 2012 Gallup World Poll (Falk et al. Reference Falk, Becker, Dohmen, Enke, Huffman and Sunde2018).

Empirical strategy

We use two quasi-experimental approaches to estimate the plausible causal impacts of social media and other sources of information on the adoption of various agricultural practices. Our preferred estimation technique is the Difference-in-Differences (DID) analysis, which is used to quantify the impact of the ICT interventions while accounting for any pre-existing trends or inherent disparities between different groups. However, because many of the new practices that are being promoted on social media in 2019 (see Table 1) were not used in 2009, because our data collection strategy did not include questions about pasture reform in 2009, and because we expanded our sample size and geographic scope in 2019, we complement our DID analysis with Propensity Score Matching (PSM). The use of PSM allows us to estimate the impact of the different treatments on pasture reform as well as the other agricultural practices we cannot include in the DID analysis. The rationale behind the PSM is that we can include more (and newer) practices that weren’t asked about in 2009; capture a more varied sample that is perhaps more representative of the state (and the Amazon frontier); and compare an alternative identification strategy for robustness. This dual-method approach allows us to draw more reliable and nuanced conclusions, ultimately contributing to a deeper understanding of the relationship between social media engagement and agricultural practice adoption.

To estimate a causal effect, one would ideally compare the agricultural practices adopted (Y) for a given household with and without the information treatment (T), i.e. social media use, mobile phone ownership, cooperative membership or extension visits. As we cannot observe both outcomes, we estimate counterfactual outcomes for the treated individuals in the absence of the information treatment.

We first employ a Difference-in-Differences (DID) approach to estimate the changes in outcomes for treated households relative to untreated households between 2009 and 2019. For our main outcome of the number of cattle and pasture management practices adopted, we use a fixed effects Poisson regression model. The equation is specified as follows:

$${Y_{it}} = {\rm{exp}}\left( {{\beta _0} + {\beta _1}{T_{it}} + \mathop \sum \limits_k {\beta _k}{X_{kit}} + {\mu _i} + {t_t} + {\varepsilon _{it}}} \right)$$

In this model, Y _it represents the count of agricultural practices for household i at time t. We compare the outcomes for households that adopted social media or mobile phones, or changed their cooperative membership or interaction with extension agents (our treatments, T) between 2009 and 2019 and those that did not. The model controls for all time-invariant unobservable influences on farm outcomes (μ _i), year fixed effects (t _t), k number of time-variant observable characteristics (X _kit ) and includes the error term ( ${\varepsilon _{it}})$ . This model allows us to capture the relationship between the treatment and the count outcomes while appropriately handling the non-negative nature of the count data. Similarly, a fixed effects probit model is used to estimate the impact of the treatments on the individual practices that are summed to create these categories. The equation for these estimations is similar; however, the model is based on a latent variable approach and uses a nonlinear function (the cumulative distribution function of the standard normal distribution) to estimate the probability of the binary outcome. Finally, we use a linear specification to estimate the effects of the treatments on the area of pasture.

This DID estimate provides a counterfactual group that did not change their treatment status while subject to the same changes in external conditions (policies, inflation, etc.) as the group that did change their treatment status. In the case of social media, the pretreatment period (2009) serves as a baseline for all households because social media was effectively nonexistent in Rondônia in 2009. In this quasi-experimental setup, the treated households adopt social media by 2019 and the untreated “control” households do not. The difference between the changes in outcomes experienced by the treated and control households can therefore be attributed to the treatment. The identification strategy is similar for mobile phones, cooperative membership, and engagement with extension agents, although these information mechanisms were available to farmers in both time periods.

To take advantage of a larger and more diverse cross-sectional sample, evaluate impacts on additional practices, and assess the robustness of our difference-in-difference results, we also use propensity score matching (PSM) to identify a farmer population that is otherwise similar to our treated populations (i.e. the social media and mobile phone users, farm cooperative members, and farmers who received extension visits). This is because farmers who use social media, own mobile phones, participate in farmer cooperatives and/or receive extension activities could be significantly different from those who do not use or participate in regards to these information activities, particularly in regards to relative wealth. PSM addresses this potential bias resulting from non-random selection into each of the information treatments by comparing households that are similar in their observable characteristics except their information access and dropping those that are not from the analysis.

We estimate the propensity to use social media or the other information sources as a function of the observable covariates described in Section 3 to obtain a propensity score for each observation. We then use nearest neighbor matching with replacement, which matches a treated observation with the control that has the closest propensity score. Nearest neighbor matching has superior performance in regards to the variance-bias tradeoff in comparison to propensity score calipers (Austin Reference Austin2018) and assumes that differences in outcomes are random conditional on observable characteristics; i.e. that no systematic differences in unobservables exist between households that do and do not use social media or participate in farmer cooperatives. There is a possibility that our outcomes of interest may be correlated with unobservable determinants of social media, mobile phone use, farm cooperative membership and/or extension engagement. For example, if farmers with an affinity for new technology both engage with social media and are inclined to adopt innovative agricultural practices or if farmers participate in cooperatives with the objective of learning about alternative approaches to farming. In either case, this would positively bias our estimates of the impact.

Once we identify the matched sample, we estimate the difference in the means between our control and treated groups with the following linear equation:

$${Y_i} = {\beta _0} + {\beta _1}{T_i} + {\beta _2}{X_i} + {\varepsilon _i}$$

where, similar to above, Y _i represents the count of agricultural practices for household i in 2019, T _i represents the treatments, X _i is a set of controls and ${\varepsilon _{it}}\;$ is the error term.