Study area

This study was conducted in the Lalitpur district (latitudes 24°11’–25°14’ N and longitudes 78°10’–79°0’ E) of the Bundelkhand region of central India (Fig. S1). Of the total district area, c. 19% is degraded land, and c. 52% of the total degraded land is agricultural. Most of the population in the district is dependent on crop/livestock-based activities (GoI 2016b).

The prevalent undulating topography, hard rock geology, low soil fertility, scarce groundwater resources along with poor and erratic rainfall lead to frequent droughts and crop failure in the region (Garg et al. Reference Garg, Anantha, Nune, Venkataradha, Singh and Gumma2020, Singh et al. Reference Singh, Choudhary, Dwivedi, Arunachalam, Kumar and Dev2023). Farmers mainly cultivate crops such as groundnut, black gram, sesame and millet during the kharif (monsoon) and wheat, chickpea, barley, mustard and lentils during the rabi (October–February) season.

Three villages, namely Birdha, Purakhurd and Jhabar, in the Talbehat block of Lalitpur district were designated as treated villages, as all of the soil and water conservation activities were concentrated within their physical boundaries. Three adjacent villages, namely Gundera, Gebra and Viharipura, were chosen as control villages, which did not receive any soil- or water-based interventions but shared similarities with the treated villages in terms of agro-climatic conditions, infrastructure and socio-economic status.

Soil and water conservation measures in the study area

As a part of a project to double farmers’ income (KISAN MITrA) funded by the government of Uttar Pradesh State (India), various types of SWCMs were started in the study area in 2017 by the ICRISAT Development Center (IDC; Hyderabad) in a consortium with ICAR – Central Agroforestry Research Institute (CAFRI; Jhansi), ICAR – Indian Grassland and Fodder Research Institute (IGFRI; Jhansi) and a non-governmental organization (NGO) partner, Upman Mahila Sansthan.

Details of the SWCMs in the project villages are given in Table S1. As developing surface water and groundwater resources is crucial to enhancing farm productivity in rain-fed areas, a significant proportion of the total project expenditure was allocated for harvesting surface water through deepening and widening of the drainage network and the construction of water-harvesting structures such as farm ponds and havelis (traditional rainwater-harvesting tank systems to store runoff generated from the catchment during the monsoon and used for multiple purposes), which were present in almost every village in Bundelkhand (Meter et al. Reference Meter, Steiff, McLaughlin and Basu2016, Garg et al. Reference Garg, Anantha, Nune, Venkataradha, Singh and Gumma2020, Pathak et al. Reference Pathak, Pal and Mohapatra2020). All of these off-farm activities were being used for conserving soil and ensuring supplemental irrigation to nearby fields during dry periods.

Conceptual framework

The two primary methodologies employed in measuring farm TE are SPF analysis and data envelope analysis (DEA; Bravo-Ureta et al. Reference Bravo-Ureta, Greene and Solís2012, Wang et al. Reference Wang, Huo and Kabir2013, Choudhary et al. Reference Choudhary, Dev, Singh, Singh, Sharma and Chand2022). The DEA method is sensitive to outliers due to its reliance on the assumption of there being no sampling errors (Diagne et al. Reference Diagne, Demont, Seck and Diaw2013), and its applicability in agricultural studies, where output is particularly susceptible to random errors, is constrained (Koirala et al. Reference Koirala, Mishra and Mohanty2016). We therefore opted for the SPF approach to assess the TE of farmers, and the model was specified as in Equation 1:

(1) $${Y_i} = f\left( {{X_i},{d_i}} \right) + {\rm{\;}}{{\rm{\varepsilon }}_i}$$

where Y _i is the output variable for the ith farmer, X _i denotes the input variables and the adoption of SWCMs is encapsulated by the dummy variable d (1 = adopters, 0 = non-adopters). The error term ϵ _i is delineated as the disparity between the stochastic error term (v _i ) (v ∼ N(0, σv ²)) and a positive one-sided component (u _i ) designed to account for the impact of inefficiency in the production process.

Several observed and unobserved factors exert influence on farmers’ adoption decisions, introducing self-selection bias in the case of SWCMs. Consequently, the dummy variable d _i , signifying the technology adoption status of the farmers, is endogenously determined (Ma et al. Reference Ma, Renwick, Yuan and Ratna2018). Therefore, the sample selection equation for the adoption decision of farmers was formulated as in Equation 2:

(2) $$d_i^{\rm{*}} = {\rm{\;}}{{\rm{\alpha }}_i}{W_i} + {\rm{\;}}{e_i}$$

where d _i * serves as a latent variable denoting a farmer’s inclination towards adopting SWCMs; it signifies the adoption status, with d _i taking a value of 1 for adopters and 0 for non-adopters. W _i encompasses exogenous variables that impact the adoption decision of the farmer. The coefficient α represents unknown parameters, and e _i represents the error term.

Selectivity bias correction

The propensity score matching (PSM) technique was employed to pair farmers from treated and control villages based on observed characteristics. The predicted probability of farmers adopting SWCMs, known as the propensity score, was generated by estimating Equation 2 through a binary-choice probit model. To ensure a balanced comparison between groups was achieved, a balancing test was conducted to confirm that farmers from treated and control villages were perfectly matched, indicating no systematic differences in observed characteristics such as age, education and landholdings. In order to address selectivity biases arising from unobserved factors such as attitude to risk, managerial ability and motivation of farmers within a SPF framework, we adopted Greene’s (Reference Greene2010) model, which is superior to Heckman’s self-selection specification for linear regression models (Bravo-Ureta et al. Reference Bravo-Ureta, Greene and Solís2012, Ma et al. Reference Ma, Renwick, Yuan and Ratna2018). The error structure in Greene’s (Reference Greene2010) model assumes correlation between the error term in the selection equation (ϵ _i ) and the noise (v _i ) in the stochastic frontier model. Mathematically, the error structures of Greene’s (Reference Greene2010) model can be expressed as in Equation 3:

$${u_i} = {\rm{\;}}\left| {{{\rm{\sigma }}_u}{U_i}} \right| = {\rm{\;}}{{\rm{\sigma }}_u}\left| {{U_i}} \right|;{\rm{\;}}{U_i}{\rm{\;}}\sim {\rm{\;}}N\left[ {0,1} \right]$$

$${v_i} = {\rm{\;}}{{\rm{\sigma }}_v}{V_i}{\rm{\;}};{\rm{\;\;}}{V_i}{\rm{\;}}\sim {\rm{\;}}N\left[ {0,1} \right]$$

(3) $$\left( {{{\rm{\varepsilon }}_i},{\rm{\;}}{v_i}} \right){\rm{\;}}\sim {\rm{\;}}{N_2}\left[ {\left( {0,1} \right),{\rm{\;}}\left( {1,{\rm{\rho }}{{\rm{\sigma }}_v},{\rm{\sigma }}_v^2} \right)} \right]$$

where ρ represents the selectivity correction term, and a statistically significant coefficient for ρ would indicate the presence of selectivity bias arising from unobservable factors. U is a non-negative term accounting for technical inefficiency, V is a symmetric error term, σ is the standard deviation and N is the normal distribution function.

Sampling procedure and data collection

Given that the matching technique employed in this study necessitates a larger number of observations from control units, ideally in a ratio of c. 1:2 (Datta Reference Datta2015), data were collected from 150 farm households from the treated villages and 250 households from the control villages. Stratification of household heads was conducted based on land size categories within each village, and the probability proportional to size method was applied to select sample households from each village. Respondent household heads were then chosen using a random sampling technique.

The survey schedule comprehensively gathered information on various socio-economic parameters, including the age and education status of household members, the farming experience of the household head and the landholdings of the household. The crop farming data encompassed details on the area and production of each crop cultivated during the kharif and rabi seasons for the agricultural year 2021–2022. Additionally, the survey delved into the variable costs associated with diverse input categories such as human labour, machine labour, seeds, fertilizers and pesticides on a crop-by-crop basis.

Empirical techniques

We employed both PSM and the selectivity bias-corrected SPF model of Greene (Reference Greene2010) to control for biases arising from both observed and unobserved factors. Within PSM, we used kernel-based matching (KBM) with a bandwidth of 0.01 due to its reported effectiveness at minimizing biases (Ma et al. Reference Ma, Renwick, Yuan and Ratna2018). The application of KBM resulted in a total of 336 matched observations, comprising 150 farmers from the treated villages and 186 farmers from the control villages.

To evaluate the efficacy of the matching process, we conducted t-tests both before and after matching, as outlined by Leuven and Sianesi (Reference Leuven and Sianesi2003). These tests were employed to assess the null hypothesis that the means of observed characteristics for beneficiaries and non-beneficiaries are equal. Utilizing the propensity scores, we estimated the selectivity correction term (ρ) and incorporated it into the SPF framework, following the approach of Abdulai and Abdulai (Reference Abdulai and Abdulai2017). In the estimation of the production frontier, we compared both the Cobb–Douglas and translog functional forms using the likelihood ratio (LR) test. Based on the test results, we specified the Cobb–Douglas function as in Equation 4:

(4) $${\rm{ln}}\left( {{Y_i}} \right) = {{\rm{\beta }}_{0{\rm{\;}}}} + {\rm{\;}}\mathop \sum \nolimits_{i = 1}^4 {{\rm{\beta }}_i}\ {\rm{ln}}\ {X_i} + {\rm{\;}}{\vartheta _i}{d_{i\;}} + {\varepsilon _i}$$

In the specified model, the dependent variable ln(Y _i ) represents the log transformation of the total gross revenue (in INR) from the considered crop. The independent variable ln(X _i ) is the log-transformed value of inputs, aggregated into four major categories, namely expenditures on labour, machinery, seeds and agrochemicals (fertilizers and pesticides). The parameter β _i denotes the production elasticity of the ith input and was estimated. ϑ is the coefficient parameter of d (adoption status) and ϵ is the error term.

To compare the goodness of fit between two nested models, where one model is a constrained version of the other, we performed the LR test on both the unmatched and matched samples to examine potential technology disparities between the treated and control groups. Specifically, the restricted model assumes no disparities in technology adoption between the treated and control groups, whereas the unrestricted model permits differences in technology adoption (Equation 5).

(5) $${\rm{LR}} = {\rm{\;}} - {2^{}}\left( {{\rm{ln}}{L_P} - {\rm{\;}}\left( {{\rm{ln}}{L_T} + {\rm{\;ln}}{L_C}} \right)} \right)$$

where lnL _P , lnL _T and lnL _C represent the log-likelihood function values estimated from the pooled sample, treated subsample and control subsample, respectively. If the null hypothesis indicating no differences in technology adoption between the treated and control groups was rejected based on the LR test, this implied that the parameters for the production frontiers differed between treated and control farmers. This rejection would suggest significant disparities in how technology is adopted and utilized by the treated and control groups; technology-related factors were influencing production outcomes differently for the two groups. The SPF for beneficiaries and non-beneficiaries was then estimated as in Equations 6 and 7:

(6) $${\rm Beneficiaries:}\ln \left( {{Y_i}} \right) = {{\rm{\theta }}_0} + \mathop \sum \nolimits_{i = 1}^4 {{\rm{\theta }}_i}\ {\rm{ln}}\ {X_i} + \left( {1 - {\rm{\varphi }}} \right){{\rm{\delta }}_i}{{\rm{\rho }}_i} + {{\rm{e}}_i}$$

(7) $$\eqalign{ & {\rm{Non}} - {\rm{beneficiaries}}\ln \left( {{Y_i}} \right) = {\theta _0} + \sum\nolimits_{i = 1}^4 {{\theta _i}} {\mkern 1mu} {\rm{ln}}{\mkern 1mu} {X_i} + \left( {1 - \varphi } \right){\tau _i}{\rho _i} \cr & \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad + {\omega _i} \cr} $$

where ln(Y _i ) and ln(X _i ) are the logarithmic forms of gross revenue and input parameters, respectively, ρ _i is a correction term, ϕ₀ and θ₀ are constant terms, δ _i , θ _i and τ _i are parameters to be estimated and ϕ is a selectivity correction term that takes a value of 0 when unobserved selection bias issue is considered and 1 if this not considered in estimating the SPF. Both e and ω are error terms of their respective equations.