This study was conducted to investigate the factors affecting the adoption of organic farming in Peshawar-Pakistan. A total of 100 respondents were randomly selected from the four different cultivated areas of Peshawar, namely Palosi, Regi, Ternab and Pushtakhara. Binary logistic re-gression was used in this study to categorize the organic farming into adoption and non-adoption. The purpose of this model was to check the event probability for a categorical response variable with two outcomes. The results of the binary logis tic show that factors affecting adoption of organic farming have a significant effect on the farmer productivity. Moreover, cost, productivity, profitability, compatibility and efficiency have a positive and significant effect. Thus, it is obvious that adopting organic farming not only to increase the farmer income but also to protect environmental pollution by avoiding the toxic chemical and fertilizer. Finally, we suggest that government agencies, extension and research institution should play a vital role to strengthen the awareness and advantages of organic farming.
In agriculture, one of the methods is organic farming which protects environment, quality of the food, animal health, natural resources on sustainable bases and is helpful for the social welfare purpose. These objectives support the market and compensate for the internalization of externalities [
Since the mid-1980s, policy-makers, environmentalists, consumers and farmers have paid significant attention to organic farming and actively involved for the regulation and support of organic sector. To achieve the major goals in organic farming and agricultural policy, a diverse and complex range of policy approaches have been formed and implemented to support this sector. Conversely, there are many particular challenges for policy making and implementation of the policy. These challenges are to maintain the balance between societal and consumer/market goals and to keep the balance between institutional and private stakeholder interests in the organic sector [
The countries with the most organic agricultural land are Australia (12 million hectares), Argentina (3.8 million hectares), and the United States (1.9 million hectares). Currently 0.9 percent of the agricultural land of the countries covered by the survey is organic. By region, the highest shares of the total agricultural land are in Oceania (2.9 percent) and in Europe (2.2 percent). In the European Union, 5.4 percent of the farmland is organic. However, some countries reach far higher shares: Falkland Islands: 35.9 percent; Liechtenstein: 27.3 percent; Austria 19.7 percent. In ten countries, more than ten percent of the agricultural land is organic. There has been an increase of the organic agricultural land in Asia, Europe, North America and Oceania. For Asia, after a major drop of organic land in 2010, 0.9 million more hectares were reported. There was also strong growth in Europe, where the area increased by 0.6 million hectares (6 percent). In Latin America the organic land decreased, mainly due to a decrease of organic grazing areas in Argentina. Apart from agricultural land, there are further organic areas, most of these being areas for wild collection. Other areas include aquaculture, forests, and grazing areas on non-agricultural land. They constitute 32.5 million hectares. In total, 69.7 million hectares (agricultural and non-agricultural areas) are organic. There were 1.8 million producers in 2011. Thirty-four percent of the world’s organic producers are in Asia, followed by Africa (30%), and Europe (16%). The countries with the most producers are India (547591), Uganda (188625) and Mexico (169570) [
Over the past four decades not only incorporation of modern agricultural farming practices, but also the usage of excess amount of chemical inputs have caused losses for the natural habitat balance and soil fertility. Examples of these losses are soil salinization, soil erosion, pollution due to fertilizers and pesticides, decreased groundwater level, genetic erosion. These hazards have initiated ill effects on environment, degrade the food quality, enhance the cost of production, and badly affect the farmer life [
Several studies have suggested that the determinants of the adoption of organic production systems should be explained. Various research approaches have been used for this purpose: factors influencing the adoption of organic and inorganic fertilizers in maize and kales by using the logit and probit regression analysis [
The adoption approach which usually relies upon cross-sectional data which is analyzed by means of probability models to assess the likelihood that conversion occurs [
On the basis of in-depth research literature [
This study is based on the factors affecting adoption of organic farming in District Peshawar, Pakistan. Four different agricultural areas namely Palosi, Regi, Ternab and Pushtakhara were selected for the purpose that a large number of farmers were involved in these areas. Due to financial and budget constraint the study was restricted to limited number of sample size. A total of 100 respondents were randomly selected by using proportional sampling allocation technique. A well-developed pretested structured questionnaire was formed to collect the primary data from the farmers in the study area. The empirical data was analyzed by using Statistical tools for Social science (SPSS) Version 20. The main of objectives of the paper was to find the fertilizer used adoption or non-adoption of organic farming.
The categorization of firms into “adopters” and “non-adopters” is based on the dichotomous outcome of the adoption decision, which characterizes the dependent variable (Y). Thus, a firm is defined as an “adopter” where Yi = 1 or as a “non-adopter” where Yi = 0 [
Probit model deals with a choice between two alternatives [
Binary logistic regression analysis were used in this study to categorize the Organic Farming into adoption and non-adoption. Binary logistic regression is most useful in cases where we want to model the event probability for a categorical response variable with two outcomes. The logistic regression model is a type of generalized linear model that extends the linear regression model by linking the range of real numbers to the range 0 - 1.
where: pi is the probability that the ith case will adopt an Organic farming and zi is the value of the unobserved continuous variable for this ith case. The model also assumes that Z is linearly related to the predictors.
Thus,
The term zi is the ith value of the dependent variable and Xi is ith value of the independent variable. The term ei is known as the “error” and contains the variability of the dependent variable not explained by the independent variable. Where n is the number of independent variables.
The regression coefficients are estimated through an iterative maximum likelihood method.
The following model was used to assess the adoption of organic farming in the study area. Description of the model variables are explained in the
After detailed interview from the respondents in the study area results of the descriptive statistics were presented in tabular form (
Dependent Variable | Categories | |
---|---|---|
TFU | Type of Fertilizer used | Organic = 0 Inorganic = 1 |
Independent Variables | ||
AGE | Age of the respondent | Less than 30 years = 1 30 - 40 years = 2 40 - 50 years = 3 50 - 60 years = 4 60 - Above years = 5 |
EDU | Education od the respondent | Literate = 0 illiterate = 1 |
EXP | Experience of the farmers | 0 - 10 years = 1 10 - 20 years = 2 20 - 30 years = 3 30 - 40 years = 4 40-above = 5 |
LTS | Land Tenure status of the Farmers | Owner = 1 OwnerCum status = 2 tenants = 3 |
IA | Irrigation Availability | Whole year = 1 seasonal availability = 2 Rain fed = 3 |
TCHF | Type of Cheaper/Healthy Fertilizer | Organic = 0 Inorganic = 1 |
AEF | Adverse effect of fertilizer | Organic = 0 Inorganic = 1 |
TV | Training or Visit attend by the Respondents | 0 - 10 = 1 10 - 20 = 2 20-Above = 3 |
COST | Cost | High Cost = 1 Equal = 2 Low Cost = 3 |
PRD | Productivity | Less Productive = 1 Equal = 2 More Productive = 3 |
PRF | Profitability | Less profitable = 1 Equal = 2 More Profitable = 3 |
CPT | Compatibility | Incompatible = 1 Equal = 2 More Compatible = 3 |
EFC | Efficiency | Less efficient = 1 Equal = 2 More Efficient = 3 |
Variables | Mean | Min. | Max. | Std. Dev. |
---|---|---|---|---|
AGE | 2.7 | 1 | 5 | 0.937 |
EDU | 0.73 | 0 | 1 | 0.446 |
EXP | 1.69 | 1 | 4 | 0.8127 |
LTS | 1.75 | 1 | 3 | 0.8333 |
IA | 1.14 | 1 | 2 | 0.3487 |
TFU | 0.73 | 0 | 1 | 0.446 |
TCHF | 0.65 | 0 | 0 | 0.479 |
AEF | 0.46 | 0 | 1 | 0.501 |
TV | 1.68 | 1 | 4 | 0.815 |
COST | 1.97 | 1 | 3 | 0.936 |
PRD | 1.92 | 1 | 3 | 0.849 |
PRF | 1.87 | 1 | 3 | 0.848 |
CPT | 1.9 | 1 | 3 | 0.870 |
EFC | 1.83 | 1 | 3 | 0.853 |
Source: Field survey-2010.
mean and Standard Deviation land tenure status of the farmers and irrigation availability was 1.75, 0.8333 and 1.14, 0.3487 respectively.
During survey in the research area it was found that type of fertilizer used by farmers mean was 0.73 which shows that large number of farmers have adopted the organic farming. Moreover, Type of Cheaper/Healthy Fertilizer and Adverse effect of fertilizer mean and Standard Deviation was calculated 0.65, 0.479 and 0.46, 0.501 respectively. In addition, training or visit attended by the respondents mean was1.68, and Standard Deviation was estimated 0.815.
The sole objective of the producer is productivity. Mean and Standard Deviation for productivity was calculated 1.92 and 0.849. At last, mean and Standard Deviation for compatibility was figured out 1.9 and 0.870. Besides, mean and Standard Deviation for efficiency was valued 1.83 and 0.853.
Variables | Coefficient | Std. Error | Z | Significance |
---|---|---|---|---|
Intercept | −5.911 | 1.956 | −3.02198 | 0.998 |
AGE | 0.051 | 1.13 | 0.045133 | 0.964 |
EDU | 0.068 | 0.487 | 0.13963 | 0.889 |
EXP | −0.523 | 0.338 | −1.54734 | 0.939 |
LTS | 1.253 | 0.721 | 1.737864 | 0.082 |
IA | −1.06 | 0.678 | −1.56342 | 0.941 |
TCHF | 1.346 | 0.885 | 1.520904 | 0.128 |
AEF | 0.843 | 0.43 | 1.960465 | 0.049 |
TV | −0.547 | 0.216 | −2.53241 | 0.994 |
COST | 1.258 | 1.387 | 0.906994 | 0.364 |
PRD | 1.367 | 1.374 | 0.994905 | 0.749 |
PRF | −0.234 | 0.124 | −1.8871 | 0.970 |
CPT | 1.91 | 1.451 | 1.316334 | 0.188 |
EFC | 1.569 | 1.325 | 1.184151 | 0.236 |
Pseudo R2 | 0.45 | |||
Log likelihood | −42.510 | |||
Correct Predictions | 87.2% | |||
Observations | 100 |
Source: Field survey-2010.
Results in
Other important factors on decision of adoption of organic farming that were positively significant included water accessibility, farm-gate price and attitude to conventional production problems. This implies that the early organic adopter may have better access to water, the ability to seek and find higher prices, and have stronger attitudes toward conventional farming problems [
Farmers’ perception about the adoption of organic farming plays an influential role in adopting or non-adopting organic farming. Concluding the results, the adoption of organic farming has a positive and significant impact on the farmer life i.e. cost, productivity, profitability compatibility and efficiency. Hence, the farmers should motivate and be aware of the advantages of organic farming through extension and research intuitions not only to increase income but also to change their behavior and perception about new technique of the farming. Finally, it is suggested that the adoption of organic farming is essential for famers, and for this purpose comprehensive policy and strategies should be made to aware the farmers from the benefits of organic farming.