Hybrid knowledge and climate-resilient agriculture practices of the Tharu in the western Tarai, Nepal

Introduction

The complementarity of different knowledge systems in regard to climate science, biodiversity conservation, and sustainable farming is being realized in the contemporary climate change context (Agrawal, 1995; IPCC, 2007). Indigenous knowledge is increasingly appreciated because scientific knowledge alone is recognized as inadequate to deal with the complex global climate crisis (Ellen, 2007; Sillitoe, 2007; Finucane, 2009). The knowledge of Indigenous people about agriculture and natural resource management, as well as their perceptions of climate change, is important due to their generations of engagement. Indigenous knowledge is often used interchangeably with concepts of traditional and local knowledge despite these having different meanings. According to the Food and Agriculture Organization of the United Nations (FAO, 2004, p. 1), Indigenous knowledge has a close association with “tribal groups” and the “original inhabitants of an area,” while traditional knowledge has the connotation of being “rural, isolated, static and not interacting with other knowledge systems,” and local knowledge is community knowledge of people who may or may not be Indigenous people and whose knowledge may have various sources. Scientific knowledge, in contrast, is derived from scientific method through the formal academic and research institutions and includes scientific technology, input and information in the subject matter. Traditional farming communities, such as the Tharu of Nepal, continue to use proven traditional agricultural practices, but also adopt knowledge, input and technology from others into a hybrid farming system harnessing all available knowledge. Such hybrid knowledge of agricultural practices is being adopted in local sociocultural and environmental contexts to contribute to climate-smart agriculture. Knowledge hybridity in agriculture occurs because the local land use systems that are dominated by traditional beliefs and Indigenous knowledge in agriculture may not meet future food demands due to increasingly limited land and low productivity of landraces (Van Vliet et al., 2012).

A discussion of knowledge hybridization with due consideration of Indigenous knowledge gained momentum with its integration into development programs by the World Bank (Warren, 1991; Woytek, 1998; World Bank, 2004) and its consideration by the Inter-Governmental Panel on Climate Change (IPCC) in the fourth assessment report (AR4) in 2007 (IPCC, 2007). In the modern world, Indigenous knowledge has proven beneficial when integrated with science. Local practices and Indigenous knowledge have been integrated in climate science and natural resource management in many projects worldwide, such as the use of Inuit knowledge to explore snow routes in Canada (Galloway McLean, 2009) and Australian Aboriginal knowledge for controlled bushfire management in Australia (Kimber, 1983; Andersen et al., 2005). Similar examples involve traditional techniques for field contouring in Mali that reduce water runoff by 20–50% and increase yields by up to 30% (Technology Need Assessment, 2017), and shifting cultivation or swidden farming practices used for such crops as dry rice by Indigenous communities in the tropics (Conklin, 1957, 1980; Sillitoe, 2017). However, debate continues regarding soil degradation and low production under shifting cultivation, which involves keeping land fallow between crop plantings, crop rotations and slope/contour farming, all of which are useful to reduce soil degradation and nutrient losses, especially in forest contexts, and reduce carbon emissions. There are diverse local practices in agriculture, mainly for crop production and soil and insect-disease management that contribute to scientific knowledge (Thurston, 1990; Warren, 1991; Dewalt, 1994). For example, Dewalt (1994) describes how scientific knowledge complements Indigenous knowledge, for example, in managing locusts by identifying specific species and using scientific control measures when Indigenous knowledge does not recognize such species at the time and place of the outbreak. The integration and legitimization of Indigenous knowledge with formal science could help to develop and scale-up Indigenous knowledge using programs of bilateral/multilateral agencies (Briggs, 2013). Similarly, the use of weather forecast systems, integration of flooding early warning mechanisms in the Tharu barghar system (village leadership), and adoption of agriculture input (inorganic fertilizer, pesticides, herbicides, and seed) are some of the examples of the contribution of scientific knowledge to Indigenous knowledge to reduce climatic risks to contribute resilient agrarian livelihoods (Chaudhary et al., 2021).

Adaptation to changing climatic conditions and mitigation of the sources of greenhouse gases (GHGs) are necessary to improve the resilience of agriculture among agriculture-dependent communities. A meta-analysis by the IPCC on wheat, maize and rice showed that adaptation will increase the yield equivalent by 15–18% more than without adaptation until the 2080s (Porter et al., 2014). Indigenous knowledge and traditional farming practices, including agrobiodiversity conservation, have been widely described as providing adaptation to climatic variability, mitigation of GHG emissions, and sustainable productivity and income (Sterrett, 2011; Caritas, 2016). Climate-resilient agriculture practices and technology can minimize negative impacts and can also mitigate future risks (Speranza, 2010). Climate-resilient agriculture refers to the robustness of the system that can reduce climatic stresses and impacts, as well as dealing with future risks (Adger, 2006; Folke, 2006; Speranza, 2010; IPCC, 2014). Although resilient agricultural practices often emit low GHGs, their yield and profitability may not be as competitive as climate-smart agriculture that utilizes both traditional and innovative agricultural practices and technology to effect productivity enhancement, in addition to adaptation (resilience) and mitigation (Totin et al., 2018).

Traditional agricultural practices may be the basis for innovation in modern agriculture. Mixed cropping, relay sowing and zero-tillage are examples of traditional practices that farmers have used for many years in Asia and other parts of the world. Mixed cropping avoids complete crop failure and increases per unit area productivity of land, as well as reducing weeds, pest incidence and lodging; as well, it provides crop insurance against unstable market prices and extreme weather conditions (Sarker et al., 2004; Lithourgidis et al., 2011; Wang et al., 2012). Relay sowing in the Tarai setting of Nepal includes broadcast sowing of lentil, grasspea, linseed and other crops 2–3 weeks before rice harvesting. The productivity of relay sowing is determined by the genotypes and management practices used (Sarker et al., 2004; Wang et al., 2012; Malik et al., 2016; Wiraguna et al., 2017). Conservation tillage, such as zero-tillage, no-tillage or minimum tillage, in rice–wheat systems produce similar or higher yields, particularly of rice, than conventional tillage, along with having lower production costs (mostly through reduced labor), increased water productivity and reduced GHG emissions, thereby contributing to the mitigation of climate change (Jat et al., 2014; Gathala et al., 2015; Sapkota et al., 2015; Ladha et al., 2016). Such agricultural systems are specifically suited to the local context, resilient to climate change, and also emit low GHG. However, adoption of these practices is, in all likelihood, unrelated to perceived or actual climate change because these strategies have not been employed only after perceiving the impact of climate change. Rather, the practices are embedded in the traditional farming system due to providing a consistent yield, one which is able to respond to climatic variability.

The Tharu of the western Tarai (foothills/southern plains) have been, for generations, dependent on agriculture, with limited engagement in services, business and foreign labor (Bista, 1972; Rajaure, 1981; Guneratne, 2002; Chaudhary, 2008). The Tarai of Nepal, particularly its central and western regions, is comprised of forested land where there has historically been a high risk of malaria infection before its eradication in the late 1950s. The Tharu in the Tarai were the only frontier group who continuously settled in the area and supported Nepali rulers throughout the centuries. As a consequence of long-term settlement in the Tarai, the Tharu adapted and became genetically resistant to malaria (Modiano et al., 1991). After malaria eradication, hill and mountain people were encouraged to migrate and resettle in the Tarai, rendering the Tharu economically, socially and politically marginalized and suffering from an identity crisis (Müller-Böker, 1997, 1999; Guneratne, 1998, 2002).

Previous studies of Tharu knowledge have not focused upon what they know about climate, weather and the contribution of agricultural practices for adapting to and mitigating climate change. Studies touching on their knowledge in regard to climate change and adaptive agricultural practices have mostly been limited to consideration of crop landraces, pest management and adjusting crop sowing/harvesting dates (Devkota et al., 2011; Maharjan et al., 2011). The studies have not explored why such traditional practices are being continued by the farmers despite comparatively lower yield than the modern agriculture technology and practices, as well as how Indigenous and scientific knowledge are blended in local agricultural practice. Therefore, this study addresses two issues, first it contextualizes the knowledge of the Tharu relating to climate and agriculture in the context of a changing climate. Second, the study examines the role of conservation agricultural practices (e.g., relay sowing, zero-tillage, and mixed-cropping) in rendering agriculture resilient in withstanding climate change. The study endeavors not only to provide greater depth on existing Indigenous knowledge and its value, but also to contribute to the theoretical discourse concerning integration of different sources of knowledge for climate-resilient and climate-smart agriculture.

Materials and methods

Fieldwork area

The study was conducted in two rural villages, Thapuwa and Bikri, in Gulariya municipality, Bardiya district, Nepal, as shown in Figure 1. The villages are situated between the latitude of 28° 14′ N and longitude of 81° 18′ E at an altitude of ~215 m above mean sea level. The district shares its southern border with India. The Bardiya district was selected due to the high percentage of the Tharu in the district (53%, ~226,089 Tharu) (CBS, 2014), high reliance on agriculture-based livelihoods (DDC Bardiya, 2013; DADO Bardiya, 2015), and its status as one of the least developed districts in the naya muluk (new territory—Banke, Bardiya, Kailali and Kanchanpur) in terms of the human development index (HDI, 0.466) (Government of Nepal UNDP, 2014). Within the Bardiya district, Thapuwa and Bikri villages were chosen based on predominance of Tharu ethnicity and vulnerabilities to flooding and drought, respectively (DDC Bardiya, 2013; RKJS/Practical Action, 2013). Thapuwa village is long-settled, whereas Bikri village was settled in 1967 by immigrants from Dang-Deokhuri, which is more than 100 km to the east.

FIGURE 1

Figure 1. Bardiya district map showing the two fieldwork villages, Thapuwa and Bikri. Source: DoFRS (Cartographer) (2019).

Research methods and data analysis

The research utilized a sequential mixed-methods approach, with collection of quantitatively analyzed data followed by qualitative data elicited through in-depth interviews, focus group discussions (FGDs) and participant observation, conducted across 6 months in two phases in 2018. Table 1 gives a summary of the study's research methods and numbers of participants.

TABLE 1

Table 1. Interviews, focus group discussions (FGD) and household surveys during fieldwork in 2018.

The research utilized a mixed-methods approach in order to provide data validation and triangulation. The knowledge, interpretation, and experience of people are guided by their cultural beliefs; therefore, ethnoscience, with its emic focus on local classifications and knowledge, defined one study framework. Complementarily, etic analysis of agricultural production required quantitative analysis. Mixed methods increase the reliability and validity of research from both approaches (Neuman, 2004; Creswell and Plano Clark, 2011). A mixed methods approach includes the use of qualitative methods—participant observation, in-depth interviews, and focus group discussions/FGDs)—to elicit locally grounded data to complement quantitative results and also to facilitate triangulation of data (Creswell and Plano Clark, 2011). In the study, qualitative and quantitative analyses were performed separately, but the findings were mixed for discussion and interpretation.

Quantitative methods

A census was conducted of 229 households (143 in Thapuwa and 86 in Bikri), comprising all village households in the populations under study, using a semi-structured survey questionnaire after 1 month of familiarization and rapport-building with the people to ensure reliable information. The survey questionnaire was in three sections: agriculture, climate change and livelihoods. The survey was conducted with a household head or member engaged in farming, both wife and husband, if possible. Particular consideration in the choice of interviewees was given to people over 30 years old so that they could recall 10–20-year-long scenarios of climate and farming.

The questionnaire covered aspects of conservation agriculture—minimum soil disturbance, soil cover and crop rotation—aspects that are considered for analysis as climate-resilient agricultural practices. Relay sowing and zero-tillage constitute the minimum soil disturbances, rice stubble after harvest serves as a soil cover, and rotation of lentil and wheat in rice field meets the criteria of crop rotation. Relay sowing of lentil is conducted through broadcasting before 2–3 weeks of rice harvesting, which is conducted according to absolute no-tillage. In this study, one minor tillage with bullock or tractor cultivator is considered as zero-tillage. Tillage with mouldboard plow or harrow for two or more than two times is considered as conventional tillage. Mixed cropping (two or more than two crops cultivation) and sole cropping (single crop cultivation) are also considered in lentil cultivation. Lentil is normally mixed cropped with pea, mustard, and wheat. IBM SPSS version 20 was used to calculate frequency, means, standard deviations and t-tests for the productivity analysis.

Qualitative methods

During the first month, several transect walks, bike-rides, and many informal conversations were undertaken with the villagers. Building rapport was facilitated by the field researcher (i.e., the first author) also being Tharu and having been brought up in the region. The barghar (traditional village head), guruwa (shaman), school teachers and social leaders were approached as key informants and to obtain their support for the study.

Altogether, four focus group discussions/FGDs (2 in Thapuwa and 2 in Bikri) were conducted with farmers to assess the changes in agriculture in the last 10–20 years and possible reasons of change, strategies to manage insects, diseases and performance of ritual practices. The first FGD in each village was conducted with a wider range of participants, comprising household heads, traditional village leaders (barghar, guruwa, and chaukidar), farmers, and animal herders to assess the impact of climate change on livelihoods and farming and their coping and adaptation strategies. The second rounds of FGDs were conducted specifically with the farmers to assess the change in agriculture over 10–20 years, its possible reasons and farmers' responses to manage it. The agricultural knowledge and practices gathered from the FGDs were also triangulated with the district agriculture office and private service providers (e.g., agro-vets). For each of the FGDs conducted, 8–10 people representing different ages, genders, educational levels, and landholding sizes were selected. Farmers were asked to recall changes in agriculture and the farming system. The FGDs' format facilitated their memory of visible changes in the major aspects of agriculture and their recall of reasons for these changes. Hence, a maximum 20-year timeframe is considered for this analysis to gather robust information on such topics as changes in cropping patterns, as well as use of improved seeds and inorganic chemicals in agriculture. The FGDs were conducted during the pre-monsoon season (April to May) to reflect the preparation of rice cultivation, as well as preparation for coping with climatic extremes (flooding and drought). The FGDs took place in the community hall used by the entire village, and each lasted for a maximum of 4 h. The questionnaire checklist and framework for each FGD were translated into Tharu to facilitate the researchers leading the discussion with the support of a local facilitator. The research was carried out with the approval of the Human Ethics office (reference number RA/20/4133) of The University of Western Australia, Perth.

The qualitative data were manually categorized into themes and tabulated. NVivo 12 Plus (Qualitative Research Software (QSR) International) was used to analyze qualitative information. Interviews were manually transcribed. The qualitative data files were uploaded into the NVivo 12, categorized into different groups such as FGDs, interviews, and observations. The uploaded files were coded to form the nodes and sub-nodes in the software, where node and sub-node identify a theme and sub-theme. Different facilities of NVivo, such as node comparison, hierarchical chart, and cluster analysis, were used as a foundation for analysis in terms of important words and thematic areas (nodes). The final analysis was conducted by reading and re-reading transcriptions, digesting the information, and reflecting upon the interpretation of interviews to reach conclusions regarding knowledge and practices regarding climate and agriculture of the Tharu.

Ethnoclassification

Local peoples have their own ways of understanding and classifying climate/weather and seasons, agricultural land, weeds and other aspects of agriculture that derive from their Indigenous knowledge and its practical applications in everyday life. The Tharu ethnoclassifications were elicited based on the thematic analysis of various levels of discussions in groups, interviews, and participant observation during the major agricultural operations, such as rice transplantation and winter crop harvesting. Weeds were commonly observed during fieldwork in the winter and monsoon seasons. A series of individual and group interviews were conducted to capture local people's ethnotaxonomy of weeds and their management.

Results

Household and farming characteristics

Landholdings and other essential household characteristics are presented in Table 2. The households are small landholders (normally a household head owns the land), with households in Bikri have smaller landholdings (0.55 ha/household) than Thapuwa (1.17 ha/household). There are 19 mukta kamaiya families (former agricultural bondage laborers) in Thapuwa with small plots of land (0.07 ha/family). Despite the small landholdings, particularly in Bikri, the primary occupation of people in both villages is agriculture. The Tharu have been a patriarchal society, but the household leadership role of women is increasing in nuclear families.

TABLE 2

Table 2. Average household characteristics of the study villages.

Most large farmers cultivate the land themselves, while some of them lease additional land or rent out part of their land for cultivation. When renting land, 50% of the product is usually shared, which is called adhiya bataiya (sharecropping). Sharecropping is common among many families, with 64% (n = 91) in Thapuwa and 27% (n = 23) in Bikri participating in the practice. There are a small number of non-cultivators, 6% Thapuwa and 2% in Bikri, who own land, but who do not farm themselves. The members of these families mostly engage in salaried work or are in skilled employment.

Climate change—Perceptions and data evidences

Local people's perceptions are important for strategies of adaptation and mitigation and their realization. The responses of the participants regarding perception of climate change against four indicators (temperatures, rainfall, insect-diseases, and weeds) revealed consistent perceptions of increased temperatures (except for winter temperatures) by three-quarters of the respondents. Our analysis of 38 years of temperatures and rainfall data of the study area from government sources showed a significant increase in maximum temperature and mean temperatures almost by 1°C and 0.6°C, respectively. However, there has been no clear trend in rainfall due to high variation in the year-to-year rainfall. Therefore, we could not validate local Tharu perceptions of decreasing rainfall with climate data.

The Tharu in the study village prioritized flooding as the number one hazard, in both villages followed by droughts in Bikri and storms in Thapuwa in the 2nd place. The Tharu consider storms and hail as a natural disaster. Flooding has destroyed houses and roads, swept away stored grains, affected livestock, inundated standing crops, and sometimes caused irreversible damage to agricultural land by converting it into sandy riverbed. The local Tharu do practice riverbed farming based on the suitability of crops, including cereals, legumes and vegetables. Droughts have had varying levels of impact on crops, ranging from reduction in yield to complete crop failure. Droughts have still constituted a common threat in crop yield despite introduction of an irrigation technology and improved varieties of crops. Storm before monsoon (March to May) is disastrous to crops, fruit trees and even destruction of roof of houses thereby impacting livelihood of farmers.

Adjustment in agriculture—Changing climate and technology

There are multiple factors inducing change in an agricultural system. Household food security, market demand, technology, as well as climatic factors, have contributed to such change in cropping patterns, the crop calendar, and crop types/varieties. The crop calendar for the study villages is shown in Appendix 1, while possible reasons for changes in the agricultural system are summarized in Supplementary material.

There has been a clear adjustment in cropping pattern and cropping calendar over the last two decades. Rice and wheat are cultivated about 2 weeks earlier than 10–20 years ago. Monsoon-season maize has been almost entirely replaced with rice. An experienced farmer said, “Farmers near my maize field started to cultivate rice, which creates soil waterlogging that makes my field unsuitable for growing maize; then I also started to cultivate rice in that field.” Many farmers started to cultivate rice instead of maize in the summer/monsoon season due to the availability of short-duration rice varieties, high rice yields, and preference for eating rice over maize. Also, maize can be grown in winter/spring after harvesting rice, but rice normally grows only during the summer/monsoon season. No changes in lentil and pea cultivation were noted, but mustard cultivation has declined.

Traditional minor crops, such as linseed and sesame, are rarely cultivated due to the changes in land cultivation patterns and possible decline in market demand. Similarly, pigeon pea and pointed gourd cultivation have practically disappeared in Thapuwa due to changes in the river course making the land unsuitable for their cultivation. Local soybean, Tharu alu (Tharu potato) and chickpea cultivation have also drastically declined in the study area.

Major changes in the agricultural calendar and related activities have taken place regarding the traditional rice field preparation and threshing of crops. Rice field preparation was traditionally (up until 10–20 years ago) very labor-intensive, with at least three tillage passes before rice transplantation. The first preparatory tillage of the khetwa (rice terrace field) is called ofar/chir. It is performed after the onset of rain to loosen the soil, exposing it to sunlight, and to accelerate later land preparation for rice and maize cultivation. The first tillage of dihwa (flat land traditionally used for maize cultivation) is called dhuriya tillage—meaning dusty tillage without soil moisture. The main characteristics of ofar and dhuriya are one-way tillage (no cross-sectional tillage), shallow depth, and tillage not taking place in a flooded condition. The second tillage is called gejar, which is performed during the rice cultivation season in the shallow flooded field. The field is then left for 7–10 days so that weeds can decompose. The final tillage, called lewa, is then undertaken, followed by danta/kilwahi (raking) and henga (leveling) to puddle the field for rice transplantation. However, now the land preparation is much faster and easier than in the past because of use of farm implements (harrows) and mechanized power (tractors and power-trailers). A disc-harrow is used for plowing the dihwa as well as khetwa for land preparation, and there is no waiting period for crop cultivation. Overall, this process demonstrates the use of hybrid knowledge, combining traditional and modern methods, in land preparation, selection of adaptive and resilient crop varieties, and production and postharvest processing of crops.

Tharu agricultural calendar—Associated knowledge and practices

Tharu farmers perform activities based on the agricultural calendar and a combination of Indigenous and modern weather forecasting systems. Preparatory activities for agriculture are based on the Tharu seasons and crop calendar.

Tharu classify a year into three seasons based on the climate, with each season comprising ~4 months: Jar mahina (winter, November to February), Gham mahina (summer, March to June), and Barkha mahina (monsoon, July to October). Table 3 represents the months of the agricultural calendar with their associated activities.

TABLE 3

Table 3. Tharu agricultural calendar in wet rice and associated activities.

Jar represents the winter from mid-October (Katik) to mid-February (Magh). A thick fog, kuhira, is followed by cold waves, shitlahar, rendering life harder. The night frost is called pala. The area receives winter rainfall, labeled hewat, and rain in the peak of winter is called chamar barha, which kills cattle and goats due to the cold and lack of green fodder. If there is no rain, then the local people believe the chance of hail is high and vice-versa. Jar has positive and negative aspects in relation to agriculture. Farmers declare that the winter frost and dew are important for pulse crops (lentil, pea) and wheat. Hewat (winter rainfall) is an indicator of good winter crop production. Local farmers believe hewat increases the branching and growth of winter crops. Local people have a strong belief that canal irrigation without hewat is insufficient for good winter crops. Extended foggy weather with limited sunlight and high humidity increases the incidence of diseases, such as late blight in potato.

Gham, the summer season (March to June), is characterized by high temperatures and low humidity. Frequent windstorms occur during summer. Villagers believe storms come from the north-west, causing damage to houses, trees and crops. This is the agriculture leisure period before onset of the monsoon.

Barkha (monsoon season) runs from July to October. Most of the annual rain falls during this period. Barkha is characterized by high temperatures (lower than summer season) and humid conditions. The monsoon season is one of the busiest seasons because of rice cultivation. The Tharu in Thapuwa and Bikri villages identify rainfall by different names, such as Bundibunda barkha (scattered raindrops for a very short time), Jhimjhim (drizzling rain for a short period), Jhammak (heavy rain), and Jhari (continuous rainfall). Jhammak and Jhari lead to khet bahiya (field flooding) and ghar bahiya (house flooding) based on the intensity and season of rain. Villagers in Thapuwa prefer khet bahiya, as it deposits clay soil on the khet, which gives bumper crop yields and improves soil quality.

Hybridity in the sources of weather information

The use of scientific weather forecasts is increasing in the Tharu community despite continuing consideration of their Indigenous knowledge. Some local indicators that Tharu farmers consider the basis of their decision making in daily life are listed in Table 4. The regional weather forecast from local media is not accurate for specific locations; therefore, local knowledge remains important to farmers. The specific indicators of climate variability and local weather allow farmers to take appropriate actions to cope with the incoming changes and challenges in agriculture.

TABLE 4

Table 4. Tharu Indigenous indicators of weather and extreme events.

The Tharu in the study villages are increasingly using scientific weather information, particularly during rice cultivation and for preparedness from flooding disasters. Radio is still the most important source of information. Accessibility to radio stations and local FM on mobile phone devices has greatly increased access to weather information (Table 5). Other sources of information are social networks (friends, relatives, neighbors) and television. More than 90% of respondents receive reliable weather information in a timely manner, so they act upon it, especially in the case of flood warnings.

TABLE 5

Table 5. Top five sources to obtain weather information.

Ethnoclassification—A basis of Indigenous knowledge

Indigenous and local peoples have their own traditional ways of understanding and practicing agriculture. One of the most important aspects is grouping their understanding, knowledge and experience into the thematic categories that forms the basis for traditional classification, as was evident in the classifications of seasons and of weather indicators treated above. As these classifications reveal, the Tharu farmers have a rich knowledge of understanding on weather and agriculture, which is reflected in their classifications of seasons, agricultural land and weeds and which functions to facilitate agriculture.

Classification of agricultural land

Tharu farmers classify agricultural land into three categories—dihwa/dadwa, khetwa/khet and baggarwa—that are further divided into sub-categories associated with varying agricultural land usage. Dihwa is flat land that is not normally divided into smaller units (plots). A bund (low height, 10–15 cm) separates dihwa from the plots owned by others. There is no stagnation of rainwater in the field and traditionally no provision for irrigation. Farmers generally cultivate maize in the monsoon and mustard in the winter on such land. Residential land, gharauri, also comes under the category dihwa, which is comparatively further upland than normal dihwa land. Gharauri is the safest land and accessible by foot-trails and road.

Khetwa is wet rice land that is divided into square or rectangular-shaped small plots (350–650 m²) called oenra. Bunds are normally higher than the khetwa (about 30–50 cm height) to conserve water for rice cultivation. Irrigation is mostly feasible on this type of land, and the soil has good water-holding capacity. Khetwa is further divided into dadai khet and jabda. Dadai khet is more upland than jabda, sometimes sandy and with low water-holding capacity for 1–2 days. Jabda is lowland with blackish-colored soil that has better water-holding capacity than dadai khet. Short-duration ashan (coarse) rice is grown in dadai khet, whereas jarhan rice (late maturing, super quality fine rice) is cultivated in jabda.

Baggarwa is riverbed land that is affected by rivers and streams flooding and consequent erosion. It usually floods when the water volume increases during the monsoon. Baggarwa is further divided based on its suitability for farming. In the initial few years, rice can be grown in lowland riverbed areas, and black/green gram, lentil and linseed in upland areas in the riverbed. Baggarwa soil is sandy, so crops such as watermelon, groundnut and gourds can grow during lean periods; this is called baggar kheti (riverbed farming). Riverbed farming is one of the Indigenous knowledge-based traditional practices among the Tharu and others in the region (Gurung et al., 2014; Schiller, 2014). Bushes, shrubs and tall grasses in the baggarwa that make land not suitable for cultivation are normally called bhagraiya.

Classification of weeds and their management

Tharu farmers classify weeds based on the season of growth, crop of prevalence, habitat (herb/shrub), consumption (edible/inedible) and physical characteristics (thorny/non-thorny). The Tharu mostly classify weeds as edible or inedible. Edible weeds are further divided into edible for humans, animals, or both. Inedible weeds are noxious for both humans and animals.

Herbicides are used primarily to reduce agricultural labor due to family labor scarcity and unavailability of workers during periods of peak agricultural activities. Herbicide costs are 8–10 times cheaper than labor costs. Both pre-emergent and post-emergent herbicides are used in rice, but only post-emergent herbicides are used for wheat and maize.

The Tharu farmers use both Indigenous and scientific knowledge—hybrid knowledge—for weed management. The decision to apply herbicides is based on the crop history of the land and the weed infestation. Farmers use pre-emergence herbicides based on the weed prevalence in preceding years. However, most post-emergent applications are based on direct observations of the weed population. If <25% of the land is covered by weeds, then the weeds are removed by hand. The decision making is also based on weed vigor. If the crop is taller than the weeds and the weeds are scattered, then farmers prefer hand removal or even no weed removal. Hand removal of weeds also loosens the soil, and walking on the soil works as inter-tillage for the rice. Within the village area, anyone can harvest weeds from any field, so manual harvesting of weed grass is common for livestock. If weeds remain in the field, then farmers will use a post-emergence herbicide.

Farmers have not been fully satisfied with the results from herbicide application. Some farmers reported that pre-emergent application of herbicides during rice field preparation reduces rice yield and even affects pulse crops (lentils and peas). Bharose Tharu from Thapuwa declared, “Last year, I did not use herbicides in rice after 5 years of regular use. I had a problem with weeds, then started manual hand removal. It took us 22 days in two bigha (about 1.25 ha) of land. I couldn't use post-emergence herbicides because it had become too late to spray by the time weeds matured.”

Likewise, Binod Chaudhary from Bikri shared, “A couple of years ago, I had used a pre-emergence herbicide in rice soil that badly affected my succeeding peas and lentils. Crops grew well, but when reaching the flowering stage, they turned yellow and died. I did not get any harvest. After that, I use post-emergence herbicide by spraying mainly in rice and wheat at the early stage.”

Apart from traditional classification, there is the Indigenous knowledge system operating in crop protection and grains storage, e.g., dehari—earthen wares. Dehari is an earthen storage structure prepared at home by Tharu women. Dehari is not only used for seed and grain storage, but also as a room separator; it has cultural importance, e.g., as a wall painting, and as a type of holy bag containing a deity and divine tools (cane, swords). Dried grains are stored in air sealed conditions that are unfavorable for insects and fungi. Various traditional methods of crop protection, such as the scarecrow (jhukka), deadfall trap (odra), watch tower (atwa) and botanical pesticides are traditional ways of farming of the Tharu in western Nepal. The Tharu Indigenous ritual practices related to agriculture, such as hareri (wishing for green and productive crops along with removal of Gandhi bugs (Leptocorisa spp. or the rice ear bug), darbandhi (sealing village territory) and various non-lethal traditional techniques for crop protection, reflect and enhance their adaptive capacity. In recent decades, chemical methods have become an integral part of farming, but various non-chemical techniques are still used that support the concept of integrated pest management.

Traditional climate-resilient agricultural practices

Mixed cropping

Mixed cropping is one of the oldest farming techniques of smallholders to maintain food security, reduce the risk of crop failure, and conserve agrobiodiversity. Mixed cropping involves growing more than one crop simultaneously on the same land without row maintenance (Sekhon et al., 2007). Growing two or more crops in separate rows is known as intercropping, which is a modified version of mixed cropping (Sekhon et al., 2007).

In the study area, various combinations of mixed cropping occur, e.g., the cultivation of lentil with mustard and pea. Cereal crops (rice, wheat and maize) are generally grown as sole crops. Common mixed cropping patterns in Thapuwa and Bikri are listed in Table 6.

TABLE 6

Table 6. Cropping patterns on khetwa and dihwa at Thapuwa and Bikri.

Mixed cropping is more prevalent in Bikri (96%) than in Thapuwa (64%) (Figure 2), with an average of 82% of households in two villages cultivating lentil in mixed cropping. A yield analysis of lentil under different tillage and cropping systems is presented in Table 7. Lentil yields are significantly higher in mixed cropping (0.84 t/ha) than sole cropping (0.61 t/ha). Farmers reported that the higher lentil yields from mixed cropping than sole cropping were due to the production of two or more crops from the same piece of land, low weed infestation and few insect/disease problems.

FIGURE 2

Figure 2. Prevalence of zero-tillage and mixed cropping with lentil in the study villages.

TABLE 7

Table 7. Lentil yields under different tillage and cropping systems.

Mixed cropping is a common strategy by farmers that can be used for climate change adaptation, as it reduces the risk of total crop failure and diversifies the household food basket, contributing to food and nutritional security. One drawback of mixed cropping, especially for the medium and large farmers in the study villages, is that machine harvesting is limited to the sole crops—rice and wheat.

Relay sowing

Relay sowing is broadcast sowing of lentil, grass pea, linseed and other crops into the standing rice crop 2–3 weeks before harvest. Relay sowing is a traditional practice in the Tharu community to overcome high and low soil moisture. Broadcasting of lentil into rice is the most dominant practice, followed by grasspea, linseed and faba bean. Relaying extends the period for vegetative growth, uses residual soil moisture and reduces tillage costs compared to sole cropping (Sarker et al., 2004). Relayed crops germinate before or at the time of rice harvest; the relayed crop grows quickly after rice harvest, meeting the appropriate winter length for growth and development. Relay sowing is a no-tillage method that meets the principles of zero-tillage (minimum soil disturbance) and conservation agriculture through crop rotation and soil cover.

Relay cropping varies with soil type and the availability of irrigation. No relay sowing occurs in Thapuwa. In Bikri, about 50% of the fields are under relay crops (lentil, pea and grasspea). In Thapuwa, the soil is sandy, which is easy to till, and farmers have pumps for irrigation, so they cultivate wheat or maize after the rice harvest. In Bikri, relay-sown lentil had more uniform germination and better vegetative growth than conventionally tilled lentil.

The comparative yields of lentil under relay sowing and zero-tillage are shown in Table 7. Yields are significantly lower (0.71 t/ha) in zero-tillage including relay sowing than the conventional tillage system (0.83 t/ha), contradicting the others research findings of higher yields under zero-tillage than conventional tillage. Most zero-tillage lentil comes under relay sowing. Farmers reported that lentil production depends on the weather conditions, as some crops fail due to waterlogging.

Zero-tillage

Zero-tillage is practiced in different crops to varying degrees. In the study villages, farmers practice zero-tillage mainly for lentil and garlic. Although zero-tillage in the rice–wheat system has been widely researched in South Asia (Jat et al., 2014; Bhatta and Aggarwal, 2015; Sapkota et al., 2015), it was not practiced in the study villages. As discussed earlier in the mixed cropping section, slightly fewer households (about 45%) practiced zero-tillage than conventional tillage (55%), with lentil yields significantly lower under zero-tillage (0.71 t/ha) than conventional tillage (0.83 t/ha) (Table 7).

In the study area, farmers do not use zero-tillage equipment; instead, they practice shallow tillage with a bullock-pulled plow and tractor-driven cultivators. Many farmers also use modern inputs (seeds, inorganic fertilizers, herbicides) in combination with the traditional practice of wheat broadcast sowing, a method using one plot of land—another example of the Tharu turning to hybrid agriculture.

No-tillage (a type of zero-tillage) of garlic is an innovative practice in rice-based farming systems (Figure 3). After the rice harvest, cloves of garlic (sprouted or non-sprouted) are inserted in the harvested rice stubble and, in some cases, covered with mulch (rice straw). Tharu farmers stated that no-tillage garlic produces few weeds, conserves soil moisture and produces larger bulbs than conventional tillage-based cultivation. It also reduces the costs of tillage, irrigation and weed management, as well as increasing yield. No-tillage garlic cultivation is common in Thapuwa, but rare in Bikri, where farmers cultivate garlic in the dihwa (flat upland field) together with potato and other winter vegetable crops.

FIGURE 3

Figure 3. No-tillage garlic at Thapuwa.

Garlic is a minor crop cultivated on a small piece of land (<0.07 ha), mostly for household consumption, with excess produce sold. One farmer, Kallu Tharu, said that in the previous year he cultivated garlic on one kattha (0.03 ha), consumed much of it, distributed some to relatives, and sold 75 kg for NPR 22 per kg (USD 0.2/kg) before the Dashya festival in October.

Crop landraces

Crop biodiversity is the one of the widely used agricultural adaptations to reduce the impact of climate change (Bhatta and Aggarwal, 2015; Totin et al., 2018). Landraces may produce lower yields than improved varieties, but many have characteristics that are preferred by farmers. Some of the crop landraces and reasons for their continued use in the study area are listed in Table 8.

TABLE 8

Table 8. Landraces cultivated in Thapuwa and Bikri.

Low yields of landraces are a key challenge faced by farmers to continue their cultivation. Despite this, farmers grow local landraces for their hardiness—tolerance to high temperature, drought and waterlogging—and taste and because they lack access to improved varieties. It is predicted that the frequency of extreme climatic events such as droughts, flooding and high temperature will increase. Consequently their advantages in stress tolerance will become increasingly of value. Total crop failure does not occur for landraces under adverse climatic circumstances (drought, flooding, insect/ disease). However, Tharu farmers were found open to adopting new crop varieties, technologies and practices.

Discussion

To illustrate the links between knowledge systems, climate adaptation and mitigation, and yield/profitability, we developed a framework to compare the various agricultural practices used by Tharu farmers (Figure 4). This discussion sections present a description of components of the model, knowledge and agricultural practices, and their contribution to mitigation/adaptation and yield/profitability.

FIGURE 4

Figure 4. Role of knowledge systems in climate change adaptation and mitigation.

The framework is presented in the form of a triangle with the sides illustrating inter-relationships among different knowledge-based agricultural practices with adaptation/mitigation and yield/profitability. Agricultural practices that have been adopted in and adapted to the local environment to produce low emissions and competitive yields have led to more climate-resilient agriculture. The axis along the base of the triangle reflects knowledge across a spectrum from scientific knowledge at one end to Indigenous knowledge at the other end, with local knowledge often a synthesis of those two extremes, as the basis of agricultural practices. The left axis of the triangle represents the contribution to adaptation/mitigation, and the right axis represents yield/profitability. Various agricultural practices prevalent in the Tharu community are shown in ellipses with different colors and positions at different distances from the base of the triangle. The relative size of the ellipse represents its prevalence in farming, while color represents the form of knowledge (yellow—scientific, gray—local, and green—Indigenous); the vertical position on each ellipse indicates the level of contribution to adaptation/mitigation and profitability dimensions in agriculture. Complementarily, the horizontal position of practices implies that the practice belongs primarily to or is most related to one of the three knowledge systems along the horizontal axis. The upward direction of the black arrows, along with the signs (+ and –), indicates the direction of contribution to adaptation and mitigation and profit, with a larger contribution signified by a position toward the apex of the triangle.

To the left side of the triangle, the first group of knowledge/practices includes relay sowing, dehari (earthen grain storage structure), and riverbed farming, which are considered Tharu Indigenous agricultural practices, as they are largely exclusively practiced by the Tharu in the region. In the middle of the triangle are zero-tillage, mixed cropping, and compost use, all of which are used locally, but integrate scientific knowledge and are used in other Nepalese communities and elsewhere; therefore, these practices are considered as derived from local knowledge. The final group (use of improved seed, inorganic fertilizer, pesticide, and herbicide) on the right side of the triangle, are categorized as scientific knowledge, as their use is mostly derived from science and is widespread as a result of various development programs and interventions.

The Tharu Indigenous knowledge of weather, climate and farming/agriculture is diverse. Ethnoclassification and associated knowledge of seasons, agricultural land, and weeds are some of the key bases for climate-resilient and sustainable farming. Furthermore, Indigenous knowledge-based crop protection and management are embedded in Tharu culture and are reproduced through everyday practice and performance of various rituals. Tharu unanimously follow the traditional agricultural calendar to perform major agricultural activities. The Tharu have their own way of classifying seasons, rain and floods that help them to take appropriate actions to minimize climate-related hazards and risks. For example, when a biological indicator (e.g., behavior of insects, animals and birds) indicates severe rainfall, they prepare for safety. Similarly, wind velocity and direction help to predict frost during the winter, thereby allowing them to take appropriate measures. However, the application of Indigenous knowledge (e.g., old climate rules) for weather predictions and practices (e.g., local pest control) has been decreasing due to access to scientific information and technology. It is not so much that traditional knowledge is declining, but rather that it is evolving and in some cases integrating with scientific knowledge in hybrid forms as the climate changes and other sources of knowledge become accessible. A hybrid knowledge system that includes Indigenous knowledge and scientifically sourced knowledge now shapes Tharu agricultural practices, helping farmers to make informed decisions, thereby making agriculture resilient to climate change.

The application of information and communication technology for digital agriculture is increasing to reduce risks from climatic hazards and insect pests and diseases (Shen et al., 2010; Marvin et al., 2013). Access to information plays an important role in building perceptions and responses to climate adaptation and mitigation. Among information and communication technology tools, radio remains the most common source of information in Nepal, in terms of cost, convenience and frequency coverage. Piya et al. (2012) reported that radio, training and agriculture extension services are important sources of climate information, perception and adaptive measures among the Chepang elsewhere in Nepal. Similarly, Marvin et al. (2013) in a general review described the supportive role of various media in information dissemination during climate extremes and disasters.

The perceptions of the Tharu regarding change in the temperature has validated with the local weather station data covering 38 years. The increased monsoon temperature (June to September) has been reported for Nepal (Shrestha et al., 1999; Practical Action, 2009; DHM, 2017). Inconsistent perceptions of winter temperature (December to February) may be due to the increasing intensity of cold waves, foggy days with extended hours, and sudden drops in night temperatures that have been reported in the Tarai (Manandhar et al., 2011; Shrestha et al., 2018; Budhathoki and Zander, 2020). The perception of decreased rainfall cannot supported by the climatic data of the Bardiya because of very high year-to-year variation in rainfall. Erratic patterns of rainfall have been reported in Nepal (Practical Action, 2009; MoE, 2010; DHM, 2017). However, the perceptions of the Tharu are also in line with other Indigenous and local peoples of Nepal and India (Chaudhary and Bawa, 2011; Chaudhary et al., 2011; Piya et al., 2012). The increased temperature, erratic rainfall and droughts increase risk of crop failure and yield reduction. Hybrid knowledge and practices, such as the adoption of modern agricultural technology (e.g., irrigation, improved varieties) in traditional agricultural practices (relay sowing, mixed cropping), help to increase yield by reducing climatic risks. Knowledge hybridization at the household level is also reflected through continuing traditional practices in minor crops (e.g., lentil, pea and mustard), but adopting improved varieties in a certain percentage of their farming in major cereals (rice, wheat and maize).

The distinction between Indigenous and local agricultural practices is fuzzy in practice. However, specific Indigenous knowledge explicitly relating to the Tharu, such as the making and use of dehari (earthen grain storage; for details, see Chaudhary, 2021) and relay sowing, is considered as Tharu Indigenous knowledge. The claim to Indigenous knowledge is made based on the engagement of the Tharu in agriculture in the Tarai region of Nepal over centuries. Some other practices that are not specifically related to the Tharu and are used in the wider community are considered as local as well as traditional knowledge and practices. Local knowledge is shared by the larger local community in a particular geographical area and may also integrate scientific knowledge during the process of knowledge generation. In this sense, local knowledge itself represents a form and process of knowledge hybridization. Thus, agricultural knowledge and the practices associated with the Tharu have developed over time, as the Tharu have sought to improve and consolidate their agricultural livelihoods.

The situation of the Tharu parallels that of other Indigenous peoples in Nepal who are largely dependent on natural resources, such as the Chepang and Bote Majhi. The livelihood of Chepang depend on collection, use and marketing of non-timber forest product (NTFPs) and shifting cultivation (khoriya). Collection and selling of non-timber forest products with commercial value cannot improve livelihood of Chepang, as the selling price is currently so low that it does not cover labor cost (Piya et al., 2011). However, Pandit (2001) argues integration of NTFPs in khoriya can contribute to income as well as reduce pressure on forest resources. Similarly, traditional fishing of the Bote Majhi is constrained due to the establishment of national parks and protected areas in Nepal (Jana, 2007).

Despite the advantages regarding the adaptation and mitigation provided by Indigenous and local agricultural practices, their application has been decreasing in some contexts mainly due to their low yields and profitability. Indigenous knowledge and traditional agricultural practices are less used for major cereals, such as rice, wheat and maize, but are consistently being used for minor crops, such as lentil and pea. Farmers often practice Indigenous and scientific knowledge and practices together for the crops to cope with local challenges. Thus, different knowledge and practices complement each other for climate adaptation and resilient agriculture. Relay sowing (lentil, grass pea, linseed), zero-tillage/no-tillage (pea, garlic), and mixed cropping (any combination of lentil, pea, wheat and mustard) are some of the traditional and Indigenous crop production methods practiced in the western Tarai, Nepal. The yield and profitability of relay sowing and zero-tillage practices are not consistent, and yields are normally on a par or lower than conventional tillage-based production. This finding contradicts others in Nepal and Bangladesh (Sarker et al., 2004; Malik et al., 2016; Pokhrel and Soni, 2018), but is supported by Jat et al. (2014), who reported competitive yields under conservation agriculture (zero-tillage is a main component of conservation agriculture) in the long-term (>5 years) in a rice–wheat system on the Indo-Gangetic Plain (IGP) in India. Research shows that lentil yields under relay sowing depend on the varieties (genotypes) used, management, and other conditions (Sarker et al., 2004; Wang et al., 2012; Malik et al., 2016). In Bangladesh, lentil (improved varieties: Barimasur−2 and Barimasur−4) relayed into rice crops produced higher yields than conventional tillage of the local cultivar (Sarker et al., 2004). However, Malik et al. (2016) reported that relay-sowing the local lentil cultivar in Bangladesh was more economical (yield, >1 t/ha) than early flowering lines in sole cropping to fill the fallow gap in rice cultivation. Another study reported equal or slightly higher yields under conservation agriculture in a rice–wheat system on the IGP than conventional tillage (Sapkota et al., 2015). Farmers practice conservation agriculture mainly because of the lower production costs in rice–wheat and rice–lentil cropping systems than conventional tillage (Kumar and Ladha, 2011; Sapkota et al., 2015), but this form of agriculture can also potentially offer benefits for climate change mitigation and adaptation. Few studies have related conservation tillage to climate change mitigation, as many believe that zero/no-tillage does not play a significant role in mitigation due to the small amount of soil carbon deposition, which is often emitted during later tillage, and consider that the role of conservation agriculture has been over-emphasized (Powlson et al., 2016; Wolf et al., 2017). Farmers continue traditional agriculture practices in the absence of competitive and compatible technology despite in some cases reasonably lower yield/profitability than the scientific/modern agriculture practices.

The higher yield under mixed cropping than sole cropping is supported by other research findings. The literature indicates that mixed cropping is productive with an appropriate planting density, which is determined by the seeding rates. Mixed cropping avoids complete crop failure and increases per unit area productivity of land, and reduces weeds, pest incidence and lodging, as well as providing crop insurance against unstable market price and extreme weather conditions (Sarker et al., 2004; Lithourgidis et al., 2011; Wang et al., 2012). The relationship between conservation agriculture and climate resilience is multi-dimensional, with various positive effects on soil health, reduction of risks from pests and climatic extremes, as well as reduction of GHG emissions and energy use and higher crop quality. Most of the positive effects of relay and mixed cropping concern soil fertility improvement through integration of legumes, reduction of labor cost and energy use, the latter particularly contributing to adaptation to and mitigation of climate change (Quinn, 2009; Sapkota et al., 2015; Ladha et al., 2016).

The adoption of modern agriculture technologies, inputs and methods is increasing within the Tharu community. Adoption has been limited largely to major staple crops (rice, wheat and maize) in terms of the cultivation of improved seeds and the use of chemical inputs and irrigation technology in order to boost yields. However, the proportion of total farmland cultivated with improved varieties and the application of chemical inputs per unit area of land is negligible. These practices support small farmers to improve food security and household economy, but modern agriculture also increases dependency on production inputs (seeds, inorganic fertilizers, herbicides), as well as decreasing crop diversity. The use of improved crop varieties, agronomic management (e.g., crop rotation, adjusting sowing dates) and technology (irrigation, machinery, and information) are widely discussed strategies for climate adaptation (Nelson et al., 2009; Shen et al., 2010; Speranza, 2010; Bhatta and Aggarwal, 2015). Modern agriculture is comparatively energy-intensive, with higher emissions of GHGs, though the emissions are lower in terms of per tons of crop yield than traditional and local methods (Ladha et al., 2016). Modern agriculture often excludes legume crops (lentil, pea) in the rice system and has been promoted with an almost exclusive focus on cereal production (rice—maize) in the study area. However, the use of crop landraces not only conserves crop biodiversity, but also is a practice that continues and transfers traditional knowledge, thus contributing to its revitalization (Dahlin and Svensson, 2021). Local seeds that are adapted to harsh climatic conditions, such as emmer (Triticum dicoccon) and einkorn (Triticum monococcum) varieties of wheat that have been used in the high altitude context of Iran (Aksoy and Öz, 2020), have proved useful in modern breeding as part of the gene pool.

Conclusions

In conclusion, neither Indigenous knowledge nor scientific knowledge alone is sufficient to improve the resilience of Tharu farming communities. The Tharu have embraced “hybrid knowledge”—a combination of Indigenous and scientific knowledge, technology and practice to increase yield and maximize profit, as well as decrease vulnerability to extreme weather events. This hybridity is evident in the complementarity between the employment of modern varieties and scientific agricultural practices for the major grains and the continuing use of landraces for minor crops such as lentils, peas and mustard. In addition, the traditional pest management strategies, which often have a ritual component, are used in conjunction with botanical and chemical pesticides. Indigenous knowledge-based agriculture encourages the use of local resources, low-energy intensive practices and the conservation of crop biodiversity, which can provide diverse options within the hybrid knowledge system not only for decision making among local farmers, but also policy options at national and global levels. The integration of scientific weather information in traditional weather forecasting and the early warning system for flooding in the Tharu barghar system (village leadership) helps to cope with weather extremes and to reduce climatic risks. Similarly, hybrid agricultural practice, integrating the adoption of technology, inputs and methods in existing traditional agriculture, enhance yield and income in agriculture. The flexibility of options provided by hybrid knowledge and practice offers various choices based on household requirements, local environment and market demand from which farmers can benefit in the face of climate change.

A limitation of this research concerns the justification of local agricultural practices in the mitigation of climate change. The study did not focus on the quantitative calculation of emission reductions and mitigation potentials of local agricultural practices and technologies. Estimation at the local level could be possible, using the mitigation potential provided in similar studies as a reference. However, the figures from two small villages would be too small to generalize for the district and the country. It would be valuable to calculate the mitigation potential at a sub-national and national level using a suitable model that offers a low emissions scenario.

The research has, nevertheless, demonstrated the value of many insights from the perspective of Indigenous peoples in terms of the contribution of Indigenous knowledge and local responses in climate and agriculture for theoretical discourse regarding integration of Indigenous and scientific knowledge in hybrid knowledge systems. The deployment of such knowledge systems in resilient and climate-smart agriculture can contribute to several of the UN Sustainable Development Goals, such as (2) zero-hunger and (13) climate action, and to conservation of agro-biodiversity for future farming. In terms of policy implications, the research has documented and explored some Tharu Indigenous knowledge and practices that can be further studied in agricultural research for use in response to the needs and vulnerability of farmers in the Tarai of Nepal and elsewhere to improve their livelihoods and adaptive capacity. For the Tharu community, the research helps to identify climate-resilient knowledge, methods, technology and practices that will assist their planning for adaptation and mitigation of climate change and reduce vulnerability with support from local authorities.

Four interventions could reduce the anticipated increased vulnerability of the Tharu specifically and farmers in the Tarai in general: first, providing skill enhancement and vocational training, particularly for youth, to diversify the income of smallholders through off-farm related activities; second, continued infrastructure development for improved safety and accessibility; third, strengthening agricultural extension for resilient agriculture; fourth, recognition and promotion by the government of Nepal of the continuing value of traditional practices for at least some crops and thus the incorporation in farming extension of the value of hybrid knowledge-based practices. Local adaptations based on hybrid knowledge can contribute to the improved management of Indigenous knowledge-based traditional agriculture for continuing and future climate-resilient and climate-smart agriculture.

Data availability statement

The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.

Ethics statement

The studies involving human participants were reviewed and approved by RA/20/4133. The patients/participants provided their written informed consent to participate in this study.

Author contributions

All authors listed have made a substantial, direct, and intellectual contribution to the work and approved it for publication.

Funding

This Ph.D. research project was supported by an International Postgraduate Research Scholarship and Australia Postgraduate Award from The University of Western Australia (UWA).

Acknowledgments

We acknowledge the participating Tharu communities for their provision of information and cooperation during the fieldwork, especially the people who responded to and administered the household surveys and interviews and contributed to data organizing.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fpos.2022.969835/full#supplementary-material

Abbreviations

FGD, focus group discussion; GHGs, greenhouse gases; ha, hectare; IPCC, intergovernmental panel on climate change (IPCC); t, ton.

References

Adger, W. N. (2006). Vulnerability. Glob. Environ. Change 16, 268–281. doi: 10.1016/j.gloenvcha.2006.02.006

CrossRef Full Text | Google Scholar

Agrawal, A. (1995). Indigenous and scientific knowledge: some critical comments. Indig. Knowl. Dev. Monit. 3, 3–6.

Google Scholar

Aksoy, Z., and Öz, Ö. (2020). Protection of traditional agricultural knowledge and rethinking agricultural research from farmers' perspective: a case from Turkey. J. Rural Stud. 80, 291–301. doi: 10.1016/j.jrurstud.2020.09.017

CrossRef Full Text | Google Scholar

Andersen, A. N., Cook, G. D., Corbett, L. K., Douglas, M. M., Eager, R. W., Russell-Smith, J., et al. (2005). Fire frequency and biodiversity conservation in Australian tropical savannas: implications from the Kapalga fire experiment. Austral. Ecol. 30, 155–167. doi: 10.1111/j.1442-9993.2005.01441.x

CrossRef Full Text | Google Scholar

Bhatta, G. D., and Aggarwal, P. K. (2015). Coping with weather adversity and adaptation to climatic variability: a cross-country study of smallholder farmers in South Asia. Clim. Dev. 8, 145–157. doi: 10.1080/17565529.2015.1016883

CrossRef Full Text | Google Scholar

Bista, D. B. (1972). Peoples of Nepal. Kathmandu: Ratna Pustak Bhandar.

Google Scholar

Briggs, J. (2013). Indigenous knowledge: a false dawn for development theory and practice? Prog. Dev. Stud. 13, 231–243. doi: 10.1177/1464993413486549

CrossRef Full Text | Google Scholar

Budhathoki, N. K., and Zander, K. K. (2020). Nepalese farmers' climate change perceptions, reality and farming strategies. Clim. Dev. 12, 204–215. doi: 10.1080/17565529.2019.1612317

CrossRef Full Text | Google Scholar

Caritas (2016). Approaching Resilience: Practices and Innovations Supporting Smallholder Climate Change Adaptation. New Delhi: Caritas India.

Google Scholar

CBS (2014). Population Monograph of Nepal (Vol. II). Kathmandu: Central Bureau of Statistics (CBS), Government of Nepal.

Google Scholar

Chaudhary, B. R. (2021). Climate change perception, vulnerability and adaptive agricultural practices of the Tharu in the western Tarai of Nepal (Dissertation/ Ph.D. thesis). Perth (WA: The University of Western Australia.

Google Scholar

Chaudhary, B. R., Acciaioli, G., Erskine, W., and Chaudhary, P. (2021). Responses of the Tharu to climate change-related hazards in the water sector: indigenous perceptions, vulnerability and adaptations in the western Tarai of Nepal. Clim. Dev. 13, 816–829. doi: 10.1080/17565529.2021.1889947

CrossRef Full Text | Google Scholar

Chaudhary, M. (2008). The Tarai of Nepal and its landowners [In Nepali: Nepal ko Tarai tatha yeska bhumiputraharu]. Dang: Shanti Chaudhary, Rural Women Development Organization.

Google Scholar

Chaudhary, P., and Bawa, K. S. (2011). Local perceptions of climate change validated by scientific evidence in the Himalayas. Biol. Lett. 7, 767–770. doi: 10.1098/rsbl.2011.0269

PubMed Abstract | CrossRef Full Text | Google Scholar

Chaudhary, P., Rai, S., Wangdi, S., Mao, A., Rehman, N., Chettri, S., et al. (2011). Consistency of local perceptions of climate change in the Kangchenjunga Himalaya landscape. Curr. Sci. 2011, 504–513. Available online at: http://www.jstor.org/stable/24078981

Google Scholar

Conklin, H. C. (1957). Hanunoo Agriculture. A Report on an Integral System of Shifting Cultivation in the Philippines. Rome: Food and Agriculture Organization of the United Nations (FAO).

Google Scholar

Conklin, H. C. (1980). Ethnographic Atlas of Efugao. New Haven, CT; London: Yale University Press.

Google Scholar

Creswell, J. W., and Plano Clark, V. L. (2011). Designing and Conducting Mixed Methods Research, 2nd Edn. Los Angeles, CA: SAGE.

Google Scholar

DADO Bardiya (2015). Annual Agriculture Development Programme and Statistics Book. Gulariya, Bardiya, Nepal: District Agriculture Development Office (DADO), Government of Nepal.

Google Scholar

Dahlin, J., and Svensson, E. (2021). Revitalizing traditional agricultural practices: conscious efforts to create a more satisfying culture. Sustainability 13, 11424. doi: 10.3390/su.132011424

CrossRef Full Text | Google Scholar

DDC Bardiya (2013). District Profile and Resource Map [In Nepali: Jilla Bastugat Bibaran, 2071 B.S.] Gulariya, Bardiya: District Development Committee (DDC) Bardiya, Government of Nepal.

Google Scholar

Devkota, R. P., Bajracharya, B., Maraseni, T. N., Cockfield, G., and Upadhyay, B. P. (2011). The perception of Nepal's Tharu community in regard to climate change and its impacts on their livelihoods. Int. J. Environ. Stud. 68, 937–946. doi: 10.1080/00207233.2011.587282

CrossRef Full Text | Google Scholar

Dewalt, B. (1994). Using indigenous knowledge to improve agriculture and natural resource management. Hum. Organ. 53, 123. doi: 10.17730/humo.53.2.ku60563817m03n73

CrossRef Full Text | Google Scholar

DHM (2017). Observed Climate Trend Analysis in the Districts and Physiographic Regions of Nepal (1971-2014). Kathmandu, Nepal: Department of Hydrology and Meteorology (DHM), Ministry of Population and Environment, Government of Nepal.

Google Scholar

DoFRS (Cartographer) (2019). Gulariya Nagarpalika, Bardiya, Province-5. Department of Forest Research and Survey (DoFRS), Ministry of Forest and Environment, Government of Nepal.

Google Scholar

Ellen, R. (2007). “Introduction,” in Modern Crises and Traditional Strategies: Local Ecological Knowledge in Island Southeast Asia, ed R. Ellen (New York, NY: Berghahn Books), 1–10. doi: 10.1515/9780857452832-005

CrossRef Full Text | Google Scholar

FAO (2004). What is local knowledge. Food and Agriculture Organization of the United Nations (FAO). Available online at:http://www.fao.org/tempref/docrep/fao/007/y5610e/y5610e00.pdf (accessed March 24, 2017).

Google Scholar

Finucane, M. (2009). Why science alone won't solve the climate crisis: managing climate risks in the Pacific. Available online at: http://hdl.handle.net/10125/11545 (accessed August 20, 2020).

Google Scholar

Folke, C. (2006). Resilience: the emergence of a perspective for social–ecological systems analyses. Glob. Environ. Change 16, 253–267. doi: 10.1016/j.gloenvcha.2006.04.002

CrossRef Full Text | Google Scholar

Galloway McLean, K. (2009). Advanced Guard: Climate Change Impacts, Adaptation, Mitigation and Indigenous Peoples – A Compendium of Case Studies (UNU-IAS Ed.). Darwin: United Nations University (UNU) - Institute of Advanced Studies (IAS), Traditional Knowledge Initiative.

Google Scholar

Gathala, M. K., Timsina, J., Islam, M. S., Rahman, M. M., Hossain, M. I., Harun-Ar-Rashid, M., et al. (2015). Conservation agriculture based tillage and crop establishment options can maintain farmers' yields and increase profits in South Asia's rice–maize systems: evidence from Bangladesh. Field Crops Res. 172, 85–98. doi: 10.1016/j.fcr.2014.12.003

CrossRef Full Text | Google Scholar

Government of Nepal and UNDP (2014). Nepal human development report 2014: beyond geography, unlocking human potential. Kathmandu: National Planninjg Commission (NPC)/ Government of Nepal, United Nations Development Programme (UNDP).

Google Scholar

Guneratne, A. (1998). Modernization, the state, and the construction of a Tharu identity in Nepal. J. Asian Stud. 57, 749–773. doi: 10.2307/2658740

CrossRef Full Text | Google Scholar

Guneratne, A. (2002). Many Tongues, One People: The Making of Tharu Identity in Nepal. Ithaca, NY; London: Cornell University Press. doi: 10.7591/9781501725302

CrossRef Full Text | Google Scholar

Gurung, G. B., Pande, D. P., and Khanal, N. P. (2014). “Riverbed vegetable farming for enhancing livelihoods of people: a case study in the Tarai region of Nepal,” in Communities and Livelihood Strategies in Developing Countries, ed K. L. Maharjan (Tokyo: Springer). doi: 10.1007/978-4-431-54774-7_7

CrossRef Full Text | Google Scholar

IPCC (2007). Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of working group II to the fourth assessment report of the intergovernmental panel on climate change (M. Parry, O. Canziani, J. Palutikof, P.v.d. Linden, and C. Hanson eds.). Cambridge, UK: Cambridge University Press.

Google Scholar

IPCC (2014). Climate Change 2014: Synthesis Report. Contribution of working groups I, II and III to the fifth assessment report of the intergovernmental panel on climate change (Core writing team, R.K. Pachauri, and L.A. Meyer eds.). Geneva: Cambridge University Press.

Google Scholar

Jana, S. (2007). Local movement of indigenous fishing communities around Chitwan National Park. Sustainable Mountain Development, 30. Available online at: https://lib.icimod.org/api/files/32182fc2-b0c3-467a-993d-c14f0e795c7a/c_attachment_525_4889.pdf (accessed November 11, 2022).

Google Scholar

Jat, R. K., Sapkota, T. B., Singh, R. G., Jat, M. L., Kumar, M., and Gupta, R. K. (2014). Seven years of conservation agriculture in a rice–wheat rotation of Eastern Gangetic Plains of South Asia: yield trends and economic profitability. Field Crops Res. 164, 199–210. doi: 10.1016/j.fcr.2014.04.015

CrossRef Full Text | Google Scholar

Kimber, R. (1983). Black lightning: aborigines and fire in central Australia and the western desert. Archaeol. Oceania 18, 38–45. doi: 10.1002/arco.1983.18.1.38

CrossRef Full Text | Google Scholar

Kumar, V., and Ladha, J. K. (2011). Direct seeding of rice: recent developments and future research needs. Adv. Agron. 111, 297–413. doi: 10.1016/B978-0-12-387689-8.00001-1

CrossRef Full Text | Google Scholar

Ladha, J. K., Rao, A. N., Raman, A. K., Padre, A. T., Dobermann, A., Gathala, M., et al. (2016). Agronomic improvements can make future cereal systems in South Asia far more productive and result in a lower environmental footprint. Glob. Chang. Biol. 22, 1054–1074. doi: 10.1111/gcb.13143

PubMed Abstract | CrossRef Full Text | Google Scholar

Lithourgidis, A., Dordas, C., Damalas, C. A., and Vlachostergios, D. (2011). Annual intercrops: an alternative pathway for sustainable agriculture. Aust. J. Crop Sci. 5, 396. doi: 10.3316/informit.281409060336481

PubMed Abstract | CrossRef Full Text | Google Scholar

Maharjan, S. K., Sigdel, E. R., Sthapit, B. R., and Regmi, B. R. (2011). Tharu community's perception on climate changes and their adaptive initiations to withstand its impacts in Western Terai of Nepal. Int. NGO J. 6, 35–42. doi: 10.5897/NGO10.003

CrossRef Full Text | Google Scholar

Malik, A. I., Ali, M. O., Zaman, M. S., Flower, K., Rahman, M. M., and Erskine, W. (2016). Relay sowing of lentil (Lens culinaris subsp. culinaris) to intensify rice-based cropping. J. Agric. Sci. 154, 850–857. doi: 10.1017/S0021859614001324

CrossRef Full Text | Google Scholar

Manandhar, S., Vogt, D., Perret, S., and Kazama, F. (2011). Adapting cropping systems to climate change in Nepal: a cross-regional study of farmers' perception and practices. Reg. Environ. Change 11, 335–348. doi: 10.1007/s10113-010-0137-1

CrossRef Full Text | Google Scholar

Marvin, H. J. P., Kleter, G. A., Noordam, M. Y., Franz, E., Willems, D. J. M., and Boxall, A. (2013). Proactive systems for early warning of potential impacts of natural disasters on food safety: climate-change-induced extreme events as case in point. Food Control 34, 444–456. doi: 10.1016/j.foodcont.2013.04.037

CrossRef Full Text | Google Scholar

Modiano, G., Morpurgo, G., Terrenato, L., Novelletto, A., Di Rienzo, A., Colombo, B., et al. (1991). Protection against malaria morbidity: near-fixation of the α-thalassemia gene in a Nepalese population. Am. J. Hum. Genet. 48, 390.

PubMed Abstract | Google Scholar

MoE (2010). National Adaptation Programme of Action (NAPA) to Climate Change. Kathmandu: Ministry of Environment (MoE), Government of Nepal.

Google Scholar

Müller-Böker, U. (1997). “Tharus and Pahariyas in Chitawan: observations on the multi-ethnic constellation in southern Nepal,” in Perspectives on History and Change in the Karakorum, Hindukush, and Himalaya (Vol. 3), eds I. Stellrecht, and M. Winiger (Koln: Culture Area Karakorum, Scientific Studies, 3), 157–169.

Google Scholar

Müller-Böker, U. (1999). The Chitwan Tharus in Southern Nepal: An Ethno Ecological Approach. Stuttgart: Franz Steiner Verlag.

Google Scholar

Nelson, G., Rosegrant, M., Koo, J., Robertson, R., Sulser, T., Zhu, T., et al. (2009). Climate Change: Impact on Agriculture and Costs of Adaptation. IDEAS Working Paper Series from RePEc.

Google Scholar

Neuman, W. L. (2004). Basics of Social Research: Qualitative and Quantitative Approaches, 2nd Edn. Boston, MA: Pearson Education, Inc.

Google Scholar

Pandit, B. H. (2001). Non-timber forest products on shifting cultivation plots (khoriya): a means of improving livelihood of Chepang Rural Hill Tribe of Nepal. Asia Pac. J. Rural Dev. 11, 1–14. doi: 10.1177/1018529120010101

CrossRef Full Text | Google Scholar

Piya, L., Maharjan, K. L., and Joshi, N. P. (2012). Perceptions and realities of climate change among the Chepang communities in rural Mid-Hills of Nepal. J. Contemp. India Stud. 2, 35–50.

Google Scholar

Piya, L., Maharjan, K. L., Joshi, N. P., and Dangol, D. R. (2011). Collection and marketing of non-timber forest products by Chepang community in Nepal. J. Agric. Environ. 12, 10–21. doi: 10.3126/aej.v12i0.7558

CrossRef Full Text | Google Scholar

Pokhrel, A., and Soni, P. (2018). An investigation into a resource and environmentally sustainable system: zero-tillage lentil and garlic production in Nepal. Agroecol. Sust. Food Syst. 42, 982–1002. doi: 10.1080/21683565.2018.1487359

CrossRef Full Text | Google Scholar

Porter, J. R., Xie, L., Challinor, A. J., Cochrane, K., Howden, S. M., Iqbal, M. M., et al. (2014). “Food security and food production systems,” in Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, eds C. B. Field, V.R. Barros, D.J. Dokken, K.J. Mach, M.D. Mastrandrea, T.E. Bilir, et al. (Cambridge, UK; New York, NY, USA: Cambridge University Press).

PubMed Abstract | Google Scholar

Powlson, D. S., Stirling, C. M., Thierfelder, C., White, R. P., and Jat, M. L. (2016). Does conservation agriculture deliver climate change mitigation through soil carbon sequestration in tropical agro-ecosystems? Agric. Ecosyst. Environ. 220, 164–174. doi: 10.1016/j.agee.2016.01.005

CrossRef Full Text | Google Scholar

Practical Action (2009). Temporal and Spatial Variability of Climate Change Over Nepal (1976–2005). Kathmandu, Nepal: Practical Action Nepal Office.

Google Scholar

Quinn, M. A. (2009). “Biological nitrogen fixation and soil health improvement,” in The Lentil - Botany, Production and Uses, eds F. J. M. W. Erskine, A. Sarker, and B. Sharma (Wallingford, CT: Comm Agric Bureau Int.), 229–247. doi: 10.1079/9781845934873.0229

CrossRef Full Text | Google Scholar

Rajaure, D. P. (1981). Tharus of Dang: the people and the social context. Kailash 8, 155–181.

Google Scholar

RKJS/Practical Action (2013). Participatory Vulnerability and Adaptation Capacity Analysis. Radhakrishna Tharu Jansewa Kendra (RKJS) and Practical Action. Gulariya, Bardiya, Nepal.

Google Scholar

Sapkota, T. B., Jat, M. L., Aryal, J. P., Jat, R. K., and Khatri-Chhetri, A. (2015). Climate change adaptation, greenhouse gas mitigation and economic profitability of conservation agriculture: some examples from cereal systems of Indo-Gangetic Plains. J. Integr. Agric. 14, 1524–1533. doi: 10.1016/S2095-3119(15)61093-0

CrossRef Full Text | Google Scholar

Sarker, A., Erskine, W., Abu Bakr, M., Matiur Rahman, M., Ali Afzal, M., and Saxena, M. C. (2004). Lentil improvement in Bangladesh. A success story of fruitful partnership between the Bangladesh Agricultural Research Institute and the International Center for Agricultural Research in the Dry Areas. APAARI Publication 1, 1–38. Available online at: http://www.apaari.org/web/wp-content/uploads/2009/05/ss_2004_01.pdf (accessed June 06, 2019).

Google Scholar

Schiller, K. (2014). Assessing the sustainability of leasehold riverbed vegetable farming for landless and land-poor households in the Terai of Nepal (Master's thesis). University of Hohenheim, Hohenheim, Germany.

Google Scholar

Sekhon, H. S., Singh, G., and Ram, H. (2007). “Lentil-based cropping systems,” in Lentil: An Anicient Crop for Modern Times, eds S. S. Yadav, D. McNeil, and P. C. Stevension (Dordrecht: Springer), 123–142.

Google Scholar

Shen, S., Basist, A., and Howard, A. (2010). Structure of a digital agriculture system and agricultural risks due to climate changes. Agric. Agric. Sci. Proc. 1, 42–51. doi: 10.1016/j.aaspro.2010.09.006

CrossRef Full Text | Google Scholar

Shrestha, A. B., Wake, C. P., Mayewski, P. A., and Dibb, J. E. (1999). Maximum temperature trends in the Himalaya and its vicinity: an analysis based on temperature records from Nepal for the period 1971–94. J. Clim. 12, 2775–2786.

Google Scholar

Shrestha, S., Moore, G. A., and Peel, M. C. (2018). Trends in winter fog events in the Terai region of Nepal. Agric. Forest Meteorol. 259, 118–130. doi: 10.1016/j.agrformet.2018.04.018

CrossRef Full Text | Google Scholar

Sillitoe, P. (2007). “Local vs global science: an overview,” in Local Science vs Globa Science: Approaches to Indigenous Knowledge in International Development (Vol. Studies in Environmental Anthropology and Ethnobiology), ed P. Sillitoe (Oxford: Berghahn Books), 1–22. doi: 10.1515/9781782382102-005

CrossRef Full Text | Google Scholar

Sillitoe, P. (2017). Indigenous Knowledge: Enhancing Its Contribution to Natural Resources Management. Wallingford, CT, Oxfordshire: CABI. doi: 10.1079/9781780647050.0000

CrossRef Full Text | Google Scholar

Speranza, C. I. (2010). Resilient Adaptation to Climate Change in African Agriculture. Bonn: German Development Institute/Deutsches Institut für Entwicklungspolitik (DIE). Available online at: http://hdl.handle.net/10419/199179 (accessed August 04 2020).

Google Scholar

Sterrett, C. (2011). Review of Climate Change Adaptation Practices in South Asia. Available online at: https://www-cdn.oxfam.org/s3fs-public/file_attachments/rr-climate-change-adaptation-south-asia-161111-en_3.pdf (accessed August 04, 2020).

PubMed Abstract | Google Scholar

Technology Need Assessment (2017). From Needs to Implementation: Stories From the Technology Needs Assessments, eds S. Bee, S. Traeru, and V. Hecl (Copenhagen, Denmark: United nations Energy Programme (UNEP DTU Parthership).

Google Scholar

Thurston, H. D. (1990). Plant disease management practices of traditional farmers. Plant Dis. 74, 96–102. doi: 10.1094/PD-74-0096

CrossRef Full Text | Google Scholar

Totin, E., Segnon, A. C., Schut, M., Affognon, H., Zougmoré, R. B., Rosenstock, T., et al. (2018). Institutional perspectives of climate-smart agriculture: a systematic literature review. Sustainability 10, 1990. doi: 10.3390/su10061990

CrossRef Full Text | Google Scholar

Van Vliet, N., Mertz, O., Heinimann, A., Langanke, T., Pascual, U., Schmook, B., et al. (2012). Trends, drivers and impacts of changes in swidden cultivation in tropical forest-agriculture frontiers: a global assessment. Glob. Environ. Change 22, 418–429. doi: 10.1016/j.gloenvcha.2011.10.009

CrossRef Full Text | Google Scholar

Wang, L., Gruber, S., and Claupein, W. (2012). Optimizing lentil-based mixed cropping with different companion crops and plant densities in terms of crop yield and weed control. Org. Agric. 2, 79–87. doi: 10.1007/s13165-012-0028-5

CrossRef Full Text | Google Scholar

Warren, D. M. (1991). Using Indigenous Knowledge in Agricultural Development. Washington, DC: The World Bank.

Google Scholar

Wiraguna, E., Malik, A. I., and Erskine, W. (2017). Waterlogging tolerance in lentil (Lens culinaris Medik. subsp. culinaris) germplasm associated with geographic origin. Genet. Resour. Crop Evol. 64, 579–586. doi: 10.1007/s10722-016-0385-0

CrossRef Full Text | Google Scholar

Wolf, K., Herrera, I., Tomich, T. P., and Scow, K. M. (2017). Long-term agricultural experiments inform the development of climate-smart agricultural practices. California Agric. 71, 120–124. doi: 10.3733/ca.2017a0022

CrossRef Full Text | Google Scholar

World Bank (2004). Indigenous Knowledge: Local Pathways to Global Development - Marking Five Years of the World Bank Indigenous Knowledge for Development Program. Washington, DC: The World Bank.

Google Scholar

Woytek, R. (1998). Indigenous Knowledge for Development: A Framework for Action. Washington, DC: Knowledge and Learning Center, African Region, The World Bank.

Google Scholar

Appendix 1

APPENDIX 1

Appendix 1. Comparison of crop calendar (current and 20 years ago) in Bardiya, Nepal.