Introduction

Coffee is among the top traded agricultural commodities in the world1. Climate variability and change are increasingly threatening the profitability and sustainability of the coffee industry2,3,4,5,6. Prolonged droughts and high temperatures during the crop season, in combination with heavy rains and frosts, not only affect blossoming and fruit setting but also cherry development and filling, thereby reducing coffee bean yield and/or decreasing bean quality4,7,8,9,10. With longer and more intense droughts coupled with higher temperatures increasing across most of the world’s coffee growing areas11,12, strategies such as relocation of coffee farming, adapting coffee farming practices and/or the development of new coffee crops are being developed to ensure the sustainability and profitability of coffee production in the future13,14.

Agroforestry is a potential management strategy for mitigating climate variability and change impacts in coffee farming systems13,15,16,17. Coffee-based agroforestry systems (CAFS) consist of coffee intercropped with a diverse canopy of native or nonnative forest trees in high to moderate shade, with varying shade cover management. There are various benefits of CAFS, including improved soil chemical and physical properties, the creation of a microclimate at the farm level that can lower soil and air temperatures and acts as a buffer against extreme temperature fluctuations within the farm, and an increase in ecosystem productivity per area13,15,18,19. CAFS can also provide additional income to farmers20,21. However, similar to any other ecosystem, CAFS are vulnerable to large-scale annual and multi-year fluctuations in weather and climate. In countries that manage diverse shade trees in all or parts of their coffee-producing regions (i.e., India, Colombia, Haiti)22, the vulnerability of these managed ecosystems to climate is expected to increase over the coming decades23,24,25. The appropriate scale at which to describe the impact of climate on coffee under the scope of varying CAFS set-ups needs, therefore, explicit investigation.

When assessing climate risks and climate change impacts on coffee, studies have mostly focused on either the suitability of land areas for coffee production2,16,26 or the assessment of potential coffee yield under projected climate conditions4,27,28, the exposure and vulnerability of coffee-producing regions to changes in climate hazards29 or the proportion of variation in coffee yield explained by climate predictors (i.e., rainfall and temperature)30,31. However, the risks associated with climate variability at different spatial scales in CAFS under various management practices have yet to be fully investigated.

At different scales, climate risks such as excess or deficit rainfall, dry spells or frosts, may differ depending on the topographical characteristics and the management practices that dominate the CAFS. If climate impacts vary considerably between scales, i.e., the particular climate driver(s) most important for yield vary, then extrapolating findings from global and country-level studies2,4,9,31 may have limited utility for informing smaller farm-scale climate adaptation responses. Likewise, smaller experimental and farm-scale studies32 may not be relevant for understanding the larger scale regional and global impacts of climate change. Understanding the impact of climate at different spatial scales is therefore crucial for accurately assessing the threat current and future climate variability pose to CAFS.

In this study, climate risk impacts on robusta coffee (Coffea canephora Pierre ex A. Froehner) yield at different spatial scales in CAFS were investigated for the key robusta coffee-growing regions in India, the third largest Asian robusta coffee-producing country33. Robusta coffee production in India accounts for approximately 70% of the national production, for an average annual cultivated land area estimated ca. 237,000 ha (that is, approximately 50% of the national coffee acreage)34.

In India, coffee is grown under native and nonnative shade tree cover and presents a range of management practices across different landscapes21,35, making it an ideal system for investigating climate impacts at different scales. In the study we hypothesized that climate risks and their impact on coffee yield would vary across spatial scales, i.e., within and across regions. Therefore, mitigation and adaptation strategies must be designed and implemented accordingly. Agroforestry is pivotal to the success and sustainability of Indian coffee farming systems since it helps protect against the adverse effects of prolonged dry spells and hot summers, particularly during the dry season (November–March)6,21. The findings of this study could inform and support spatial planning and actions for improved climate risk management at multiple spatial scales in robusta CAFS in India and other coffee-producing countries around the world.

Methods

Study area

Data were collected from 314 coffee farmers across the districts of Chikmagalur, Coorg (Karnataka state), and Wayanad (Kerala state) in India (Fig. 1) during the 2015/2016 to 2017/2018 coffee seasons. Karnataka and Kerala are the main robusta coffee-producing states in India and account for 93% of national production34. The robusta coffee calendar in the study regions can be roughly divided into four periods: the January to April period, during which flower-bud initiation, blossoming, and fruit setting occur; the May to October period, encompassing cherry development and maturation; the October to December period, encompassing ripening and harvest; and the dormancy stage from December to January36. In Wayanad, coffee is grown in rainfed conditions, whereas in Chikmagalur and Coorg supplemental deficit irrigation is adopted, namely, to trigger flowering when blossom showers (occurring generally during March–April) are not sufficient. Robusta coffee flowering in the study regions usually falls during the dry season and coincides with the summer months30, with backing showers needed within 20–25 days of first blossom showers to allow for good fruit setting36.

Figure 1
figure 1

The study regions and spatial distribution of the surveyed robusta coffee farms across the districts of Chikmagalur, Coorg (Karnataka state) and Wayanad (Kerala state) in India. The total number of surveyed farmers each year was 122, 146, and 46 in Chikmagalur, Coorg, and Wayanad, respectively.

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Farm data

Farm level data were collected using designed questionnaires. The sampling was performed to represent the range of farm sizes and crop management practices. Coffee farmers kept their farm activity records using bookkeeping, which is also valuable for coffee certification and traceability programmes. The surveyed farmers were selected so as to represent the range of climate, the proportion of coffee growing area, use of irrigation water, and farming systems. The questionnaire was reviewed and approved by the ethical committee of ECOM Agroindustrial Corp. Ltd. Data collection was carried out in accordance with relevant guidelines and regulations. Informed consent was obtained from all participants before the interview.

The total number of farmers surveyed each year was 122, 146, and 46 in Chikmagalur, Coorg, and Wayanad, respectively; that is 942 observational data records for the three coffee seasons. Data collected included farm characteristics (farm size, type of shade trees—native or exotic tree species), crop management practices (plant density, fertilizer types and rates, pest and disease management strategies, irrigation water use), and production data (i.e., annual coffee bean yield). The surveyed coffee farms were composed of robusta coffee and native tree species, with tree spacings of 3 m × 3 m and 12 m × 14 m for coffee and shade trees, respectively36. All the data were anonymised before any analysis was performed in this study.

Climate data

Monthly climate data for the period 1985–2018, sourced from the TerraClimate dataset (~ 4 km resolution)37,38, were used. Climate projections for the study area were for two levels of change in global climate corresponding to (1) baseline conditions representing those from 1985 to 2015 and (2) a global mean temperature 2 °C above the preindustrial period (1850–1879)37,38. The approach from Refs.37,38 for developing future climate projections uses monthly data from 23 Coupled Model Intercomparison Project 5 (CMIP5) climate models and observational records to scale changes in individual climate variables38. Details of the pattern scaling approach, as well as information about the 23 different Coupled Model Intercomparison Project 5 (CMIP5) climate models used, are provided in Ref.38.

In this study, we focused on the flowering (January–April) and post-flowering (May–August) periods as this is when coffee production is most sensitive to climatic variability4,8. For each farm, the total rainfall, mean, minimum and maximum temperatures were computed each year for the flowering and post-flowering periods. Variations in each of the climate predictors for the period 2015–2018 are presented in Fig. 2.

Figure 2
figure 2

Distribution of mean maximum and minimum temperatures, and total rainfall across the Chikmagalur, Coorg, and Wayanad districts in India for the period 2015–2018. (ac): values during the flowering period (January–April); (df): values during the post-flowering period (May to August). In a boxplot, the top and bottom of the box represent the 75th and 25th percentiles, respectively; the solid line indicates the median. The whiskers on the top and bottom represent the largest and smallest values within the 1.5 times interquartile range above the 3rd and 1st quantiles, respectively. Black points are outliers.

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Data analysis

Climate impacts were assessed at two different scales: (1) regional, encompassing the entire study region and including all sample farms, and (2) district, covering the three distinct districts of Chikmagalur, Coorg and Wayanad (Fig. 1). All data analyses were carried out in R39.

Identifying the key climate drivers of robusta coffee production

A generalized additive regression model (GAM)40,41 and multimodel selection42 were used to identify the key climate drivers of coffee yield. In the GAM coffee yield was modeled as a nonlinear function of climate variables for each site and year using a scaled t distribution to account for the heavy tailed distribution of yield data. A random effect for each site and year was included to account for the repeat measurements for each year at the district level. Random effects control for non‐independence by constraining non‐independent observations to have the same intercept43. For example, yield observations from a particular district, may be more similar (e.g., higher on average if soils and management techniques are better) relative to yield observations from other areas. There were six potential climate predictors (maximum temperature, minimum temperature, and total rainfall for both the flowering and post-flowering periods) in the global model.

To select the best climate predictor(s) for each of the periods (flowering and post-flowering) the second-order Akaike Information Criterion (AICc)-based model selection42 was used. This approach tests all possible model combinations of predictors and provides an AICc for these, which is used to rank model performance or parsimony. AICc is a stricter form of AIC and accounts well for situations when there are limited sample sizes42, as occurs here for our smaller-scale analyses. As with AIC, lower AICc values indicate better model performance and model parsimony. From model selection based on AICc, the most parsimonious model, that is, the one with the lowest AICc was selected. Model selection also accounted for collinearity, with no predictors with a Pearson coefficient of correlation > 0.7 being included in any of the models tested44. AICc-based model selection was performed using the ‘MuMIn’ package45.

Assessing the impacts of climate change scenarios on robusta coffee yield across different spatial scales

The best models selected for the regional scale (all sample farms within the Karnataka and Kerala states) and district scale (sample farms for each of the three districts Chikmagalur, Coorg, and Wayanad) were used to assess the percentage change in robusta coffee yield across the study area in the future under two different scenarios corresponding to (1) baseline conditions (1985–2015) and (2) projections under a global mean temperature scenario of 2 °C. Under each scenario, we projected a percentage change in yield based on the best model for each district and the regional model, which encompassed all districts.

Results

Key climate drivers of robusta coffee yield variability across scales

The key drivers of robusta coffee yields in the CAFS we assessed across India varied considerably (Tables 1 and 2). At the regional scale encompassing our entire study region (Karnataka and Kerala states), post-flowering maximum temperatures were the most important climate driver of coffee yields (Table 1). In contrast, at the smaller district scale in Wayanad and Coorg, only rainfall-related variables were selected in the best models for explaining variation in coffee yields (Table 1).

Table 1 Model selection results (showing all models < delta 2) at the district level and across all regions combined.
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Table 2 Statistical indicators of the best selected models at the combined regional and district levels.
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Regional-scale yield variation is best explained by post-flowering season temperature variation

At the regional scale, higher mean maximum temperatures were linearly and negatively related to yields (Fig. 3). In the post-flowering season, yields for mean maximum temperature of 28 °C were predicted to be approximately 700 kg/ha lower than those for a mean maximum temperature of 23 °C. Each degree increase in mean maximum temperatures, therefore, corresponded to an approximately 140 kg/ha decline in coffee yield (Fig. 3).

Figure 3
figure 3

The relationship between post-flowering mean maximum temperature and robusta coffee yield at the regional level (across all farms assessed in the study). The shaded area is the 95% confidence interval from the model predictions.

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District-level yields are best explained by rainfall

In contrast to the regional scale models, district-level yields were best explained by variations in rainfall (Fig. 4). In Wayanad, rainfall was a key predictor of yield variation in both the flowering and post-flowering periods (Fig. 4a, b). The relationship between rainfall and robusta coffee yields was negative during flowering; that is, higher rainfall corresponded to lower coffee yields (Fig. 4a). The opposite (higher rainfall corresponded to higher coffee yields) was found for the post-flowering period. During the post-flowering period in Wayanad, there was also a notable nonlinear relationship between rainfall and coffee yield, such that yields did not begin to decline until rainfall fell below 3000 mm (Fig. 4b). Once rainfall fell below 3000 mm, yields declined strongly, by approximately 400 kg/ha as rainfall declined to 2000 mm (Fig. 4b).

Figure 4
figure 4

Relationships between robusta coffee yield and key climate drivers identified through model selection at the district level (see Table 1) for (a) flowering rainfall and (b) post-flowering rainfall in Wayanad. The shaded area in the figure represents the 95% confidence interval from the model predictions.

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In Coorg, rainfall was also important, but only during the flowering period. There was a distinct inverted ‘U’ relationship between flowering total rainfall and coffee yield for that district (Fig. 5). Increasing rainfall from 80 to 100 mm corresponded to increased coffee yield, at which point the yield plateaued, and further rainfall (rainfall above 100 mm) was predicted to decrease yields. The lowest coffee yields (~ 1500 kg/ha) were predicted to occur at the highest flowering period rainfall observations (> 160 mm) (Fig. 5). In Chikmagalur, maximum temperature was the only variable identified in the best model, but its relationship with robusta coffee yield was not statistically significant (p > 0.05; Table 2).

Figure 5
figure 5

The relationship between the key climate drivers of robusta yield at the district level identified in Coorg. The shaded area in the figure represents the 95% confidence interval from the model predictions.

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Impacts of climate change scenarios on robusta coffee yield across different spatial scales

The projected impacts of climate change on robusta coffee yields vary depending on whether district-level or regional-level models are utilised. At the district level where rainfall was identified as the key limiting factor of robusta coffee yields, virtually no impact on yields is anticipated in Coorg under a 2 °C warming scenario (Fig. 6a). In contrast, at Wayanad, slight positive changes (up to 5%) were found under a 2 °C warming scenario relative to the baseline (1985–2015) climatic conditions (Fig. 6b). In contrast, when projecting from the regional scale model, for which post-flowering maximum temperature was identified as the key limiting factor on production, the results showed decreases in robusta coffee yields under a 2 °C warming scenario for both Coorg and Waynad (Fig. 6). The median changes were − 7% and − 12% for Coorg and Waynad, respectively, with higher decreases found in the latter district (Fig. 6b).

Figure 6
figure 6

Boxplots showing the distribution of projected percentage changes in robusta coffee yield under a 2 °C global warming relative to baseline (1985–2015) climatic conditions for the best model at the district level and regional level for (a) Coorg and (b) Wayanad. No results are shown for Chickmagalur as there were no climate variables significantly related to yield at the district level for this area (p > 0.05; Table 2). In the boxplots, the top and bottom of the box represent the 75th and 25th percentiles, respectively; the solid line indicates the median. The whiskers on the top and bottom represent the largest and smallest values within the 1.5 times interquartile range above the 3rd and 1st quantiles, respectively. Black points are outliers.

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The spatial distribution of the projected changes in robusta coffee yields at the district and regional scales is presented in Fig. 7. Irrespective of the scale, there were no distinct spatial patterns across the study districts. For instance, when using the regional-level model for Coorg, projected decreases of 15% and 30% were found for multiple farms within the same vicinity (Fig. 7).

Figure 7
figure 7

The spatial distribution of the projected mean change (%) in robusta coffee yield for each farm under a 2 °C global warming scenario relative to baseline (1985–2015) climatic conditions for the best model at the district scale in (a) Coorg and (b) Wayanad, and (c) the regional scale (all data pooled). Note that for the district-level model, no results are shown for Chickmagalur, as there were no climate variables significantly related to yield for this area (p > 0.05; Table 2).

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Discussion

The risks associated with climate variability and change during the flowering and post-flowering periods on robusta coffee production at different spatial scales were investigated. The results showed varying scale-dependent relationships between robusta coffee yield and flowering and post-flowering rainfall and temperature variables in the study areas. At the regional scale (pooled data for all three districts), post-flowering maximum temperature was selected as the best variable explaining the variability in robusta coffee yield, with lower maximum temperatures being associated with higher yields. These results concur with previous findings indicating that high temperatures adversely impact robusta coffee yield7,31,46,47. Bud development and berry filling, two key yield determinants in coffee yield, can be drastically and negatively affected under high temperature conditions7,46, which may explain the relationships observed in this study.

At the district scale (i.e., in coffee farms within each district), variations in rainfall during flowering mostly explained the variability in robusta CAFS across the study area. Negative impacts of relatively higher rainfall during flowering on robusta coffee yield were found across Coorg and Wayanad. Such results are in line with other work46,47. This could be related to various factors including reduced pollination potential and abortion of flowers in the case of intense rainfall early and late flowering, respectively, which both result in lower overall fruit set and low final yield10,15. On the other hand, good rainfall conditions during the post-flowering period yielded better robusta coffee productivity, namely, across Wayanad, where robusta coffee is typically grown under rainfed conditions. Good rainfall conditions are most often beneficial to cherry development in robusta coffee8,15, although such conditions can be conducive to increased pest and disease infestations, which in turn may lead to yield loss if not well managed46,47. The selection of post-flowering maximum temperature as the variable explaining the most variability in robusta coffee yield in Chikmagalur suggests that the effects of localised microclimatic conditions on coffee yields were also identified through the model in our study. Indeed, the presence of a shade canopy can buffer extreme temperatures, reduce soil evaporation and crop transpiration, and improve production15,48,49.

To cope with the adverse impacts of climate variability on coffee productivity in CAFS a range of management strategies exist, including reliance on supplemental deficit irrigation, infrastructural investments in farms to enhance rainwater storage capability, tailored shade management to avoid competition for light during critical coffee phenological stages, diversification and careful selection of shade tree species (preferably context-specific species with rooting systems that would avoid competition for water and nutrients), crop and income diversifications, and adoption of crop insurance schemes16,21,50,51.

Our study shows that under a 2 °C warning scenario relative to baseline (1985–2015) climatic conditions, the projected coffee yield changes varied between + 5 and − 20% depending on the scale, with reductions found at the regional scale (i.e., projections made using the regional-scale model). With increasing interest in adopting CAFS as a strategy to reduce the vulnerability of both farmers and the global coffee sector to climate change13,16,52, as well as to enhance ecosystem services in coffee-growing regions53,54, it is important to identify the risks associated with climate variability in CAFS at different spatial scales for tailored and improved risk management. To date, studies have focused on the analysis of the co-benefits, synergies, and trade-offs of shade canopy and robusta coffee productivity in CAFS, with little attention given to scale-dependent climate risk levels14,49. Our study highlights the need to consider differentiated responses based on the main climate driver and its scale-dependent level of risk.

At finer spatial scales, mitigation and adaptation strategies should focus on helping farmers improve their shade management (pruning method and intensity, choice of context-specific and multipurpose tree species based on farmer knowledge), adopt practices that would increase water and nutrient use efficiencies, and use drought- and heat-stress-adapted varieties. Given that yield potentials and responses to environmental stresses in robusta coffee are genotype- and location-specific15,55, the adoption of new robusta coffee varieties needs to be preceded by appropriate pilot phases and good communications of their outcomes within farmers for better uptake.

At coarser spatial scales, land management and use that minimize the effects of regional warnings should be prioritized. This would require long-term institutional arrangements among multiple stakeholders, and multisectoral planning and implementation of appropriate adaptation actions to avoid risks of maladaptation56,57. Although farm relocation to suitable cropping areas may be seen as a potential climate adaptation strategy58,59,60, it is critical to investigate the feasibility of such strategies according to local contexts (e.g., suitable sites located in protected areas, prevailing land policies). Moreover, relocating farms will require adequate financial, technical, and social resources, which in most cases are unaffordable for smallholder coffee farmers, unless they are subsidised.

There are some limitations in this study that indicate a need for further research. Climatic variables such as solar radiation, wind speed, vapor pressure deficit, and soil moisture conditions were not included, but their effects may also vary across scales. As these factors could drive robusta coffee productivity13,55,61, considering the potential interactions of these factors with robusta coffee productivity would provide further insights into the climate risk levels in CAFS and help improve risk management. Moreover, targeted data collection and quantitative analysis should be undertaken in future research to explore the potential impacts of climate variability and change on shade trees in CAFS and understand how interspecific interactions will respond to climate change62,63. This would help improve current adaptive management strategies for CAFS and ensure better preparedness for future climate conditions for profitable and sustainable robusta coffee farming systems.

In summary, the study highlights the need to consider differentiated responses based on the main climate driver and its scale-dependent level of risk in coffee-based agroforestry systems. Such findings could inform and support spatial planning and actions for improved climate risk management at multiple spatial scales in robusta coffee-based agroforestry systems in India and other coffee-producing countries around the world.