Irish farms under climate change – is there a regional variation on farm responses?

S. SHRESTHA; M. ABDALLA; T. HENNESSY; D. FORRISTAL; M. B. JONES

doi:10.1017/S0021859614000331

Irish farms under climate change – is there a regional variation on farm responses?

Published online by Cambridge University Press: 01 May 2014

M. ABDALLA ,

D. FORRISTAL and

S. SHRESTHA*: Affiliation:
Land Economy, Environment & Society Scottish Rural College, Edinburgh, UK
M. ABDALLA: Affiliation:
Botany Department, School of Natural Sciences, Trinity College, Dublin, Ireland Institute of Biological and Environmental Sciences, School of Biological Sciences, University of Aberdeen, Aberdeen, UK
T. HENNESSY: Affiliation:
RERC, Teagasc, Mellows Campus, Athenry, Co. Galway, Ireland
D. FORRISTAL: Affiliation:
Oak Park Crops Research Centre, Teagasc, Co. Carlow, Ireland
M. B. JONES: Affiliation:
Botany Department, School of Natural Sciences, Trinity College, Dublin, Ireland
*: *To whom all correspondence should be addressed. Email: [email protected]

Article contents

Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSIONS
References

Rights & Permissions

Summary

The current paper aims to determine regional impacts of climate change on Irish farms examining the variation in farm responses. A set of crop growth models were used to determine crop and grass yields under a baseline scenario and a future climate scenario. These crop and grass yields were used along with farm-level data taken from the Irish National Farm Survey in an optimizing farm-level (farm-level linear programming) model, which maximizes farm profits under limiting resources. A change in farm net margins under the climate change scenario compared to the baseline scenario was taken as a measure to determine the effect of climate change on farms. The growth models suggested a decrease in cereal crop yields (up to 9%) but substantial increase in yields of forage maize (up to 97%) and grass (up to 56%) in all regions. Farms in the border, midlands and south-east regions suffered, whereas farms in all other regions generally fared better under the climate change scenario used in the current study. The results suggest that there is a regional variability between farms in their responses to the climate change scenario. Although substituting concentrate feed with grass feeds is the main adaptation on all livestock farms, the extent of such substitution differs between farms in different regions. For example, large dairy farms in the south-east region adopted total substitution of concentrate feed while similar dairy farms in the south-west region opted to replace only 0·30 of concentrate feed. Farms in most of the regions benefitted from increasing stocking rate, except for sheep farms in the border and dairy farms in the south-east regions. The tillage farms in the mid-east region responded to the climate change scenario by shifting arable production to beef production on farms.

Type: Climate Change and Agriculture Research Papers
Information: The Journal of Agricultural Science , Volume 153 , Issue 3 , April 2015 , pp. 385 - 398

DOI: https://doi.org/10.1017/S0021859614000331 [Opens in a new window]
Copyright: Copyright © Cambridge University Press 2014

INTRODUCTION

In the last few decades, extensive research has been conducted to examine the impacts of future climate change on agricultural production, more so recently, with the growing concern over food security (Rötter & Van De Geijn Reference Rötter and Van De Geijn1999; Chang Reference Chang2002; Craigon et al. Reference Craigon, Fangmeier, Jones, Donnelly, Bindi, De Temmerman, Persson and Ojanpera2002; Jones & Thornton Reference Jones and Thornton2003; Nelson et al. Reference Nelson, Rosegrant, Koo, Robertson, Sulser, Zhu, Ringler, Msangi, Palazzo, Batka, Magalhaes, Valmonte-Santos, Ewing and Lee2009, Reference Nelson, Rosegrant, Palazzo, Gray, Ingersoll, Roberton, Tokgoz, Zhu, Sulser, Ringler, Msange and You2010; Ciscar et al. Reference Ciscar, Feyen, Soria, Lavalle, Perry, Raes, Nemry, Demirel, Rozsai, Dosio, Donatelli, Srivastava, Fumagalli, Zucchini, Shrestha, Ciaian, Himics, Van Doorslaer, Barrios, Ibáñez, Rojas, Bianchi, Dowling, Camia, Libertá, San Miguel, De Rigo, Caudullo, Barredo, Paci, Pycroft, Saveyn, Van Regemorter, Revesz, Mubareka, Baranzelli, Rocha Gomes, Lung and Ibarreta2013; Shrestha et al. Reference Shrestha, Ciaian, Himics and Van Doorslaer2013; Witzke et al. Reference Witzke, Ciaian and Delince2014). Many of these studies have concluded that the effects of climate change on crop yields is highly dependent upon the geographical location of crop production, with crops in some regions benefiting (Cuculeanu et al. Reference Cuculeanu, Marica and Simota1999; Ghaffari et al. Reference Ghaffari, Cook and Lee2002; Witzke et al. Reference Witzke, Ciaian and Delince2014) while crops in other regions show adverse effects under new climatic conditions (Morison & Lawlor Reference Morison and Lawlor1999; Jones & Thornton Reference Jones and Thornton2003; Parry et al. Reference Parry, Rozenzweig, Iglesias, Livermore and Fisher2004; Witzke et al. Reference Witzke, Ciaian and Delince2014). In general, higher CO₂ concentration and an increase in spring/summer air temperatures as well as the length of growing season will be beneficial to crop production, especially in northern temperate latitudes (Cannell & Thornley Reference Cannell and Thornley1998; Campbell & Smith Reference Campbell and Stafford Smith2000; Donatelli et al. Reference Donatelli, Srivastava, Duveiller, Niemeyer, Seppelt, Voinov, Lange and Bankamp2012). However, an increase in temperature during crop development will depress yields in those regions where summer temperature and water stress are already limiting factors for plant growth (Rosenzweig & Tubiello Reference Rosenzweig and Tubiello1997). Similarly, higher rainfall can enhance grass growth in regions where water is a limiting factor, but it will be detrimental on grazing and grass conservation in areas with poor water drainage due to water logging (Cooper & McGechan Reference Cooper and McGechan1996). This regional variation of the impact of climate change on agricultural production eventually leads to differences in farms’ responses to such change in different regions (Mendelsohn et al. Reference Mendelsohn, Nordhaus and Shaw1996; Bryant et al. Reference Bryant, Smit, Brklacich, Johnston, Smithers, Chiotti and Singh2000; Tan & Shibasaki Reference Tan and Shibasaki2003; Seo & Mendelsohn Reference Seo and Mendelsohn2008; Walker & Schulze Reference Walker and Schulze2008; Nelson et al. Reference Nelson, Rosegrant, Koo, Robertson, Sulser, Zhu, Ringler, Msangi, Palazzo, Batka, Magalhaes, Valmonte-Santos, Ewing and Lee2009, Reference Nelson, Rosegrant, Palazzo, Gray, Ingersoll, Roberton, Tokgoz, Zhu, Sulser, Ringler, Msange and You2010; Ciscar et al. Reference Ciscar, Feyen, Soria, Lavalle, Perry, Raes, Nemry, Demirel, Rozsai, Dosio, Donatelli, Srivastava, Fumagalli, Zucchini, Shrestha, Ciaian, Himics, Van Doorslaer, Barrios, Ibáñez, Rojas, Bianchi, Dowling, Camia, Libertá, San Miguel, De Rigo, Caudullo, Barredo, Paci, Pycroft, Saveyn, Van Regemorter, Revesz, Mubareka, Baranzelli, Rocha Gomes, Lung and Ibarreta2013; Shrestha et al. Reference Shrestha, Ciaian, Himics and Van Doorslaer2013; Witzke et al. Reference Witzke, Ciaian and Delince2014).

Research has also been carried out in recent years to determine the effects of climate change on Irish farms (Brereton & O'Riordan Reference Brereton, O'Riordan and Holden2001; Holden et al. Reference Holden, Sweeney, Brereton, Fealy, Keane and Collins2004, Reference Holden, Brereton, Fitzgerald, Sweeney, Albanito, Brereton, Caffarra, Charlton, Donnelly, Fealy, Fitzgerald, Holden, Jones and Murphy2008). Many of these studies included regional variation in farm responses to climate change. For instance, Holden et al. (Reference Holden, Brereton, Fitzgerald, Sweeney, Albanito, Brereton, Caffarra, Charlton, Donnelly, Fealy, Fitzgerald, Holden, Jones and Murphy2008) included a number of adaptation measures such as changing stocking rate, N-inputs, silage area and grazing period to examine the impact of climate change on Irish livestock farms in different regions. They concluded that livestock farms in some areas, such as in the southern regions, would not benefit by adopting these changes whereas livestock farms in the eastern regions would improve production by increasing stocking rate or moderately decreasing N-input on farms. These previous Irish studies included farm adaptations as fixed measures implemented on all farms without considering the variability between different farm types. It is argued that use of generalized measures may not be ideal at a farm level without taking account of farm variability (due to socio-economic conditions and farm management), which would have a strong relationship with farm performances and hence influence their responses to future changes (Reidsma et al. Reference Reidsma, Ewert, Lansink and Leemans2010). This variability can be examined properly by providing modelled farms with more flexibility on selecting management strategies according to their individual needs to adjust under new conditions (Ramsden et al. Reference Ramsden, Wilson and Gibbons2000; Gibbons et al. Reference Gibbons, Sparkes, Wilson and Ramsden2005).

With 4·4 million ha of farming land, Irish agriculture covers only a small area of land compared to other EU countries (CSO 2012). However, there is a wide diversity among farms across the country. There are seven nomenclature of territorial units for statistics (NUTS) III agricultural regions in Ireland; border, mid-east, midlands, mid-west, south-east, south-west and west regions. The NUTS is a single uniform breakdown of territorial units for the production of regional statistics for the European Union (for details see http://ec.europa.eu/eurostat/ramon/nuts/introduction_regions_en.html). Both of the southern regions are dominated by dairy-production-oriented farms, whereas the north and west regions have smaller extensive farms. Tillage farms are scattered over southern and eastern regions of the country. Table 1 shows the characteristics of average farms in different regions to illustrate the variability between these regions.

Table 1. Characteristics of representative farms in different regions in Ireland

* Excluding single farm payments.

Source: Connolly et al. (Reference Connolly, Kinsella, Quinlan and Moran2008).

In addition to the regional variations, there is also substantial variation between different farm types within each region based on their main production system, management, economics and physical size. A number of studies have examined this variability and showed that in Ireland, different farms responded differently to changed conditions (Shrestha & Hennessy Reference Shrestha and Hennessy2006; Shrestha et al. Reference Shrestha, Hennessy and Hynes2007). For example, in response to the decoupling of farm payments, within the south-west region larger beef farms responded by reducing beef numbers by 50% whereas smaller beef farms entirely de-stocked beef animals (Shrestha et al. Reference Shrestha, Hennessy and Hynes2007).

The current paper examines the regional variation of impacts of climate change on Irish farms. It sets up different farm types in each of the regions in Ireland and aims to capture the variability between farms as mentioned above and explores the differences in farm response between those farm types under the changed climate.

MATERIALS AND METHODS

The methodology behind the current study was divided into two phases as shown in Fig. 1. The first phase determined the effects of future climate on yields of crops and grass in Irish regions using biophysical models. The second phase then used these model outputs in a farm-level economic model to examine farm responses under the changed climate. Family farm income, which represents net margin of a farm, was used as an indicator to determine the effects of climate change. A more detailed description of the data inputs and models is given below.

Fig. 1. A schematic diagram of the methodology.

Data input

The data used in the current paper was provided by two sources; farm-level data from the National Farm Survey (NFS) (Connolly et al. Reference Connolly, Kinsella, Quinlan and Moran2008) and climate data from the Irish National Meteorological Service (McGrath et al. Reference McGrath, Lynch, Dunne, Hanafin, Nishimura, Nolan, Venkata Ratnam, Semmler, Sweeney and Wang2008). In addition, farm management data and other farm variables that were not available in the NFS dataset were taken from the Teagasc Management Handbook (Teagasc 2009). The NFS data consisted of farm-level data from 1151 farms, representing 111 913 farms nationally and the NFS survey collects physical as well as financial information from each of the sampled farms. Farms were well distributed over the seven regions of the country and were classified as dairy, beef, sheep and tillage farms, based on the major activity taking place on the farm. Within each of the regions, a cluster analysis was carried out in SPSS (version 16.0.1) to group farms with similar characteristics together. Seven farm variables (production system, farm gross margins, land, animal number, labour, feed and milk yield) were used to group the farms: these variables were assumed to be the main differences between farms. The squared Euclidean distance method was used in finding similarities between the farms: it is commonly used in cluster analysis when there are multi-dimensional variables such as the farm variables used in the current study (Solano et al. Reference Solano, Leon, Perez and Herrero2001). A more detailed description of this methodology is available in Shrestha (Reference Shrestha2004).

The weather data used were a set of modelled data that were down-scaled from 136 weather stations throughout Ireland and had a horizontal resolution of 25 km (McGrath et al. Reference McGrath, Lynch, Dunne, Hanafin, Nishimura, Nolan, Venkata Ratnam, Semmler, Sweeney and Wang2008). The data included daily solar radiation, maximum and minimum air temperature, precipitation, dew point and wind speed at a height of 10 m. The weather data were obtained for a baseline scenario (1961–1990) and a climate change scenario (2061–2090). The climate scenario was based on the ‘high’ emission scenario A1B (IPCC Reference Nakicenovic and Swart2000) under a general climate model, HadCM3, which was down-scaled to regional level by using a regional climate model, RCA3 (McGrath et al. Reference McGrath, Lynch, Dunne, Hanafin, Nishimura, Nolan, Venkata Ratnam, Semmler, Sweeney and Wang2008). A number of emission scenarios based on different extents of GHG emissions were available under these models but only the ‘high’ scenario was chosen for the current study, to determine the largest response of farms under the changed climate.

Simulation models

Three different types of simulation models were used; crop and grass growth models in phase 1 and a linear programming farm-level model in phase 2.

Crop environment resource synthesis model

The crop environment resource synthesis (CERES) model was used to assess the impacts of climate change on winter wheat, spring barley and forage maize yields. The model was originally developed under the auspices of the USDA-ARS Wheat Yield Project and the US government multi-agency AGRISTARS programme, which was later modified into different modules (CERES-Wheat, CERES-Barley and CERES-Maize) to simulate yields for different crops (Ritchie & Otter Reference Ritchie, Otter and Willis1985; Otter-Nacke et al. Reference Otter-Nacke, Ritchie, Godwin and Singh1991; Ritchie et al. Reference Ritchie, Singh, Godwin, Bowen, Tsuji, Hoogenboom and Thornton1998). The CERES model has been parameterized worldwide for major crops and has shown reasonable agreement between measured and modelled results in a number of locations (Holden & Brereton Reference Holden and Brereton2006; Lizaso et al. Reference Lizaso, Fonseca and Westgate2007; Robredo et al. Reference Robredo, Perez-Lopez, De La Maza, Gonzalez-Moro, Lacuesta, Mena-Petite and Munoz-Rueda2007; Meza et al. Reference Meza, Silva and Vigil2008).

Johnstown grass model

The Johnstown castle grass model (JGM; Brereton et al. Reference Brereton, Danielov and Scott1996) was used in the current study for simulating Irish grass growth. It is a simple empirical pasture model that predicts vegetative growth and development in permanent pastures (Brereton Reference Brereton, Jeffrey, Jones and McAdam1995) and was developed for the purpose of understanding the behaviour of grassland systems herbage supply in response to weather variations. This model simulates the production of pasture dominated by perennial ryegrass, which is the common basis of livestock production in Ireland. It has been tested and validated against measured production over a wide geographical range and found suitable for simulating Irish pasture production (Brereton Reference Brereton, Jeffrey, Jones and McAdam1995; Holden et al. Reference Holden, Brereton, Fitzgerald, Sweeney, Albanito, Brereton, Caffarra, Charlton, Donnelly, Fealy, Fitzgerald, Holden, Jones and Murphy2008).

Farm-level linear programming model

An optimizing farm-level linear programming (FLLP) model was developed for the current study. The FLLP is based on a farm-level dynamic linear programming model which is described in detail in Shrestha (Reference Shrestha2004). Modified versions of FLLP have been used in a number of farm-level analyses of Irish Agriculture (Shrestha & Hennessy Reference Shrestha and Hennessy2006, Reference Shrestha and Hennessy2008; Shrestha et al. Reference Shrestha, Hennessy and Hynes2007; Hennessy et al. Reference Hennessy, Shrestha and Farrell2008). The FLLP model assumes that all farmers are profit oriented and maximize farm net income within a set of limiting farm resources. For the purpose of the current study, four production systems were considered; dairy, beef, sheep and arable production systems. These systems were constrained by land labour, feed and stock replacement available to a farm. The total land available on a farm was fixed but farms were allowed to transfer land between different production systems. Farms were also allowed to buy in feeds, animal replacements and hire labour if required. The farm net income comprised the accumulated revenues collected from the final product of the farm activities (crops, animals and milk) plus farm payments minus costs incurred for inputs under those activities. The input costs were replacement costs for livestock, variable costs including labour, feed and veterinary costs and overhead costs on farms.

In the crop production system, the model consisted of the three most common crops in Ireland; winter wheat, spring barley and forage maize. The initial land under these crops in each farm was based on the farm-level data; however, as mentioned earlier, the model was allowed to reallocate land under these crops as well as transfer to grass production. The stocking rate on each farm was also fixed to the farm-level data, assuming that all farms were operating under optimum stocking rate. The dairy system had a 4-year replacement structure where dairy animals were culled every 4 years. Similarly, beef and sheep systems followed a 2-year replacement structure. The animals were replaced by on-farm or off-farm replacement stocks. A feed module, based on Alderman & Cottrill (Reference Alderman and Cottrill1993), was used in the model to determine feed requirements for each of the animals based on type, age and production level of the animal. Feeds available to the livestock were fresh grass, grass silage, maize silage and concentrate feeds. Concentrate feed included cereal produced on farms as well as those feed bought from outside the farms. Grass silage was produced under one-cut (May) or two-cut (May and June) silage production systems. The quality of the one-cut and two-cut grass silage was assumed to be similar in the current study. The two-cut silage system produces more grass silage annually but has twice the labour costs of the one-cut silage system.

The FLLP model is pseudo-dynamic in nature, such that it runs for a 10-year time frame but the results from the first 3 years and the last 3 years were discarded to minimize the starting and terminal effects of linear programming (Ahmad Reference Ahmad1997; Shrestha Reference Shrestha2004). The model outputs from the middle 4 years were averaged to provide the final results for both the baseline scenario and the climate change scenario runs. Farm activities chosen by the model under the climate change scenario which were different from the baseline scenario were considered as farmers’ responses under the changed climate. A list of adaptation variables used in the current study is provided in Table 2. It should be noted here that the study focused only on short-term farm adaptations that could be adopted easily by a farmer on-farm. Long-term adaptations that require large investments, such as installation of irrigation/drainage facilities on farms, were not considered for the current study as they were not assumed to be farmers’ immediate response under a changed climate. The adaptation variables considered in the current study can be divided into two types; endogenous farm variables, which were the existing farm management practices and were adjusted by the model during optimization; and exogenous farm variables, which were introduced in the model externally. Two exogenous adaptations were examined in the current paper: stocking rate and introduction of Miscanthus. The stocking rate was increased by +0·5 livestock units (LU)/ha and +1 LU/ha in separate model runs to provide flexibility on farms to increase animal numbers. Miscanthus is provided in the model as an optional crop: it was included as a possible adaptation because of its importance as a biofuel crop and it is considered to be suitable for future growing conditions in Ireland (Breen et al. Reference Breen, Clancy, Moran and Thorne2009). The gross margin for Miscanthus was set at €30·7 per tonne (Clancy et al. Reference Clancy, Breen, Butler and Thorne2009).

Table 2. A list of adaptation measures used in FLLP model

The current study only considered the changes on crops and grass yields under a climate change scenario. Direct effects of climate change on grazing animals were not covered in detail because, in a temperate climate like Ireland, animals are expected to be capable of tolerating heat stress for the next 50 years (Parsons et al. Reference Parsons, Cooper, Armstrong, Mathews, Turnpenny and Clark2001). However, a 10% increase in livestock variable costs (especially increases in veterinary costs) was included in the study to enable livestock farms to undertake any preventive measures against the possibility of parasitic infestation. It should also be noted here that the current study focused entirely on the impacts of climate change and all other external factors such as market prices, technological progress and agricultural policies were kept unchanged.

RESULTS

Model validation

Crop environment resource synthesis model

The CERES crop model results for winter wheat and spring barley were validated using field data. As shown in Table 3, the model baseline average yields fall within the range of field data and RMSE value for winter wheat and spring barley are both 0·5 t/ha. The model, however, underestimated the biomass of forage maize with an RMSE value of 1·5 t/ha.

Table 3. A comparison of CERES baseline yields against field data for three crops

* Winter wheat and spring barley field data (1998–2006) taken from Forristal (Reference Forristal2007) and Forage maize field data (1992–1998) taken from Holden & Brereton (Reference Holden, Brereton and Sweeney2003a , Reference Holden and Brereton b ).

Farm-level linear programming model

The baseline farm net incomes provided by the FLLP model were compared with the farm family net income of all farm types in each of the region. Figure 2 presents a snapshot comparison of farm types in two regions; southwest (one of the most efficient production regions) and border (one of the least efficient production regions). The comparison for other regions is similar to these two regions. The FLLP is robust for large and efficient farms but it overestimated the farm income for some of the small and less efficient farms. This is understandable as FLLP is an optimizing model, hence tries to maximize utilization of farm resources on those small and less efficient farms. The model is not adjusted in the current study for these small farms since the focus was to examine counterfactual scenarios and compare them with a baseline scenario.

Fig. 2. Comparison of farm net incomes between FLLP baseline and NFS farm-level data for southwest and border regions.

Farm types

The cluster analysis resulted in different farm groups in each of the seven regions. The number of farm types in each of the regions is shown in Table 4. All of the regions contained both dairy and beef farm groups, whereas sheep farm groups are identified only in the border, mid-east, south-west and west regions and tillage farm groups are concentrated only in border, mid-east and south-east regions (it should be noted that all regions actually contain some sheep and tillage farms, but in order to preserve confidentiality those groups with fewer than 15 farms were not considered in the current study).

Table 4. Number of farm types in each of the regions

Based on their characteristics, the farm groups were arbitrarily designated as small-, medium- and large-sized farms to differentiate them from each other. Some major characteristics of the farm groups in each of the regions are provided in Table 5, showing the size of farm, available family labour, farm gross margins and livestock units. The results showed that the northern regions have smaller, extensive livestock farms whereas southern regions consisted of more intensive livestock farms. It also showed that most of the Irish tillage farms had beef or sheep activities on farms.

Table 5. Characteristics of farm groups in different regions

MWU: man work unit; LU: livestock unit

Crop yields

Both of the cereal crops used in the current study, winter wheat and spring barley, showed a decrease in yields on farms under climate change in all three tillage regions (Table 6). The extents of impact on yields were different in each of the regions. The most severe impact for both winter wheat and spring barley crops was observed on farms in the south-east region compared to farms in the mid-east and border regions. In contrast to the cereal crops, forage maize production in the three regions investigated was increased substantially under the climate change scenario compared to the baseline scenario, with yields ranging from 19·1 to 21·3 t/ha which represented increase of 43–97%.

Table 6. Effects of baseline and climate change scenario on crop yields (t/ha) and % change in yields on a regional basis

Grass yield

Under the climate change scenario, grass growth was substantially increased in all regions compared to the baseline scenario with yields ranging from 10·0 to 16·8 t/ha (Table 7). The south-west region had the highest grass yield in the baseline scenario but had the lowest increment (49%) of yield under the climate change scenario. In contrast, the border region had the lowest grass yield in the baseline scenario but the increase under the climate change was the highest at 56%.

Table 7. Effects of baseline and climate change scenario on the grass biomass production (t/ha)

Impacts on farms

The model results for farm net income under the climate change scenario are shown in Table 8. In the table, the first column represents the region and farm types within each region. The second column provides farm income data under the baseline scenario. The third column, which is the climate scenario column, is further divided into four columns; the first column, ‘Basic’, is the climate change scenario where only endogenous adaptations were considered in the model. The remaining columns in the table provide the results with exogenously introduced adaptation measures as indicated by corresponding column titles. The results are discussed in more detail for each region below.

Table 8. Percentage change in farm net incomes under climate change scenarios in different regions

LU: livestock unit

In the border region there was a negative impact on all farm types under the climate change scenario. The impact was small in the case of dairy farms and beef farms but the sheep and tillage farms showed relatively larger negative impacts (c. −10%). There was a very small replacement of concentrate feed by grass and grass silage on dairy farms, but for beef and sheep farms there was no change in feeding system as these farms already had a system based completely on grass. There was no change for animal number but most of the farms benefitted when stocking rate was increased. Sheep farms, however, did not improve for farm income since the productivity of these farms decreased when the number of animals on farms increased.

In the mid-east region, dairy farms showed mixed responses with larger farms losing out but medium-sized farms benefitting under the ‘Basic’ climate change scenario. Sheep and tillage farms had higher gains under the climate change scenario compared to the beef farms. The medium dairy farms replaced only 0·40 of the concentrate feed by grass feeds, whereas the beef farms replaced concentrate feed by up to 0·84. All other farms replaced concentrate completely with grass and grass silage feeds. The tillage farms removed all land under crop production and moved to grass production. These tillage farms increased beef numbers by 0·30. Increased stocking rate on farms substantially improved the family income in all farm types, especially in the sheep farms where there was over 100% increase in farm incomes.

In the midlands region, all farm types showed a decrease in their farm incomes. The only adjustment on these farms was to replace the entire use of concentrate feed by grass and grass silage feeds. Dairy farms in the mid-west region, however, showed only a negligible impact from climate change. However, all beef farms in this region benefitted substantially. These farms replaced all concentrate feed used on farms with grass and grass silage feeds.

Of all farm types in all regions, the large-sized dairy farms in the south-east region had the highest loss (−24%) in farm income under the ‘Basic’ climate change scenario. These farms are the milk producers with highest costs of production (€928/dairy LU). The 10% increase in variable costs under climate change affected these farms more than any other farms. These farms opted to reduce dairy animals on farm by 2%. These farms were affected more when the number of animals was increased under the higher stocking rate scenarios. The small dairy farm as well as all types of beef and tillage farms had comparatively a smaller reduction in farm income. However, these farms show an improvement on farm income under the higher stocking rate scenarios. The tillage farms benefitted by increasing 0·5 LU of animals on farms but further increase in stocking rate had a negative impact on incomes of these farms. The medium dairy farms showed a very small improvement in farm income when Miscanthus was allowed on farm. These farms had a small piece of arable land (c. 4 ha) used for cereal production to feed animals. Miscanthus as a cash crop was slightly more profitable alternative for these farms, as the farms could sell it to the market.

In the south-west region, the large dairy farms had an increase in farm income under the ‘Basic’ climate change scenario. These farms replaced c. 0·30 of concentrate feed with grass, grass silage and maize silage in animal feed and also put the animals on grass 1 month earlier in the ‘Basic’ climate change scenario compared to the baseline scenario. However, for smaller dairy farms in this region there were no impacts of climate change on farm incomes. The beef and sheep farms, however, had substantial increases in farm income under the climate change scenario. This was entirely due to replacing concentrate feed by grass feeds and hence lowering expenses. Increasing animals on farms benefitted all farms in this region.

In the west region, there was no impact of the ‘Basic’ climate change scenario on dairy farms but the cattle and sheep farms had a larger beneficial effect of climate change. These farms also exploited increase in grass yield by replacing the concentrate feed completely with grass feed. These farms also improved their incomes substantially when more animals were allowed on farms.

Farms in all regions also opted for one-cut grass silage production system to minimize production costs. As the quality of grass silage was assumed to be the same in all types of grass conservation method, the results suggested that the higher production costs for two-cut silage systems outweighs the benefits of an increase in grass silage compared to one-cut silage system.

DISCUSSION

Previous studies have shown that the growth models used in the current study (CERES and JGM) can predict crop production in Ireland reliably (Holden & Brereton Reference Holden and Brereton2002, Reference Holden, Brereton and Sweeney2003a , Reference Holden and Brereton b , Reference Holden and Brereton2006). The future crop yields projected under the climate change scenario were lower compared to the baseline scenario for both winter wheat and spring barley crops in all three regions. This result contrasts with the results of some earlier studies (Holden & Brereton Reference Holden, Brereton and Sweeney2003a , Reference Holden and Brereton b ; Holden et al. Reference Holden, Sweeney, Brereton, Fealy, Keane and Collins2004, Reference Holden, Brereton, Fitzgerald, Sweeney, Albanito, Brereton, Caffarra, Charlton, Donnelly, Fealy, Fitzgerald, Holden, Jones and Murphy2008), where positive yield for cereal crops was provided. The difference, however, lies in the climatic scenario used. Owing to the uncertainty of future climate change, a number of climatic scenarios are available ranging from low- to high-temperature change. For the current study, a ‘high’ A1B climate scenario was used to determine the farm responses under extreme conditions. Although a mild increase in temperature would benefit crops in temperate regions such as Ireland, as indicated in earlier studies, a higher temperature would cause crop stress and shortening of the grain filling period (Midmore et al. Reference Midmore, Cartwright and Fisher1982; Blum et al. Reference Blum, Sinmena, Mayer, Golan and Shpiler1994; Wolfe Reference Wolfe and Pessarakli1994; Luo & Mooney Reference Luo and Mooney1999; Anwar et al. Reference Anwar, O'Leary, McNeil, Hossain and Nelson2007), therefore reducing grain yields. This difference in the use of climate change scenario has also been illustrated by Donatelli et al. (Reference Donatelli, Srivastava, Duveiller, Niemeyer, Seppelt, Voinov, Lange and Bankamp2012), who showed that for the northern European regions, cereal production would increase by up to 20% under a ‘mild’ climate scenario but decrease by −20% under a ‘warm’ climate scenario. The ‘warm’ scenario used in the Donatelli study is similar to the ‘high’ climate scenario used in the current study.

The effect of climate change on forage maize and grass yields is generally positive in all regions in Ireland. Warmer conditions are more favourable for maize production and recent projections show a projected substantial increase (up to 200%) in maize yield in all Irish regions with climate warming (Holden & Brereton Reference Holden, Brereton and Sweeney2003a , Reference Holden and Brereton b ). It has also been suggested that the predicted future dry summers (McGrath et al. Reference McGrath, Lynch, Dunne, Hanafin, Nishimura, Nolan, Venkata Ratnam, Semmler, Sweeney and Wang2008) may affect biomass production of forage maize negatively, as higher precipitation is important for higher crop yield (Mera et al. Reference Mera, Niyogi, Buol, Wilkerson and Semazzi2006; Kovacevic et al. Reference Kovacevic, Jolankai, Birkas, Loncaric, Sostaric, Loncaric and Maric2009a , Reference Kovacevic, Sostaric, Josipovic, Iljkic and Markovic b ). However, the model results suggest that future warmer temperatures will increase forage maize biomass production sufficiently to compensate yield reduction due to expected reduced precipitation. Increases in grass yields were due to the combined effects of increasing winter rainfall, temperature and CO₂ concentration (McGrath et al. Reference McGrath, Lynch, Dunne, Hanafin, Nishimura, Nolan, Venkata Ratnam, Semmler, Sweeney and Wang2008). There have been several studies suggesting that increases in precipitation (Rosenzweig & Tubiello Reference Rosenzweig and Tubiello1997; Izaurralde et al. Reference Izaurralde, Rosenberg, Brown and Thomson2003; Mearns Reference Mearns2003), temperature (Fiscus et al. Reference Fiscus, Reid, Miller and Heagle1997) and carbon dioxide concentrations (Mitchell et al. Reference Mitchell, Mitchell, Driscoll, Franklin and Lawlor1993; Anwar et al. Reference Anwar, O'Leary, McNeil, Hossain and Nelson2007) have a positive effect on grass productivity. Increase in future grass biomass production in Ireland due to climate change has been suggested by Holden & Brereton (Reference Holden and Brereton2002) and Fitzgerald et al. (Reference Fitzgerald, Brereton and Holden2009) using the Dairy_Sim model, and Abdalla et al. (Reference Abdalla, Jones, Yeluripati, Smith, Burke and Williams2010) using the DeNitrification – DeComposition (DNDC) and DayCent models.

The FLLP model results suggested that there is a regional variation in the impacts of the climate change scenario on farms and the response of farms are different between farms in all regions. Livestock farms in the border region had reductions in farm net margins under the climate change scenario. The increase in grass yield under the climate change scenario did not make any difference to their farm management as these farms were already using grass-based systems. These farms, however, had an increase of 10% in livestock variable costs under the climate change scenario, which reduced their net margins. The farms in the west region, which are assumed to be very similar to farms in the border region, have higher costs of production and used more concentrate feed compared to their counterparts from the border region (Connolly et al. Reference Connolly, Kinsella, Quinlan and Moran2008). Moving to a complete grass-based system decreased the costs of production on these farms, hence improving the farm margins. Similarly, in the dairy producing southern regions, dairy farms in the south-west region improved their farm net margin under climate change by replacing 0·30 of concentrate feed with grass-based feed. However, dairy farms in the south-east region replaced the entire concentrate feed used on farm with grass feeds to minimize production costs. The livestock farms in all regions also opted for one-cut silage production on farms. It has been suggested that cost-saving strategies such as lowering labour costs would be preferred by farmers in the future (Ramsden et al. Reference Ramsden, Gibbons and Wilson1999). Rötter & Van De Geijn (Reference Rötter and Van De Geijn1999) also pointed out that the impact of climate change would be more favourable to a grass-based livestock production system as they could lower the costs of production further.

For a majority of farm groups, a restriction on stocking rate seemed to be a major constraint as their farm incomes improved when stocking rate was increased. This shows that these farms could exploit an increase in grass yield under climate change by simply increasing the number of animals. Parsons et al. (Reference Parsons, Cooper, Armstrong, Mathews, Turnpenny and Clark2001) also suggested that farmers benefit from increased grass yield under climate change when stocking rate was relaxed. However, increasing stocking rate has its own consequences and may not be applicable because of policy restrictions, the possibility of damaging soil and an increase in variable costs. Some farms are not profitable enough to increase animal numbers, such as sheep farms in the border and medium dairy farms/tillage farms in the south-east regions. The productivity of animals could also be affected adversely by increasing stocking rate, as reported by Gordon (Reference Gordon and O'Grady1986) who found a decrease of 4% in milk yield per cow when stocking rate was increased from 2·5 to 3 cows/ha in northern Ireland. Ruminants are also considered to produce 17% of the total global methane emission (Benchaar et al. Reference Benchaar, Rivest, Pomar and Chiquette1998) so any activity leading to further increases in the methane emissions should be considered carefully, especially if there is a limit imposed on farms on total GHG emissions.

For tillage farms, lower crop yields under the climate change scenario had a negative impact on farms. However, tillage farms in the mid-east region showed an improvement in their incomes under climate change by moving from tillage to beef farming. Beef production in this region is more commercialized with higher beef price and has a tendency to increase the number of animals when possible (Shrestha et al. Reference Shrestha, Hennessy and Hynes2007). The tillage farms in this region already have a capacity in beef production and hence can expand beef production without incurring a large investment. In the current study, Miscanthus, as an alternative crop, could not compete with other arable crops and hence most of the farms did not choose it as an adaptation. The only farms that chose Miscanthus were the medium-sized dairy farms in the south-east region, which had a small piece of land under cereal production to feed their animals. These farms moved completely to the grass-based feed system and opted for Miscanthus on arable land to sell it in the market. The prices of Miscanthus in the current study were fixed to the 2004 level but under future price projections, Miscanthus could be more competitive and considered as an adaptation measure to improve farm margins (Styles et al. Reference Styles, Thorne and Jones2008).

There are some limitations in the current study. The responses examined were based on the assumption that all farmers were profit oriented: farmers are known to take up new technologies and change their management practices to improve their profits (Kaiser & Crosson Reference Kaiser and Crosson1995). However, the current study did not cover those farmers whose responses were not always aimed at maximizing farm profits, such as hobby farmers. The study also only focused on farm adaptations and did not include long-term adaptations which would incur large investments. Another limitation of the current study is that the results are highly dependent on the outcomes of the crop growth models and climate change scenarios. Different sets of crop growth model or climate change scenarios could provide entirely different sets of crop yield results. Since only one climate change scenario was included, the sensitivity of the growth models to temperature and rainfall suggests that further research would be beneficial under a range of climate change scenarios to identify the full scale of possible strategies under different climatic conditions. It should also be noted that prices for the future were fixed at the current level and the study did not consider any price or market effects on farm responses to the future climate.

CONCLUSIONS

Most of the farms in the border, midlands and south regions suffered while farms in rest of the regions benefitted under the climate change scenario used in the current study. A majority of livestock farms replaced all concentrate feed with grass feeds, but a number of farms opted for only a fraction of such replacement. Dairy farms in south-east regions responded to climate change by decreasing dairy animals on farms whereas dairy farms in other regions benefitted when stocking rate was increased on farms. Tillage farms in the mid-east region were able to compensate for a loss in crop yield under climate change by shifting from crop production to beef production. The current paper shows that there exists a regional variability in farm responses to the impacts of climate change on Irish farms.

The authors would like to acknowledge the Department of Agriculture and Food, Ireland for providing funding for this study under the Research Stimulus Fund Programme, project no. 06/316, C4I, Ireland for providing weather data and FBS, Teagasc for providing farm-level data and two anonymous referees for providing valuable comments to prepare this paper.

References

REFERENCES

Abdalla, M., Jones, M., Yeluripati, J., Smith, P., Burke, J. & Williams, M. (2010). Testing DayCent and DNDC model simulations of N₂O fluxes and assessing the impacts of climate change on the gas flux and biomass production from a humid pasture. Atmospheric Environment 44, 2961–2970.CrossRef Google Scholar

Ahmad, Z. (1997). Modelling the impact of agricultural policy at the farm level in the Punjab, Pakistan. Ph.D. Thesis, University of Nottingham.Google Scholar

Alderman, G. & Cottrill, B. R. (1993). Energy and Protein Requirements of Ruminants. An Advisory Manual Prepared by the AFRC Technical Committee on Responses to Nutrients. Wallingford, UK: CAB International.Google Scholar

Anwar, M. R., O'Leary, G., McNeil, D., Hossain, H. & Nelson, R. (2007). Climate change impact on rain fed wheat in south-eastern Australia. Field Crops Research 104, 139–147.CrossRef Google Scholar

Benchaar, C., Rivest, J., Pomar, C. & Chiquette, J. (1998). Prediction of methane production from dairy cows using existing mechanistic models and regression equations. Journal of Animal Science 76, 617–627.CrossRef Google Scholar PubMed

Blum, A., Sinmena, B., Mayer, J., Golan, G. & Shpiler, L. (1994). Stem reserve mobilisation supports wheat-grain filling under heat stress. Australian Journal of Plant Physiology 21, 771–781.Google Scholar

Breen, J., Clancy, D., Moran, B. & Thorne, F. (2009). Modelling the Potential Supply of Energy Crops in Ireland: Results from a Probit Model Examining the Factors Affecting Willingness to Adopt. RERC Working Paper Series 09-WP-RE-05. Athenry, Ireland: Teagasc. Available from: http://www.agresearch.teagasc.ie/rerc/workingpapers.asp (accessed 21 January 2014).Google Scholar

Brereton, A. J. (1995). Regional and year to year variation in production. In Irish Grasslands: their Biology and Management (Eds Jeffrey, D. W., Jones, M. B. & McAdam, J. H.), pp. 12–22. Dublin, Ireland: Royal Irish Academy.Google Scholar

Brereton, A. J. & O'Riordan, E. G. (2001). A comparison of grass growth models. In Agro-meteorological Modelling – Principles, Data and Applications (Ed. Holden, N. M.), pp. 136–154. Dublin: Agmet.Google Scholar

Brereton, A. J., Danielov, S. A. & Scott, D. (1996). Agrometeorology of Grass and Grasslands for Middle Latitudes. Technical Note No. 197. Geneva: W.M.O.Google Scholar

Bryant, C. R., Smit, B., Brklacich, M., Johnston, T. R., Smithers, J., Chiotti, Q. & Singh, B. (2000). Adaptation in Canadian agriculture to climatic variability and change. Climatic Change 45, 181–201.CrossRef Google Scholar

Campbell, B. D. & Stafford Smith, D. M. (2000). A synthesis of recent global change research on pasture and rangeland production: reduced uncertainities and their management implications. Agriculture, Ecosystems and Environment 82, 39–55.CrossRef Google Scholar

Cannell, M. G. R. & Thornley, J. H. M. (1998). N-poor ecosystems may respond more to elevated [CO2] than N-rich ones in the long term: a model analysis of grassland. Global Change Biology 4, 431–442.CrossRef Google Scholar

Chang, C. (2002). The potential impact of climate change on Taiwan's agriculture. Agricultural Economics 27, 51–64.CrossRef Google Scholar

Ciscar, J. C., Feyen, L., Soria, A., Lavalle, C., Perry, M., Raes, F., Nemry, F., Demirel, H., Rozsai, M., Dosio, A., Donatelli, M., Srivastava, A., Fumagalli, D., Zucchini, A., Shrestha, S., Ciaian, P., Himics, M., Van Doorslaer, B., Barrios, S., Ibáñez, N., Rojas, R., Bianchi, A., Dowling, P., Camia, A., Libertá, G., San Miguel, J., De Rigo, D., Caudullo, G., Barredo, J. L., Paci, D., Pycroft, J., Saveyn, B., Van Regemorter, D., Revesz, T., Mubareka, S., Baranzelli, C., Rocha Gomes, C., Lung, T. & Ibarreta, D. (2013). Climate impacts in Europe: an integrated economic assessment (preliminary results of the JRC PESETA II project). In Impacts World 2013 Conference Proceedings. International Conference on Climate Change Effects, Potsdam, 27–30 May 2013, pp. 87–96. Potsdam, Germany: Potsdam Institute for Climate Impact Research.Google Scholar

Clancy, D., Breen, J., Butler, A. M. & Thorne, F. (2009). A discounted cash flow analysis of financial returns from biomass crops in Ireland. Journal of Farm Management 13, 595–611.Google Scholar

Connolly, L., Kinsella, A., Quinlan, G. & Moran, B. (2008). National Farm Survey 2008. Athenry, Ireland: Teagasc, Rural Economy Research Centre.Google Scholar

Cooper, G. & McGechan, M. B. (1996). Implications of an altered climate for forage conservation. Agricultural and Forest Meteorology 79, 253–269.CrossRef Google Scholar

Craigon, J., Fangmeier, A., Jones, M., Donnelly, A., Bindi, M., De Temmerman, L., Persson, K. & Ojanpera, K. (2002). Growth and marketable-yield responses of potato to increased CO₂ and ozone. European Journal of Agronomy 17, 273–289.CrossRef Google Scholar

CSO (2012). Census of Agriculture. Cork, Ireland: Irish Central Statistical Office. Available from: http://www.statcentral.ie/viewStat.asp?id=142 (accessed March 2014).Google Scholar

Cuculeanu, V., Marica, A. & Simota, C. (1999). Climate change impact on agricultural crops and adaptation options in Romania. Climate Research 12, 153–160.CrossRef Google Scholar

Donatelli, M., Srivastava, A. K., Duveiller, G. & Niemeyer, S. (2012). Estimating impact assessment and adaptation strategies under climate change scenarios for crops at EU27 scale. In International Environmental Modelling and Software Society (iEMSs) 2012 International Congress on Environmental Modelling and Software. Managing Resources of a Limited Planet: Pathways and Visions under Uncertainty, Sixth Biennial Meeting, Leipzig, Germany (Eds Seppelt, R., Voinov, A. A., Lange, S. & Bankamp, D.), pp. 404–411. Leipzig, Germany: iEMSs. Available from: http://www.iemss.org/society/index.php/iemss-2012-proceedings (accessed 21 January 2014).Google Scholar

Fiscus, E. L., Reid, C. D., Miller, J. E. & Heagle, A. S. (1997). Elevated CO₂ reduces O₃ flux and O₃-indued losses in soybean: possible implications for elevated CO₂ studies. Journal of Experimental Botany 48, 307–313.CrossRef Google Scholar

Fitzgerald, J. B., Brereton, A. J. & Holden, N. M. (2009). Assessment of the adaptation potential of grass-based dairy systems to climate change in Ireland – the maximised production scenario. Agricultural and Forest Meteorology 149, 244–255.CrossRef Google Scholar

Forristal, P. D. (2007). Can we reduce costs and increase profits in tillage. In Proceedings of the National Tillage Conference, 2007, pp. 25–42. Oak Park, Carlow, Ireland: Crops Research Centre. Available from: http://www.teagasc.ie/publications/2007/20070131/ (accessed 21 January 2014).Google Scholar

Ghaffari, A., Cook, H. F. & Lee, H. C. (2002). Climate change and winter wheat management: a modelling scenario for south eastern England. Climatic Change 55, 509–533.CrossRef Google Scholar

Gibbons, J. M., Sparkes, D. L., Wilson, P. & Ramsden, S. J. (2005). Modelling optimal strategies for decreasing nitrate loss with variation in weather – a farm-level approach. Agricultural Systems 83, 113–134.CrossRef Google Scholar

Gordon, F. J. (1986). Maximising milk production from grassland. In Agriculture: Consequences of Milk Quotas and Alternative Animal Enterprises (Ed. O'Grady, J. F.), pp. 149–159. Brussels, Luxembourg: Commission of the European Communities.Google Scholar

Hennessy, T., Shrestha, S. & Farrell, M. (2008). Quantifying the viability of farming in Ireland: can decoupling address the regional imbalances? Irish Geography 41, 29–47.CrossRef Google Scholar

Holden, N. M. & Brereton, A. J. (2002). An assessment of the potential impact of climate change on grass yield in Ireland over the next 100 years. Irish Journal of Agricultural and Food Research 41, 213–226.Google Scholar

Holden, N. M. & Brereton, A. J. (2003 a). The impact of climate change on Irish agriculture. In Climate Change Scenarios and Impacts for Ireland (Ed. Sweeney, J.), pp. 33–79. ERTDI Report Series No. 15. Johnstown Castle, Wexford, Ireland: Environmental Protection Agency.Google Scholar

Holden, N. M. & Brereton, A. J. (2003 b). Potential impacts of climate change on maize production and the introduction of soybean in Ireland. Irish Journal of Agricultural and Food Research 42, 1–15.Google Scholar

Holden, N. M. & Brereton, A. J. (2006). Adaptation of water and nitrogen management of spring barley and potato as response to possible climate change in Ireland. Agricultural Water Management 82, 297–317.CrossRef Google Scholar

Holden, N. M., Sweeney, J., Brereton, A. J. & Fealy, R. (2004). Climate change and Irish agriculture. In Climate, Weather and Irish Agriculture (Eds Keane, T. & Collins, J. F.), pp. 359–382. Dublin: Agmet.Google Scholar

Holden, N. M., Brereton, A. J. & Fitzgerald, J. B. (2008). Impact of climate change on Irish agricultural production systems. In Climate Change – Refining the Impacts for Ireland. STRIVE Environmental Protection Agency Programme 2007–2013 (Eds Sweeney, J., Albanito, F., Brereton, A., Caffarra, A., Charlton, R., Donnelly, A., Fealy, R., Fitzgerald, J., Holden, N., Jones, M. & Murphy, C.), pp. 82–131. STRIVE Report Series No. 12. Wexford, Ireland: Environmental Protection Agency.Google Scholar

IPCC (2000). Emissions Scenarios: a Special Report of IPCC Working Group III (Eds Nakicenovic, N. & Swart, R.), p. 570. Cambridge, UK: Cambridge University Press.Google Scholar

Izaurralde, R. C. C., Rosenberg, N. J., Brown, R. A. Jr & Thomson, A. M. (2003). Integrated assessment of Hadley Centre (HadCM2) climate-change impacts on agricultural productivity and irrigation water supply in the conterminous United States. Part II. Regional agricultural production in 2030 and 2095. Agricultural and Forest Meteorology 117, 97–122.CrossRef Google Scholar

Jones, P. G. & Thornton, P. K. (2003). The potential impacts of climate change on maize production in Africa and Latin America in 2055. Global Environmental Change 13, 51–59.CrossRef Google Scholar

Kaiser, H. M. & Crosson, P. (1995). Implications of climate change for US agriculture. American Journal of Agricultural Economics 77, 734–740.CrossRef Google Scholar

Kovacevic, V., Jolankai, M., Birkas, M., Loncaric, Z. & Sostaric, J. (2009 a). Influence of precipitation and temperature trend on maize yields. In Proceedings of the XLIV Croatian Symposium on Agriculture with International Participation (Eds Loncaric, Z. & Maric, S.), pp. 541–545. 16–20 February 2009, Opatija, Croatia: Sveucilista Josipa Jurja Strossmayera u Osijeku Faculty of Agriculture.Google Scholar

Kovacevic, V., Sostaric, J., Josipovic, M., Iljkic, D. & Markovic, M. (2009 b). Precipitation and temperature regime impacts on maize yields in eastern Croatia. Research Journal of Agricultural Science 41, 49–53.Google Scholar

Lizaso, J. I., Fonseca, A. E. & Westgate, M. E. (2007). Simulating source-limited and sink-limited kernel set with CERES-maize. Crop Science 47, 2078–2088.CrossRef Google Scholar

Luo, Y. & Mooney, H. A. (1999). Carbon Dioxide and Environmental Stress. New York: Academic Press.Google Scholar

McGrath, R., Lynch, P., Dunne, S., Hanafin, J., Nishimura, E., Nolan, P., Venkata Ratnam, J., Semmler, T., Sweeney, C. & Wang, S. (2008). Ireland in a Warmer World: Scientific Predictions of the Irish Climate in the Twenty-First Century. Final Report of C4I. Dublin: C4I. Available from: http://www.c4i.ie/publications.php (accessed 22 January 2014).Google Scholar

Mearns, L. O. (2003). Issues in the impacts of climate variability and change in agriculture. Climatic Change 60, 1–6.CrossRef Google Scholar

Mendelsohn, R., Nordhaus, W. & Shaw, D. (1996). Climate impacts on aggregate farm value: accounting for adaptation. Agricultural and Forest Meteorology 80, 55–66.CrossRef Google Scholar

Mera, R. J., Niyogi, D., Buol, G. S., Wilkerson, G. G. & Semazzi, F. H. M. (2006). Potential individual versus simultaneous climate change effects on soybean (C3) and maize (C4) crops: an agro-technology model based study. Global and Planetary Change 54, 163–182.CrossRef Google Scholar

Meza, F. J., Silva, D. & Vigil, H. (2008). Climate change impacts on irrigated maize in Mediterranean climates: evaluation of double cropping as an emerging adaptation alternative. Agricultural Systems 98, 21–30.CrossRef Google Scholar

Midmore, D. J., Cartwright, P. M. & Fisher, R. A. (1982). Wheat in tropical environments. 1. Phasic development and spike size. Field Crops Research 5, 185–200.CrossRef Google Scholar

Mitchell, R. A. C., Mitchell, V. J., Driscoll, S. P., Franklin, J. & Lawlor, D. W. (1993). Effects of increased CO₂ concentration and temperature on growth and yield of winter wheat at two levels of nitrogen application. Plant, Cell and Environment 16, 521–529.CrossRef Google Scholar

Morison, J. I. L. & Lawlor, D. W. (1999). Interactions between increasing CO₂ concentration and temperature on plant growth. Plant, Cell and Environment 22, 659–682.CrossRef Google Scholar

Nelson, G. C., Rosegrant, M. W., Koo, J., Robertson, R., Sulser, T., Zhu, T., Ringler, C., Msangi, S., Palazzo, A., Batka, M., Magalhaes, M., Valmonte-Santos, R., Ewing, M. & Lee, D. (2009). Climate Change: Impact on Agriculture and Costs of Adaptation. Washington, DC: IFPRI. Available from: http://www.ifpri.org/sites/default/files/publications/pr21.pdf (accessed 22 January 2014).Google Scholar

Nelson, G. C., Rosegrant, M. W., Palazzo, A., Gray, I., Ingersoll, C., Roberton, R., Tokgoz, S., Zhu, T., Sulser, T. B., Ringler, C., Msange, S. & You, L. (2010). Food Security, Farming and Climate Change to 2050: Scenarios, Results, Policy Options. Washington, DC: IFPRI. Available from: http://www.ifpri.org/publication/food-security-farming-and-climate-change-2050 (accessed 22 January 2014).Google Scholar

Otter-Nacke, S., Ritchie, J. T., Godwin, D. C. & Singh, U. (1991). A User's Guide to CERES Barley – V2.1. Muscle Shoals, AL: International Fertilizer Development Centre.Google Scholar

Parry, M. L., Rozenzweig, C., Iglesias, A., Livermore, M. & Fisher, G. (2004). Effects of climate change on global food production under SRES emissions and socio-economic scenarios. Global Environmental Change 14, 53–67.CrossRef Google Scholar

Parsons, D. J., Cooper, K., Armstrong, A. C., Mathews, A. M., Turnpenny, J. R. & Clark, J. A. (2001). Integrated models of livestock systems for climate change studies. 1. Grazing systems. Global Change Biology 7, 93–112.CrossRef Google Scholar

Ramsden, S., Gibbons, J. & Wilson, P. (1999). Impacts of changing relative prices on farms level dairy production in the UK. Agricultural Systems 62, 201–215.CrossRef Google Scholar

Ramsden, S. J., Wilson, P. & Gibbons, J. (2000). Adapting to agenda 2000 on combinable crop farms. Farm Management 10, 606–618.Google Scholar

Reidsma, P., Ewert, F., Lansink, A. O. & Leemans, R. (2010). Adaptation to climate change and climate variability in European agriculture: the importance of farm level responses. European Journal of Agronomy 32, 91–102.CrossRef Google Scholar

Ritchie, J. T. & Otter, S. (1985). Description and performance of CERES-Wheat: a user-oriented wheat yield model. In ARS Wheat Yield Project (Ed. Willis, W. O.), pp. 159–175. ARS-38. Washington, DC: US Department of Agriculture, Agricultural Research Service.Google Scholar

Ritchie, J. T., Singh, U., Godwin, D. & Bowen, W. T. (1998). Cereal growth, development, and yield. In Understanding Options for Agricultural Production (Eds Tsuji, G. Y., Hoogenboom, G. & Thornton, P. K.), pp. 79–98. Systems Approaches for Sustainable Agricultural Development, vol. 7. Dordrecht, The Netherlands: Kluwer Academic Publishers.CrossRef Google Scholar

Robredo, A., Perez-Lopez, U., De La Maza, H. S., Gonzalez-Moro, B., Lacuesta, M., Mena-Petite, A. & Munoz-Rueda, A. (2007). Elevated CO₂ alleviates the impact of drought on barley improving water status by lowering stomatal conductance and delaying its effects on photosynthesis. Environmental and Experimental Botany 59, 252–263.CrossRef Google Scholar

Rosenzweig, C. & Tubiello, F. N. (1997). Impacts of global climate change on Mediterranean agriculture: current methodologies and future directions. An introductory essay. Mitigation and Adaptation Strategies for Global Change 1, 219–232.CrossRef Google Scholar

Rötter, R. & Van De Geijn, S. C. (1999). Climate change effects on plant growth, crop yield and livestock. Climatic Change 43, 651–681.CrossRef Google Scholar

Seo, S. N. & Mendelsohn, R. (2008). An analysis of crop choice: adapting to climate change in South American farms. Ecological Economics 67, 109–116.CrossRef Google Scholar

Shrestha, S. & Hennessy, T. (2006). Analysing the impact of decoupling at a regional level in Ireland: a farm level dynamic linear programming approach. In 26th Conference IAAE, 12–19 August, Gold Coast, Australia. Available from: http://ageconsearch.umn.edu/handle/25458 (accessed March 2014).Google Scholar

Shrestha, S. & Hennessy, T. (2008). A prospect of moving towards free milk quota market in Ireland – will milk quota movement follow efficiency? In 12th Congress of the European Association of Agricultural Economists. 26–29 August, 2008, Ghent, Belgium. Available from: http://ageconsearch.umn.edu/bitstream/43657/2/198.pdf (accessed March 2014).Google Scholar

Shrestha, S., Hennessy, T. & Hynes, S. (2007). The effect of decoupling on farming in Ireland: a regional analysis. Irish Journal of Agricultural and Food Research 46, 1–13.Google Scholar

Shrestha, S., Ciaian, P., Himics, M. & Van Doorslaer, B. (2013). Impacts of climate change on EU agriculture. Review of Agricultural and Applied Economics 16, 24–39.CrossRef Google Scholar

Shrestha, S. K. (2004). Adaptation strategies for dairy farms in central and north-west England under climate change . Ph.D. Thesis, University of Nottingham.Google Scholar

Solano, C., Leon, H., Perez, E. & Herrero, M. (2001). Characterising objectives profiles of Costa Rican dairy farmers. Agricultural Systems 67, 153–179.CrossRef Google Scholar

Styles, D., Thorne, F. & Jones, M. B. (2008). Energy crops in Ireland: an economic comparison of willow and Miscanthus production with conventional farming systems. Biomass and Bioenergy 32, 407–421.CrossRef Google Scholar

Tan, G. & Shibasaki, R. (2003). Global estimation of crop productivity and the impacts of global warming by GIS and EPIC integration. Ecological Modelling 168, 357–370.CrossRef Google Scholar

Teagasc (2009). Management Data for Farm Planning 2008. Carlow, Ireland: Teagasc.Google Scholar

Walker, N. J. & Schulze, R. E. (2008). Climate change impacts on agro-ecosystem sustainability across three climate regions in the maize belt of South Africa. Agriculture, Ecosystems and Environment 124, 114–124.CrossRef Google Scholar

Witzke, H. P., Ciaian, P. & Delince, J. (2014). CAPRI Long-Term Climate Change Scenario Analysis: The AgMIP Approach. JRC Technical Reports. Luxembourg: Publications Office of the European Union.Google Scholar

Wolfe, D. W. (1994). Physiological and growth responses to atmospheric CO₂ concentration. In Handbook of Plant and Crop Physiology (Ed. Pessarakli, M.), pp. 223–242. New York: Marcel Dekker.Google Scholar