10584_2018_2357_Article 43..59


Managing expectations: articulating expertise in climate
services for agriculture in Belize

Sophie Haines1

Received: 16 January 2018 /Accepted: 19 December 2018
# The Author(s) 2019

Abstract
A range of institutions and individuals are engaging in the provision, translation, and applica-
tion of scientific climate information, with the aim of supporting agricultural decision-making
in the context of climate variability and change. This article contributes to understanding
political and ethical dimensions of climate services by focusing on how expertise is articulated
by those who deliver anticipatory information to potential users. The article draws on interviews
and observations with forecasters, advisors, and decision-makers in Belize—a low-lying,
coastal country recognised to be particularly vulnerable to the impacts of climate change. I
show how emerging debates over who and what is left out of climate services are not only about
the use and usability of climate knowledge, but about how individuals and institutions are
positioned in relation to each other and to uncertain futures in Belize and elsewhere.

1 Introduction

The domain of climate services, conceived as providing decision-makers with timely and
targeted climate information derived from scientific research, has been developed to enable
more effective adaptation by bridging a gap between science and policy. In the USA, explicit
efforts in this direction included the promotion of public-private co-operation under the 1978
National Climate Program Act (Hecht 1984), the resulting regional climate centres (Changnon
et al. 1990), and debates about the establishment of a national climate service (Miles et al.
2006).1 Long-standing concerns with societal impacts of climate have gained international

Climatic Change (2019) 157:43–59
https://doi.org/10.1007/s10584-018-2357-1

1Associated efforts included the International Research Institute for Climate and Society (IRI) at Columbia
University, and Regional Integrated Sciences and Assessments (RISA) program.

This article is part of a Special Issue on “Putting Climate Services in Contexts: Advancing Multi-disciplinary
Understandings” edited by Sophie Webber

Electronic supplementary material The online version of this article (https://doi.org/10.1007/s10584-018-
2357-1) contains supplementary material, which is available to authorized users.

* Sophie Haines
sophie.haines@insis.ox.ac.uk

1 Institute for Science, Innovation & Society, University of Oxford, Oxford OX2 6PN, UK

/Published online: 4 January 2019

http://crossmark.crossref.org/dialog/?doi=10.1007/s10584-018-2357-1&domain=pdf
http://orcid.org/0000-0001-7974-953X
https://doi.org/10.1007/s10584-018-2357-1
https://doi.org/10.1007/s10584-018-2357-1
mailto:sophie.haines@insis.ox.ac.uk


policy momentum through IPCC assessments and the Global Framework for Climate Services,
implemented in 2012 (Hewitt et al. 2012; Vaughan and Dessai 2014). The identification of a
need for user input to help balance credibility, salience, and legitimacy (Cash et al. 2006), and
facilitate social accountability (Meehan et al. 2018) has motivated the “coproduction of climate
science knowledge” (Meadow et al. 2015), sometimes within “boundary organisations” that
mediate science and policy (Agrawala et al. 2001; Guido et al. 2016). Tools, portals, maps, and
workshops have proliferated under this rubric. A growing body of work has examined farmers’
responses to climate forecasts (Broad and Agrawala 2000; Crane et al. 2010; Hansen 2002;
Letson et al. 2001; Patt and Gwata 2002; Roncoli 2006) and the role of public and private
sector intermediaries (Haigh et al. 2015; Lemos et al. 2014). Less well understood are the
associated epistemological, political, and ethical implications (Carr and Owusu-Daaku 2016;
Goldman et al. 2018), and the perceptions, needs, and choices of those acting as
intermediaries/advisors (Mase and Prokopy 2014).2 This article contributes to understanding
these dimensions of climate services by examining what they mean and entail for those
working “on the ground” to deliver them in the Belizean agriculture sector.

As a low-lying, coastal country, dependent on climate-sensitive industries including agri-
culture, fisheries, and tourism, Belize has been recognised in international and regional risk
assessments as vulnerable to weather and climatic variability: from day-to-day weather events
to seasonal/interannual variability in precipitation and temperature, and longer-term changes in
temperature, precipitation, and storm intensity (CaribSave 2012). Precipitation is an important
limiting factor for Belizean agriculture (rain-fed cultivation is common). Excessive rainfall can
cause waterlogging and disease; drought conditions limit water availability for crops. Much of
the Caribbean, including Belize, has an annual dry season (Nov/Dec–May/Jun), and a wet/
hurricane season (May/Jun–Nov/Dec). The El Niño Southern Oscillation (ENSO) is an
important driver of interannual rainfall variability (WMO 2016).

Increasing understanding of ENSO and other drivers has contributed to production of
seasonal consensus predictions of rainfall including by the Caribbean Climate Outlook Forum
(CARICOF) and Central American Climate Outlook Forum (CACOF)—two of 20 regional
forums supported by the World Meteorological Organisation (WMO 2017). Belize attends
both. The regional forums constitute deliberate attempts to engage “users” of climate informa-
tion, though they go about this in different ways, from linear information transfer to more
collaborative efforts (Daly and Dessai 2018). Daly and Dessai (2018) found that the CARICOF
and CACOF are among the forums that have developed collaborative strategies to co-produce
sector-specific products. In Belize, efforts to deliver climate services for agriculture at the
national level have primarily involved monthly to seasonal rainfall outlooks, published by the
Belize National Meteorological Service (NMS).3 Belize is thus a productive site to study if/how
purposeful efforts at user engagement play out, in a context where climate variability and
change are recognised as potential threats to livelihoods, businesses, and food security.

This article examines how people working between climate research and forecast application
engage with agricultural decision-makers, in a context where climate services are promoted by
global, regional, and national organisations as ways to mitigate weather- and climate-based
risks. It is informed by anthropological and science studies approaches that foreground how
expertise is enacted in practice, and recognise the mutual implication of knowledge production

2 For a recent study addressing this issue in the USA, see Haigh et al. (2018).
3 These timescales are the focus of this article, although my interlocutors’ perceptions and experiences of weather
and climate variability did not always fit these frames.

44 Climatic Change (2019) 157:43–59



and world-making. Many accounts of climate services focus on technical and institutional
barriers to uptake and co-production of knowledge (Dilling and Lemos 2011; Guido et al.
2016; Vogel et al. 2017). In line with this special issue, I focus rather on contextualising how
knowledge is articulated and contended in everyday interactions, to help understand how climate
hazards and services relate to wider practical, political, and ethical challenges. This is a way to
critically analyse established utilitarian modes of accountability, which cater to those in a position
to represent “society” and make claims on the scientific community, for example, funders and
governments (van der Hel 2016; Meehan et al. 2018). As Strathern argues: “Only certain social
practices take a form which will convince, one which will persuade those to whom accountability
is to be rendered – whether it is ‘the government’ or the taxpayer/public – that accountability has
indeed been rendered” (2000:1–2). How might environmental knowledge be more answerable to
perceptions and realities of broader constituencies? Vaughn has described interdisciplinary
climate adaptation collaborations as responses to an “unruly world” that “forces one expert
group to seek help from others, building a new ecology of expertise to adapt to a changing
climate” (2017:262). The uncertain world is one of environmental, political, and social dynamics
that often overspill established categories of technical resolution and practical governance.

The article proceeds by explaining the research methodology and outlining concepts of
expertise and co-production in relation to climate services. I then describe the institutional
landscape of climate services provision in Belize, setting out the key organisations, products,
and perceived challenges. The main empirical section focuses on accounts of how advisors
work to “manage expectations”—that is, how they tackle the interconnected challenges of
anticipating uncertain environmental futures, negotiating their own roles as “experts”, and
engaging potential “users”. I close with a discussion of how attention to ground-level
articulations of expertise and participation sheds light on understandings of responsibility that
come into view as climate services are situated in broader political and ethical contexts.

2 Methods

This article is based on 3 months of qualitative anthropological fieldwork in 2014 in Belize—a
small country of fewer than 400,000 people yet much diversity in ethnicity, ecology, class, and
education—where I have conducted anthropological research since 2006.4 The 2014 study was
part of a wider research programme investigating social and technical dimensions of forecasting
for resource stewardship across international cases, reflecting a range of governance styles,
environmental contexts, technical capacities, and cultural settings. The Belizean case was an
opportunity to study the role of forecasting in a country where weather and climate sensitivities
are recognised, national capacity for forecast modelling is limited, and international institutions
play key roles relating to the production and circulation of weather/climate information.

Research in Belize included interviews with 60 participants with professional interest in
weather/climate forecasts for resource and hazard management. I identified potential inter-
viewees in an institutional mapping process that started with core relevant organisations (e.g.
Caribbean Community Climate Change Centre (CCCCC), NMS, Ministry for Natural Re-
sources and Agriculture) and proceeded via key informant networking, attendance at relevant
events, and documentary research. Participants ultimately represented a wide range of sectors

4 Detailed examination of demography/ethnicity is beyond the scope of this article; for more, see Bolland (1988);
Medina (1997).

Climatic Change (2019) 157:43–59 45



(agriculture, development, education, emergency, environment, forecasting, municipal, water)
and public, private, and non-governmental organisations. In line with the study’s aims to better
understand the perceptions, needs and choices of forecasters, advisors, and other decision-
makers, the interview method enabled participants to articulate priorities and experiences in
their own words. To accommodate their interests while ensuring consistency (Bernard
2006:212), I used a semi-structured protocol covering: organisational priorities; decision-
making processes; weather/climate sensitivities; availability of forecasts; and future planning.5

Where possible, interviews were ethnographic (Heyl 2001): informed by ongoing interactions
which aided mutual understanding and encouraged participants to develop narratives beyond
organisational mission statements. To trace how knowledge is developed, communicated and
debated among actors and organisations, and to understand practice and narrative in relation to
one another, I supplemented interviews with participant observations (Bernard 2006:342).
These included three operational shifts at the NMS, a hydrological modelling workshop, a
coastal planning seminar, and a university climate change conference.

I categorised the cohort of 60 interviewees according to primary and, where relevant,
secondary sector.6 Of the total, 27 were involved in agriculture, development and/or forecast-
ing (primary or secondary sector). These interviews form the main empirical basis for this
article. They include weather forecasters, meteorologists, and climate scientists; agriculture
ministry liaison staff and extension officers; sugar industry researchers and buyers; other
agricultural researchers; representatives of cacao, citrus, and grain growers’ associations;
environmental NGO staff; and adaptation practitioners. The majority of interviews were
recorded and transcribed. I undertook a qualitative thematic analysis, using iterative reading
and memos to identify and cross-check material that related to respondents’ perceptions and
experiences of delivering and accessing climate services.

3 Expertise and co-production in climate services

Core rationales underpinning climate services identify information supply and demand as key
problems, and user-orientation as an important potential remedy (Harjanne 2017). Climate
services involve transnational frameworks, resource-intensive technologies, expert networks,
and user engagement. As such, they are a productive domain for studying how information and
ideas travel (or do not) across global and local contexts (Weisser et al. 2014). Climate services
are promoted on the grounds of their societal benefit; however, social science studies of
climate knowledge provision have shown there can be ethical and social justice implications
of imposing particular visions of the future or models of decision-making under uncertainty
(Broad et al. 2002; Lemos and Dilling 2007; Furman et al. 2014; Webber and Donner 2017).
Taddei’s ethnographic work in Brazil highlights the “performativity” of climate forecasts; he
argues that their technocratic use entails “flattening the imagination of future realities”
(2013:258), as they necessarily simplify the world, incorporating often implicit decisions
about what “counts” and can be acted upon. These studies call attention to what is and is
not recognised as legitimate expertise in climate services, and to the practical and political
implications of who participates (or does not) in the co-production of knowledge (and society).

5 See supplementary material.
6 See supplementary material.

46 Climatic Change (2019) 157:43–59



The notion of “expertise” is well-embedded in climate services discourse: “scientifically
credible information and expertise” is fundamental (Hewitt et al. 2012); institutional providers
are centres of climatological expertise (Changnon et al. 1990). In apparent tension with the
user-orientation of climate services discourses that typically argue for highly collaborative
activities (Harjanne 2017), this emphasis on scientific expertise as the defining feature of
centres of production arguably shores up a linear model of science. In this model, expert
knowledge is delivered to relatively passive users (McNie 2012); the scientific category of
climate becomes the determinant of regional futures (Hulme 2011; Krauss and von Storch
2012). Turning to the agricultural context, this recalls Scott’s (1998) account of scientific
agriculture as an authoritarian intervention that renders nature and production “legible” and
therefore manageable. Scott argues that such attempts usually fail, precisely because they
neglect situated knowledges that do not fit their paradigm. An alternative approach emphasises
expertise as enacted and contended by a range of actors (Carr 2010), and experts as “desiring,
relating, doubting, anxious, contentious, affective… human-subjects” (Boyer 2008:38). Paying
attention to the experiences of advisors who deliver climate services is a way to explore
multiple and embodied tensions of expertise and collaboration.

The term “co-production” has gained traction in debates about climate knowledge in
general and climate services in particular (Jasanoff and Wynne 1998; Dilling and Lemos
2011; Meadow et al. 2015; Bremer and Meisch 2017). However, its interpretation has been
ambiguous. Normative uses of the term, which foreground the instrumental goal of co-
producing knowledge by bringing together a range of different stakeholders, arguably risk
overshadowing fundamental questions of politics and ethics (Goldman et al. 2018). Descrip-
tive formulations (Jasanoff 2004) interpret co-production not as an instrumental practice or
normative ideal, but as an analytical idiom that describes the inevitable mutual constitution of
science and society. Lövbrand’s study of a European climate research programme investigated
tensions between interpretations: “there may be a trade-off between research co-produced to be
accountable to the knowledge needs of societal decision-makers, and co-produced research
that seeks to challenge and transform existing ways of thinking” (2011:231).

If we take seriously both the proposition of involving different actors in knowledge
production, and the inseparability of knowledge-making and world-making (Goldman et al.
2011), choices about how knowledge is produced and whose knowledge counts are also
questions of who gets to shape the future. The crux shifts beyond delivering robust and/or fair
outcomes for specific problems, to broader questions: who decides what constitute legitimate
concerns, appropriate evidence, acceptable solutions, and possible futures? This calls for
reflexivity about often well-intentioned efforts to include diverse voices. As critical scholars
of development have shown—including for projects involving weather/climate information—
utilitarian and normative ideals of participation do not always lead to effective or equitable
outcomes (Cooke and Kothari 2001; Peterson et al. 2010; Taddei 2011). Failure to address
power dynamics of participation in practice can introduce or reinforce inequalities that resonate
beyond specific projects. The challenge is arguably magnified in contexts involving long
timescales and uncertain outcomes—such as climate adaptation (Few et al. 2007).

4 Institutional landscapes of Belize climate services

Prior to my 2014 visit, consultations under the Global Framework for Climate Services had
been initiated in Belize by a group of national, regional, and global organisations including the

Climatic Change (2019) 157:43–59 47



NMS, the CCCCC, the Caribbean Institute for Meteorology and Hydrology (CIMH), and the
WMO. Their activities included a 2013 stakeholder meeting on agriculture and food produc-
tion (WMO 2014) and the first national climate outlook forum in 2014. Perhaps unsurpris-
ingly, given Belize’s low population count, the cohort of people involved in climate services at
national level constitutes quite a small world. The national work was led by the NMS: an
organisation with fewer than 10 meteorologists, forecasters, and climatologists, and a focus on
operational weather forecasting. At the time of research, there was no national capacity to run
sophisticated computer simulations of future weather and climate. As such, international
networks were influential in supporting climate services and related efforts.7 With its distinc-
tive history as a former British colony on the Caribbean coast of Central America, Belize
straddles geopolitical regions and attends both the Caribbean and Central American Climate
Outlook Forums, in which countries prepare national seasonal forecasts using a standardised
methodology8 and discuss results face-to-face or by teleconference to agree a probabilistic
regional outlook.9 Following regional forums, the NMS publishes the consensus seasonal
forecasts on its website, alongside monthly forecasts of expected rainfall ranges tuned to each
of its 12 weather stations.

Senior NMS staff reported feeling isolated from feedback about the forecasts from potential
users (exceptions included the National Emergency Management Organisation and an agri-
culture department contact). With other meteorologists and climate scientists, they often
framed the problem of uptake as one of public education (Callon 1999), highlighting bound-
aries between research and application, scientists and (non-scientist) stakeholders (Gieryn
1983). CCCCC staff described tensions between dual organisational goals of effective adap-
tation and innovative science, for example attributing the difficulty of explaining a new
weather scenario product to potential users to the fact that it was “the front line of research”.
One staff member distinguished different stakeholder mindsets, and distanced them from
meteorologists and climate scientists: “the water people think differently than the agriculture
people, and they all think differently than the weather people and the scientists.” A former
government meteorologist called for a “socialisation of the forecast”. For him, this meant
facilitating a linear chain of information from forecasters to extension officers to “progressive”
farmers who could educate others. He and others identified resource issues (a small, weather-
focused NMS team) and public perceptions (that the NMS was only relevant during emer-
gencies10) as key obstacles.

Research participants discussed different solutions to these challenges. Mobile telephone
messaging was much-discussed; however, obstacles included expense and poor rural coverage.
While radio could help overcome these issues, some agricultural researchers felt that personal
interactions were needed, albeit these were often described as one-directional: technical
advisors would “tell [growers] what they need to do” (as recommended by a sugar researcher).
Following a more participatory, “co-production”-oriented model of user engagement, the NMS

7 As well as monthly/seasonal forecasts from NMS and regional forums, the government sources climate
expertise from CCCCC projects and from consultants hired to draft policies/environmental impact assessments
using long-term projections.
8 The IRI Climate Predictability Tool.
9 CACOF was convened in 2000 following the 1997/8 El Niño; it issues three outlooks per year. CARICOF was
relaunched in 2012 (following a 1998 attempt); it issues monthly 3-month outlooks (WMO 2016; Guido et al.
2016).
10 One forecaster attributed this to the service being moved under the National Emergency Management
Organisation.

48 Climatic Change (2019) 157:43–59



(supported by regional bodies such as CIMH) had promoted “farmer forums” to bring
agricultural stakeholders face-to-face with scientists who could communicate forecast content
and uncertainties, while eliciting user needs. However, a government scientist noted that
because the NMS usually just puts its agro-meteorological forecasts online and many farmers
do not have internet access, more quotidian forecast communication often falls to the agricul-
tural extension service. In the rest of this article, I examine how extension agents and others in
similar roles articulate expertise in relation with other agents of climate knowledge and
agricultural decision-making.

5 Articulating climate services for agriculture

Agriculture is a mainstay of commercial and subsistence economies in Belize, with sugar,
bananas, and citrus juices leading crop exports. Sugar dominates in the north11; citrus and
banana are focused in southern districts. Sugar and citrus juice production involves small- to
large-scale growers, represented by associations, who sell to processing plants in Belize. The
banana industry consists of mainly large-scale growers (also with an association) who sell to
an international brand. Other common crops include grains (maize/rice), beans, cacao, and
other fruits and vegetables. Outside major export industries, much large-scale production is
undertaken by Mennonite communities that have adopted mechanised cultivation.12

Weather sensitivities vary with crop and scale. In export industries, concerns about precip-
itation were closely tied to their impact on crop-specific pests and diseases (sugarcane
froghopper Aeneolamia postica jugata; citrus disease huanglongbing, spread by the psyllid
Diaphorina citri; sigatoka, a disease of bananas caused by Mycosphaerella fijiensis). Interview
participants expressed different orientations to risk and success: buyers and researchers
prioritised productivity and scientific management; small-scale farmers were anxious to avoid
serious losses; mechanised farmers considered how they could combine weather knowledge
with machinery and pest control. A grain growers’ representative described risk management
as dependent on an art of “leaning” rather than calculating; a metaphor that conjures a
situational attentiveness in navigating uncertainties and information sources: “The most
successful person is … not the person who hits it exactly right all the time; it’s the one
who manages the risk.” He was discussing mechanised farming, which can include
irrigation: this can delink growing cycles from weather patterns, but requires large
investments, inaccessible to many growers. Reliable seasonal forecasts could be useful
for those able to obtain irrigation equipment in advance of a dry spell, a citrus researcher
noted, but not all farmers had the capacity to respond: “if you don’t have the means you
have to suffer the losses.”

A range of actors commented that increasingly unstable climatic conditions had reduced
their confidence in seasonal expectations based on historical patterns, prompting a search for
more reliable and relevant information, in line with the stated aims of climate services:

It becomes very difficult to look at your past data and have some reliability… That used
to be a way of forecasting, but it’s difficult now (Farmer liaison, sugar factory)

11 Since 2014, planting and processing has started in western Belize.
12 Mennonites have arrived in Belize from the USA and Canada since the 1950s, many via Mexico and El
Salvador. Some eschew mechanised farming; others have embraced it.

Climatic Change (2019) 157:43–59 49



We don’t believe any more in [historical data] because of climate change. In the past it
was a good thing to use historical data to predict, but now it’s very complicated (NGO
agriculture officer)

You can't rely anymore on saying we have rainy season, hot months… I think it's
becoming worse every year… [the farmers] come to you now for information (Govern-
ment extension co-ordinator)

The Met Office … need to better understand what kind of decisions farmers are making,
and therefore would be better able to answer questions that the farmers have. (Farmers’
association leader)

The first two quotations identify problems with established sources of information (i.e.
expectations based on historical trends); the third is an observation about farmers’ demand
for information from extension officers; the fourth argues for user engagement to help
forecasters give more salient advice, suggesting an instrumental role for “co-production”.
The following sub-sections focus on key predicaments that meteorologists, researchers, and
farmers’ advisors raised during interviews: the risks of providing as well as following expert
advice under uncertainty; and the power dynamics of legitimate knowledge and legible
practice.

5.1 Advice under uncertainty

Situated between research and operational science, meteorologists occupy a liminal position,
enacting expertise in relation to atmospheric uncertainty and the vagaries of public commu-
nication (Daipha 2015; Fine 2007). Some NMS forecasters expressed resignation about
failures of linear communication (“if they don’t heed [the forecast], we cannot do anything”).
Agricultural extension services also act as mediators, arguably representing archetypal “bound-
ary organisations” (Cash 2001), bound into debates about participatory agricultural research
and development (Scoones and Thompson 2009) and tasked with translating science and
technology into usable advice that—unlike most meteorologists—they deliver directly to
farmers (Hansen 2002). Government-supported extension in Belize operates mainly through
the ministry responsible for agriculture (the statutory sugar research institute also has an
extension department); services are also provided by NGOs (notably in the south where
government provision is less developed) and growers’ associations.

Faced with farmers’ demand for weather/climate information (as per the third quotation
above), government agriculture officers reported feeling ill-prepared. They noted that salient
information is often unavailable or inconsistent; its flow impeded by limited data and staff
time. Within the ministry responsible for agriculture, an officer had been appointed as a climate
change “focal point” specialist to sit on the National Climate Change Committee endorsed by
Cabinet in 2010. The person holding this role in 2014 had taken it on in 2011 in addition to
existing duties. At the time, he was the only officer specialising in climate change and
agriculture. Resource pressures made it hard to process information from the wide range of
sources and communicate with policymakers, farmers, and scientists. Upstream delays were
another challenge: having developed confidence in seasonal outlooks through interactions with
senior NMS staff, he had taken it upon himself to convert NMS monthly agro-meteorological
forecasts into maps for distribution to extension officers, NGOs, and others. However, he had

50 Climatic Change (2019) 157:43–59



recently stopped because of delays in obtaining the forecasts. I was told that some of the
government extension officers delivered printed NMS agro-meteorological forecasts to
farmers, but were not monitoring their use or tracking a dialogue. An extension co-ordinator
described the work that would be needed to properly equip the advisors, noting that they were
starting from a point where “the farmers look at us and we look at them, and we are not too
sure what to say.”

Other ministry representatives compared seasonal forecast content and farmers’ expectations: the
forecasts predict averages over time and do not account well for timing of precipitation—this is
problematic because much rain comes in tropical waves. A grain farmers’ representative explained
that rainfall onset and duration was more critical than average amount, owing to the threat of
waterlogging. A senior agricultural researcher in a regional institute noted a mismatch between
forecasters’ and users’ perspectives on success. He observed that a probabilistic forecast showing
33% likelihood for each tercile (above-normal/normal/below-normal rainfall) may satisfy its pro-
ducers, who assess the reliability of the forecasting system over time. However, information in this
form “is not anything to us [farmers]”. A statistical measure of forecast system performance may not
seem helpful if a decision-maker’s livelihood depends on a one-off binary choice. To illustrate, the
researcher explained how his confidence had been dented after a recent seasonal forecast (of elevated
chance of above-normal rainfall) had informed his own decision to plant soybeans rather than
cowpeas—a decision that resulted in a perceived loss when retrospectively compared with the
decision he stated he would have made without the forecast.

While these problems of resource constraints and forecast format/performance provide
insights into possible barriers to information uptake, of particular relevance to this article are
the personal narratives through which advisors reflected on the challenges of climate service
provision. Extension service staff expressed apprehension about giving advice in the context of
incomplete knowledge and high decision stakes:

[Extension officers] might not feel confident enough to be able to tell someone to plant
or not to plant. Because we know the cost of that investment, so you might have to find a
way to let them decide somehow… some officers might not want to take that chance …
We're not really trained, we're not too sure how to make these decisions and how to
advise properly. Because just as they don't understand, we're trying to keep up – even the
definition of what climate change is and what it means for us. (Government extension
co-ordinator)

The co-ordinator’s resolution that farmers “make that decision … take that risk on their own”
acknowledges the probabilistic character of the forecasts and the economic and reputational
stakes of climate services provision. It moves to position the farmer as the responsible subject
(Phillips and Ilcan 2007). Although the co-ordinator explained that their worst-case scenario
would be to fail to pass on advice and thus be deemed useless, this danger exists in tension
with a reluctance to offer firm guidance, given possible unfavourable outcomes. Another
agriculture officer noted the problem of being perceived (or perceiving oneself) to have “cried
wolf”: “If we prepare for something and it doesn’t happen, then we’ll get discouraged the next
year when maybe it will hit for real”. Even when adverse weather did eventuate, some
extension officers were uneasy about potential dependency entailed by associated government
decisions, such as providing seed and fertiliser following excessive rains. In this case, the
extension service invited the department’s climate change specialist to give a scientific
presentation (including graphs and historical data) as a strategy to enact expertise beyond
the “casual, general conversation” that characterised extension officers’ usual interactions. The

Climatic Change (2019) 157:43–59 51



objective was to explain uncertainties and—they hoped—encourage farmers to take the issues
seriously and be proactive. Yet, as the senior researcher’s comments showed, communicating
uncertainty may not guarantee “success”.

As well as acknowledging resource-related factors (time, funding, data, training), these narratives
highlight different understandings of success given uncertainty, and raise questions about the roles
and responsibilities of experts and the meaning of climate change. The confidence and capacity of
extension workers to support decisions—and their perceptions of what is at stake and who takes the
blame for adverse outcomes—affect their delivery of climate services. As Desai (2006) has
described for Rajasthan, extension agents negotiate shifting and conflicting identities and modes
of authority in their work at the interface of science, government, and rural life. Their articulations of
apprehension, and the tensions in the narratives of those who are both researchers and farmers,
resonate with Boyer’s (2008) description of experts’ human-subjectivity. They reflect situated
understanding of the diverse goals and priorities of different actors, and anxiety about how they
might be called to account for the outcomes of decisions that do not sit comfortably in a narrow
domain linking knowledge and action. As such, they recognise that as well as the challenge of co-
producing knowledge in an instrumental sense (e.g. aligning the timescales of forecasts with
farmers’ decision processes), there is a deeper sense in which these services can performatively
“co-produce” forms of accountability and behaviour change. Interactions between advisors and
advisees involve delicate negotiations of responsibility—for example through disclaimers about
accuracy, reliability, and dependency—that shape relationships among farmers (citizens), the state,
and other collectivities.

5.2 Negotiating legitimate knowledge and legible practice

Faced with variable climatic conditions, imperfect forecasts, and lack of confidence in official
sources, farmers continued to make decisions based on a range of indicators, experience, and
advice. Many listened to NMS weather bulletins on the radio (focusing on the next 24 h, with
an outlook to 4 days), supplementing with other available resources: online sources or their
own instruments (larger-scale farmers) and/or tried-and-tested local knowledge, risk-spreading
strategies like multi-cropping, and moral economies (smaller-scale and subsistence farmers13).
Extension workers acknowledged these other sources of information:

The farmers consider [the NMS forecast] to be more general. So, they don't count on it.
They go by experience, or they have their own way of going on a hill top and looking at
such an angle. They have their own cultural - their own little ideas of how they
determine. They work a lot with the moon and that kind of thing. So, they make their
decisions on their own (Government extension worker)

The planning of agricultural activities according to lunar phases is widespread among many
Mestizo, Creole, and Maya farmers. A Mennonite farmer and growers’ representative also reported
use of environmental indicators (fog and dew characteristics), noting that “some people make fun of
it”—an observation suggestive of many scientists’ and technicians’ views of “planting by the
moon”. One government forecaster who had facilitated a “farmer forum” discussion session
described how participating farmers had persistently asked for information about moon phases,
demanding recognition of their practices. The forecaster recalled that on reporting this in plenary, the
convenors preferred not to discuss it: they were there to discuss “farming scientifically”. It struck me

13 Wilk (1997) and Zarger (2009) present examples from Maya communities.

52 Climatic Change (2019) 157:43–59



that the forecaster’s summary of the impasse—“so that is what we are faced with: people who have a
mindset about certain practices that work”—could arguably refer to both parties: the farmers
interested in lunar phases to the exclusion of curiosity about scientific forecasts, and the convenors
reluctant to discuss practices that were illegible in the framework of the scientific workshop.14 The
accounts of scientists and extension workers perform “boundary work” (Gieryn 1983) when they
seek to distinguish certain situated practices (especially those of smaller-scale farmers) from
scientific knowledge. The discursive separation and hierarchization of “scientific” and “cultural”
knowledge would appear to limit the scope of user engagement in these interactions to a linear
model of knowledge transfer and public education (Callon 1999). The extension worker’s comment
bolsters the assertion of farmers’ responsibility by noting that farmers are drawing on knowledge
outside legitimised technical frameworks of extension and climate services.

Technical staff at the research arm of the citrus growers’ association reflected on the
reluctance of their members to heed their technical advice. They framed this as a problem of
their legitimacy as “local experts”, embedded in the farming communities that constitute the
users of their technical advice. They described in Biblical terms their perception of a culture
among farmers that undermined their organisation’s credibility: “you cannot be a prophet in
your own land” (Luke 4:24). For advice to be heeded, they felt it would have to be enforced by
a more distant authority—probably government. This perspective presents a challenge to
prevailing social science ideas about the effectiveness of interpersonal communication at
community level (e.g. Kunreuther et al. 1985), and suggests a need to think carefully about
the contexts of participatory expertise and authority, noting how trust relations and hierarchies
operate within “community” settings as well as between “communities” and other entities such
as governments.

Meanwhile, in the banana industry—dominated by a few large growers—the latest project
to involve weather/climate information was led by an NGO which was purposefully not
working through government, on the grounds of inertia and bureaucracy. The NGO’s interest
in using precipitation modelling to reduce unnecessary fungicide application had an environ-
mental basis; however, they argued their case to growers using an economic rationale. The
ongoing conversation relied on the NGO as an intermediary identifying the growers’ economic
priority and framing the information in terms that the growers perceived as legitimate. Climate
services advisors (whether government extension agents, growers’ association researchers, or
NGO staff) were pushed to consider and perform alternative cultural, political, and economic
framings. These debates about legitimacy highlight diverse priorities and relations of trust that
depend on the needs and capacities of potential “users” and also their social relations with
those who provide and communicate forecast information.

A brief consideration of proposed scientific management for the sugar sector further
illustrates how questions of environmental knowledge are embedded in relations among
citizens, the state, and other entities. The language of yield maximisation is prevalent across
commercial agriculture; however, sugar productivity was framed as particularly urgent as the
industry braced for a price drop in 2017.15 Sugar is sensitive to rain at harvest (waterlogged
fields are hard to reap; excess water dilutes cane) and the froghopper pest’s lifecycle and
control are rain-dependent. Although not explicitly framed as a “climate services” project, the
management system’s developers at the industry’s statutory research institute (SIRDI)

14 For a contrasting example from Kenya, where traditional and scientific forecasts were purposefully brought
into conversation (though not without political/epistemic challenges), see Haines et al. (2017).
15 The EU was lifting quotas that had protected African, Caribbean and Pacific cane sugar industries.

Climatic Change (2019) 157:43–59 53



explained the aim to incorporate weather and climate data and forecasts (e.g. from their own
weather stations, NMS, and NOAA, and via models developed by international institutes/
NGOs) alongside other variables. The objective was for the system to help the buyer (privately
owned processing factory) and other industry actors set harvest dates, schedule factory stops,
adjust quotas (used to manage the factory’s purchase of farmers’ cane), mobilise pest treat-
ments, and predict crop quality.

These motivations underpinned the development of a GIS database: a bird’s-eye view that
aimed to make production legible to those with access to the maps. A SIRDI technician
stressed the anticipatory promise of a management system that would be “one step ahead”,
enabling SIRDI to advise farmers when to harvest. Factory and institute representatives hoped
for insight into farmer behaviour, aiming to encourage farmers to work harder during good
weather, mitigate perverse incentives (whereby a farmer may hold onto degrading cane to meet
quotas), reward “progressive” farmers (those increasing yields/quality), and change behaviour
of growers characterised as planning-averse. They saw potential for anticipatory quality
control: the model would “know” when cane from each field should be ready and could reject
deliveries outside the expected window. For the researchers, it seemed, the system promised
more legitimate decision-making than that of the farmers.

While much data could be obtained from satellites, it also had to be “ground-truthed”. This
required the participation of individual farmers; at the time of research, this was proving
difficult. Factory and SIRDI staff noted that the farmers’ association had provided some soil
data, but personal details and field access were less forthcoming. Trust between farmers and
factory—long subject to antagonism—was foundering amid a dispute about by-product
pricing and tensions about precarious markets.16 In this situation, some farmers were appar-
ently resisting attempts to make their practices digitally legible. While researchers within the
industry asserted that weather was the greatest threat to the sector, factory representatives
indicated that key decisions were more sensitive to investments, markets and industrial
disputes. Considering how climate forecasts might fit into such a management system thus
demands reflection: on accountability for decisions influenced by probabilistic predictions; on
flexibility to include or exclude alternative grounds for decision-making; and on how existing
power dynamics work implicitly through new technologies.

The system’s anticipatory ambition brings to mind Scott’s (1998) characterisation of
scientific agriculture as a process of taming nature and disciplining growers from a position
of remote oversight. However, it does not neatly fit Scott’s characterisation of such schemes as
the domain of an authoritarian state. While sympathetic to Scott’s argument, Li (2005) raises
critiques that are pertinent here: questioning the possibility of an all-seeing state; noting the
roles of non-state actors and welfare approaches; and challenging the separation of situated
knowledge from power structures. Indeed, this example involves multiple non-state authorities
(private companies, development partners), and the system’s proponents did not aim to fully
eliminate local knowledge, instead seeking insights into farmers’ knowledge, behaviour, and
decision-making, and promising transparency and fairness as well as productivity. Thus, the
system could be seen to represent a utilitarian effort to co-produce knowledge, combining
different data sources to create information with proposed benefits to a range of stakeholders.
This instrumental ideal was nonetheless disrupted by tensions that suggested what was really at
stake were industrial relations and farmer autonomy.

16 I was unable to meet with the association (which has since split into three), ostensibly owing to these
circumstances.

54 Climatic Change (2019) 157:43–59



6 Discussion

In this article, I have examined how people positioned as mediators of climate services articulate
expertise in their work. I have argued that attention to their perceptions and choices can help
identify the inclusions, exclusions, and contentions that lie behind utilitarian goals of climate
services and normative discourses of participation. Different advisory relationships (e.g. in-
volving government extension workers, growers’ associations, or NGOs) present a range of
challenges for negotiating what is (or is not) legitimate knowledge, and thus for shaping as well
as being shaped by the political and ethical landscape of agriculture and society.

Meteorologists noted that evaluation of climate services would be meaningless without
understanding their use: “we might be in here congratulating each other on an excellent
product that is useless out there”. This illustrates the concern of forecast producers to engage
with users in the design and delivery of climate services. However, a focus on the utilitarian
accountability of climate services as scientific products that reflect “knowledge needs of
societal decision-makers” (Lövbrand 2011:231) cements a boundary between science and
society that is likely to reinforce established policy agendas and modes of decision-making.
Scientists’ and advisers’ narratives of interactions with certain groups (particularly small-scale
farmers) often side-lined non-scientific practices, and framed projects as ways to maximise
productivity. This arguably favours prevailing approaches of larger-scale farmers and buyers,
many of whom who have better access to additional information sources (weather stations,
websites), and risk-mitigating technologies. As such, ostensibly participatory processes risk re-
inscribing inequities. Recognising this calls attention to differential abilities to act on infor-
mation, to the modes and constituents of engagement, and to the values embedded in forecasts
that have a particular orientation to the future—that see climate impacts as amenable to
foresight and management (Broad et al. 2002; Peterson et al. 2010; Taddei 2013). Debates
about climate services thus provoke consideration of what transnational expert frameworks
mean for the resilience of situated expertise and practices through which communities address
political-economic and environmental changes (Vaughn 2017).

The extension workers, ministry liaisons, and industry researchers tasked with delivering
information are pushed by eclectic predicaments of climate and agriculture to be “jacks-of-all-
trades”, convening and navigating diverse bodies of knowledge, and negotiating blame/credit
in relationships shaped by contested power dynamics and multi-dimensional uncertainties. It is
perhaps unsurprising that these experts appear as complex human-subjects (Boyer 2008),
rather than abstracted agents of a separated realm of modernity or the state. Extension workers’
frequent emphasis on farmer responsibility exists in tension with normative ideals of co-
production that would arguably implicate shared responsibility, and with the proposed sugar
system that would overrule certain farmer decisions. The examples reveal factors other than
climate variability that may be decisive for agricultural decisions and relationships, but are not
explicitly accounted for in available climate forecast products: the politics of agricultural
production (historically configured relationships between sugar producers and buyers; gov-
ernment support for small-scale farmers); institutional versus individual responsibility for
decisions (anxious expertise of extension workers; contested legitimacy of non-scientific
knowledge); and different (moral) economies (small-scale farmers’ wishes to avoid serious
losses in tension with commercial pressures to increase production). The case of the sugar
management system highlights how contexts such as industrial relations are not “external”
barriers that limit the uptake of information: the rationales underpinning the proposed system
were not only the challenges of environmental conditions, but the perceived behaviours of

Climatic Change (2019) 157:43–59 55



farmers with respect to their relations with the factory owners. These historical and political
relations are thus at the core of the production and promotion of scientific management of
agricultural decisions, not only a limiting factor to be confronted with reference to knowledge
uptake. Such recognition is aligned with the descriptive idiom of co-production as the mutual
constitution of knowledge practices and social order (e.g. Jasanoff 2004).

New ecologies of knowledge are being assembled in contestations of farmer autonomy, the
(de)valuation of different types of expertise, and the vagaries of global economies (Vaughn
2017; Taylor 2018). These points of contention—often considered as background contexts or
external barriers for climate services—are central to how knowledge and action are
(dis)connected through social and political processes. They call for approaches to climate
services that do not focus merely on the use and usability of a product, but on the performance
of agricultural livelihoods (Roncoli 2006) and on relations among citizens, the state, NGOs,
and the private sector. This demands that we question the discursive boundaries between
producers and users, and calls attention to how responsibility might be shared in contexts
where participatory approaches are promoted. The Belize case highlights specific issues
relating to historic colonial and postcolonial agricultural-industrial relations, land tenure, and
the reliance on international networks and donors in the development, promotion, and delivery
of user-oriented climate services. Many of these are also relevant in other geographical
locations. The diversity of approaches and challenges within the sector considered here
indicates a need to attend to the singularity of relationships as well as their broader dimensions.
By paying attention to the different ways that advisors work to manage expectations—both of
uncertain environmental futures and of their own expertise and responsibility—we can better
understand emerging models of environmental governance that influence how individuals and
institutions are positioned in relation to each other and to uncertain futures.

Acknowledgements Sincere thanks to all research participants. I am grateful to Sophie Webber and others
involved in the 2017 American Association of Geographers session from which this special issue emerged; and to
Steve Rayner, Sara de Wit, colleagues at the University of Campinas, and three anonymous reviewers for
valuable feedback on earlier versions. Because of the confidential nature of some research materials, not all data
can be made accessible. Please contact the author for more information.

Funding This work was supported by the Oxford Martin School [Programme on Resource Stewardship]; and
the Economic and Social Research Council [grant ES/N016084/1].

Compliance with ethical standards

Research involving human participants followed principles of informed consent, approved by the University of
Oxford Central University Research Ethics Committee and the Belize Institute for Social and Cultural Research.

Conflict of interest The author declares that they have no conflicts of interest.

56 Climatic Change (2019) 157:43–59

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International
License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and repro-
duction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a
link to the Creative Commons license, and indicate if changes were made.

Publisher’s Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and
institutional affiliations.



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	Managing expectations: articulating expertise in climate services for agriculture in Belize
	Abstract
	Introduction
	Methods
	Expertise and co-production in climate services
	Institutional landscapes of Belize climate services
	Articulating climate services for agriculture
	Advice under uncertainty
	Negotiating legitimate knowledge and legible practice

	Discussion
	References