An
exclusive focus on smallholders risks romanticising their practices, and being
a myopic reaction to the failures of Western, top-down, 'hard' development;
such as large-scale irrigation, dam construction and monoculture cropping. A
celebration of the small, which can dominate the literature, ignores the
benefits of large-scale, commercial farming. Indeed, an increase in labour productivity
and the creation of income opportunities outside of the agricultural sector has
a significant role in poverty reduction, particularly in the face of climate
change, which is likely to affect Africa dramatically. My interests lie in the
interaction between small- and large- scale agriculture, and how different
modes of production might be appropriate to different geographical and
political regions. As I hope has been shown, one need not exclude the
other. Horizontally connecting smallholders with one another, promoting trade
and stronger institutions, as well as forming vertical links between small
farms and larger commercial enterprises can increase income, food security and
climate adaptation.
Africa in Green and Blue
Tuesday, 10 January 2017
Superfarms
A 'superfarm' deal, according to the FAO, is when a foreign government, or company acting on their behalf, takes a very long lease on a huge area of land. Superfarms can be problematic in a number of ways: firstly, they can encourage dramatic consumption of natural resources, particularly water for overhead irrigation or livestock farming. Secondly, they can create a 'monopsony' in the local or regional factor market; the market for production inputs like natural resources and labour. A monopsony occurs when a single buyer interacts with multiple sellers. While it can be advantageous for the superfarm leaseholder, as prices are driven down, it is neither beneficial nor efficient for smaller businesses or local people. Finally, the FAO condemns superfarms as having fundamentally geopolitical aims, rather than concerned with agricultural growth or poverty reduction. It hypothesises that superfarms emerged as a reaction to the 2008 global food crisis, where droughts in grain-producing countries resulted in export bans; a lack of produce entering the world food market drove prices sky-high, causing shortages and riots. Consequently countries that rely heavily on food imports, such as China, have endeavoured to secure a "major source of supply": huge swathes of African land.
The article by the FAO focussed on crop superfarms; I came across an example of a 'dairy superfarm' in Namibia, which seems to avoid many of the aforementioned issues. The !Aimab farm is a Namibia Dairies project, owned by the African company Ohlthaver & List, and is 'super' in the sense of its size, housing around 2000 cows, and its integrated network of supply, production, and processing. The farm has heavily invested in technology, such as computerised milking reports, and has features that protect the cows against Namibia's variable climates, including dry, hot winds and mudslides from excess rainfall. A 'closed cycle' waste management approach has also been adopted; following the farms construction in 2009 manure was used to fertilise the pastures (the cows are free range) but subsequently an attached biogas plant has been constructed. The farm sources the majority of its fodder from local producers, exemplifying one of the ways a large commercial enterprise can be compatible with local smallholders. Of key significance is the farm's focus on the full value chain. Value is added by processing into a wide variety of products, including long-life powder mixes and traditional fermentation. Raw milk is also purchased from local producers, to satisfy the demand for these different products. There has also been investment into the infrastructure of cold chain distribution, to ensure safety and minimise waste. This recalls much of what I mentioned in my previous post about the potential of agricultural value chains in Africa. One issue is the intensive water consumption inherent to dairy farms, for the cows to drink as well as for cleaning and processing. Despite this, efficient use is compatible with many features of the farm. For example, the sourcing of fodder from local farmers where it may be a waste product, rather than growing it specifically for the cows. Also important is that the farm has lined their manure pits to prevent contamination of groundwater.
The article by the FAO focussed on crop superfarms; I came across an example of a 'dairy superfarm' in Namibia, which seems to avoid many of the aforementioned issues. The !Aimab farm is a Namibia Dairies project, owned by the African company Ohlthaver & List, and is 'super' in the sense of its size, housing around 2000 cows, and its integrated network of supply, production, and processing. The farm has heavily invested in technology, such as computerised milking reports, and has features that protect the cows against Namibia's variable climates, including dry, hot winds and mudslides from excess rainfall. A 'closed cycle' waste management approach has also been adopted; following the farms construction in 2009 manure was used to fertilise the pastures (the cows are free range) but subsequently an attached biogas plant has been constructed. The farm sources the majority of its fodder from local producers, exemplifying one of the ways a large commercial enterprise can be compatible with local smallholders. Of key significance is the farm's focus on the full value chain. Value is added by processing into a wide variety of products, including long-life powder mixes and traditional fermentation. Raw milk is also purchased from local producers, to satisfy the demand for these different products. There has also been investment into the infrastructure of cold chain distribution, to ensure safety and minimise waste. This recalls much of what I mentioned in my previous post about the potential of agricultural value chains in Africa. One issue is the intensive water consumption inherent to dairy farms, for the cows to drink as well as for cleaning and processing. Despite this, efficient use is compatible with many features of the farm. For example, the sourcing of fodder from local farmers where it may be a waste product, rather than growing it specifically for the cows. Also important is that the farm has lined their manure pits to prevent contamination of groundwater.
Superfarms are not the solution for agricultural growth in Africa, in part because of their dramatic use of water and other inputs. However, the Namibian dairy superfarm provides an example of how commercial enterprises can be compatible with small-scale farms, by linking them to the value chain and, potentially, national or international markets.
1 Collier P & Dercon S, 2009. African
Africulture in 50 Years: Smallholders in a Rapidly Changing World. FAO Expert Meeting on How to Feed the World in
2050. Accessed 8/1/17 from http://www.fao.org/3/a-ak983e.pdf
2 Ohlthaver & List Group, 2009. Namibia
Dairies- Profile. Accessed 9/1/17
from http://www.ohlthaverlist.com/o-l-companies/namibia-dairies.php#.WHTWOrF0fBI
3 Food Processing Africa, 2008. Namibia
Gets a 'Superfarm' Dairy. Accessed 9/1/17
from http://www.foodprocessingafrica.com/namibia-gets-a-superfarm-dairy/
4 New Era Newspaper Namibia, 2016. O&L
committed to reducing carbon footprint. Accessed 10/1/17 from https://www.newera.com.na/2016/04/19/ol-committed-reducing-carbon-footprint/
Monday, 9 January 2017
'LUSH': An Unlikely Source of Corporate Inspiration
The website of the cosmetics company has some interesting case studies of the work they fund in Africa, particularly the Mountain Organic Farming Network that operates in the arid regions at the base of Mount Kenya. This article highlights the successes of connecting smallholders with large-scale enterprises, and how subsistence food crops can be compatible with cash crops if an innovation, value-chain approach is adopted.
At the farms mentioned, intercropping is practised. This means different crops are planted in close proximity, with considerations such as providing shade to vulnerable species, fixing nitrogen in the soil, or retaining soil moisture. This improves soil fertility and biodiversity in an area that lacks consistent rainfall, and challenges the 'monoculture' approach inherent to large-scale agriculture. Moreover, local farmers choose to grow food crops with specific micronutrients that supplement the cheap, but often nutritionally inadequate, staple crops that are purchased. These methods promote food security; in the concentrated nutritional benefits of these crops, but also because the project links local farmers, and allows them to trade crops that are either surplus or lacking.
Alongside food crops, cash crops are grown. While not a food, geranium plants produce a valuable oil that is in demand in the international market. Local people maintain the business, but this would not have been achieved without LUSH's investment into the value chain infrastructure: the ability to store, process (by distilling), and package the crops. In my opinion, this is an example of an international company contributing to African agriculture in a successful and sustainable manner.
Sunday, 1 January 2017
My Personal Issue of the Week: the Falkenmark Water Stress Indicator
The most widely used measure of water scarcity is the
Falkenmark Water Stress Indicator, developed in 1989, which states that water
availability below 1700m3/capita/year causes regular water stress.
Availability below 1000m3/capita/year is classed as water scarcity
that threatens human health and economic development (and below 500m3/capita/year
indicates absolute scarcity). Indicators are instruments to simplify large
amounts of data, and Falkenmark’s measure achieves this successfully. However,
attempting to aggregate water requirements and water availability into a single
measure loses important information. One such limitation of the Falkenmark
Water Stress Indicator is that it only considers renewable surface water and
groundwater flows within a country. Moreover, averaging water availability
across a spatial and temporal scale neglects water shortages that occur during
dry seasons, and at smaller regional scales. Furthermore, it does not account
for the quality of the water, nor does it describe the ability of the country
to make use of the resource. All of these limitations apply with particular
clarity to African countries, for reasons that have been described in previous
posts.
The Falkenmark Indicator is highly useful because it is understood
intuitively; however, an indicator that is applied so extensively in the realm
of social development should also hold steady the crucial meaning of the
challenges under consideration. To me, a key limitation of the Falkenmark
Indicator is not the loss of information, but the loss of action. Preoccupation
with one measure promotes lethargy in two dimensions: first, if the parameters
of the indicator are adjusted, different countries become ‘water scarce’,
meaning the label of ‘water scarcity’ has less weight and the tackling it
appears overwhelming; second, if the indicator is used in relation to a single
discourse, any challenge to that discourse that emerge, including from the
indicator itself, are ignored. I would like to illustrate this in the following
ways.
Firstly, explicitly accounting for the water needs of
ecosystems pushes many ‘developed’ countries into apparent water scarcity,
including large parts of Europe, North America and Australia. The competition
between ecosystems and irrigated agriculture in these areas is not at the
forefront of the discourse, perhaps because large-scale water use already
blends seamlessly with economic and development success. The term ‘water
scarcity’ often brings to mind domestic shortages; for drinking and sanitation,
but this is fractional compared the water requirements of agriculture and
industry. Domestic water use is not affected by scarcity in the physical sense,
but by supply infrastructure, poverty and politics. Therefore, it follows that
a sensible application of the thresholds proposed by Falkenmark is to indicate
that water is becoming scarce for food production, particularly in arid or
highly climatically variable parts of Africa. Why then, is the continent pushed
towards a ‘Green Revolution’, a plan for agricultural production that involves
massive water use? Furthermore, on a more technical note, it makes little sense
for the Falkenmark Indicator to be heavily linked to water scarcity for agriculture
when soil moisture, the recipient of a large proportion of annual rainfall, is
excluded from the measure.
Another theme that arises from the Falkenmark indicator the
negative impact of population growth on water resources: population growth
essentially multiplies the water requirements set out by Falkenmark et al., while the amount of surface
water and groundwater remains relatively constant. However, daily water needs
are likely to be dynamic, and dependent on income, lifestyle and attitude.
Currently, it appears this flexibility in water use will only exacerbate
scarcity; in the 20th century the world population tripled, but
water use increase six fold2. The potential impact of attitudes and
lifestyle can alternatively be seen as an opportunity for positive change. This
can be seen in the energy sector, with the achievement of increasing efficiency
and the adoption of corresponding values. Of course, there is far more to
achieve regarding energy use, but what is often most important, and most difficult,
is initiating a change in the existing system.
A similar change needs to happen within the current paradigm
of water use, particularly for agricultural production. In my opinion, there is
little point in the ability to say, “this area is water scarce”, when nothing
is done about it. While the value of the Falkenmark Indicator remains in
situations where information needs to be conveyed quickly and simply, measuring
water scarcity should include more observational and longitudinal measures. It
is a near consensus that water management needs to be more participatory, seen
in the increasing popularity of ‘integrated resource management’, but true
democratic participation is likely to emerge from communities and regions being
able to say “WE are experiencing water scarcity”; rather than a distant
indicator labeling them as such. More importantly, action should follow any
observation or confirmation of water scarcity. This is more likely to be
achieved with decentralised, efficient and adaptable strategies that focus on
two key areas of water: maintaining soil moisture, for example through
controlled flood releases at dams, the use of terraces (such as in Machakos,
Kenya) or simply encouraging a diversity of moisture-retaining plant species on
farms; secondly, a focus on developing highly productive strategies of
micro-irrigation, such as drip irrigation3, 4. The Falkenmark
Indicator, whether intentionally or not, places the individual user at the
centre, therefore the individual users should be given the capacity to adapt to
water scarcity effectively.
1 Rijsberman FR, 2006. Water scarcity: Fact or
fiction? Agri Wat Manag, 80(1-3):
5-22.
2 Cosgrove WJ & Rijsberman FR, 2000. World Water Vision: Making Water Everybody’s
Business. London: Earthscan Publications.
3 Gleick P, 2003. ‘Soft Path’ solution to 21st-century
water needs. Science, 320(5650):
1524-28.
4 Postel S, 2001. Safeguarding our water –
Growing more food with less water. Sci Am,
284(2): 40-45.
5 NTUA. Indicators and indices for decision
making in water management. EEMRU
Newsletter. Accessed 30/12/16 from http://environ.chemeng.ntua.gr/WSM/Newsletters/Issue4/Indicators_Appendix.htm
Thursday, 22 December 2016
Buyers vs. Sellers
Something that has caught my attention in the literature was Staatz et al.'s suggestion that African smallholders are both the net sellers AND the net buyers of food. Their study of food security in Mali found a record crop harvest in 1989 that led to a surplus of grain. Thus, the government heavily promoted exports in order to boost prices at farm-level, and increase the incomes of the smallholders producing the grain - the net sellers, located in the climatically favourable southeastern region. However, this caused conflict in another region of Mali: the more arid northern area, where farming is less feasible and food such as staple crops are mostly purchased. Putting higher prices on basic food staples, while benefiting those southeastern smallholders, negatively impacted people, particularly poor people, in the northern regions of Mali - the net buyers. In some cases, local officials even attempted to block grain exports as they passed through the northern zones. Here we can see a dilemma constitutive to food policy in many countries, but particularly severe in Africa due to sheer number of rural smallholders: how to reconcile the conflicting needs and interests of net sellers and net buyers of crops, when they may live in the same country, or even the same region?
When considering the variability of Africa's rainfall (see Access Not Amount: Africa's Uncultivated Land) one must not solely focus on how the amount and distribution of water impacts food production. Look further, and it affects the heterogenous means by which individuals and households achieve food security: by growing their own crops, as in wetter southeastern Mali, or relying on markets, like arid northern Mali. Further still, and this impacts the policy interests of individuals, households and regions. Measures of food security have an important role in this discussion as they inform policy and direct interventions such as subsidies or aid. However, overly simplistic measures may present a uniform picture when, as we have seen, there are variable and context-dependent routes to achieving food security, and profiles of food security itself. According to Staatz et al. (1990) commonly used indicators often poor predictors of food security. Consequently, the resulting policy may be overly uniform and ineffective. The measures and indicators of food security need to be improved, for example to be more area-specific; this will be discussed in-depth in a subsequent post. Furthermore, there should be greater focus on strengthening features of agriculture that encourage adaptability and dynamism. Improving productivity, rural markets and agricultural infrastructure can help to decouple individual and household food security from the fluctuations in production due to climate and water availability. For areas even less proximate to food production, it is important to ensure functioning markets outside of, or linked to, agriculture that allow a reliable income stream so food can be purchased. Africa is perhaps set apart from other countries by the significant presence of people growing, selling and buying the same food. Therefore, it may require less strong, static and centrally controlled food policy, and more investment into institutions and organisations that are flexible, and can be controlled locally or regionally.
Friday, 16 December 2016
Monday, 28 November 2016
A Consideration of Agricultural Value Chains, and Their Relevance to Africa
What is an agricultural value chain?
“The focus should be on the full
value chain – from farm to fork, not just production”1. Claudius
Kurtna, a fish farmer from Kenya, highlights in simple terms a concept that is
hard to delineate in the literature. While there is no universal definition of
the ‘agricultural value chain’, I will be operating under the FAO’s
characterisation of the value chain as identifying the set of actors and
activities that bring a basic product from production to final consumption2.
At each stage, or link of the chain, value is added to the product: through
processing, packaging, storage, transport, distribution and marketing. While
value chain models are inherently market-based, they have emerged alongside the
realisation that economic liberalisation in the 1980s and 1990s, accompanied by
state withdrawal from agriculture, has not translated into significant poverty
reduction2. This newer discourse focuses on food security and
sustainability, and has been compounded by the global food price crisis in
2007-08, and the threat of climate change. Producers, particularly small-scale
and of staple crops, are now seen as central players2,3.
In my opinion, applying a value
chain model to food production in Africa is beneficial for several reasons.
Firstly, it is inherently bottom-up, as it begins with the producer, and
inclusive. It also clearly identifies current barriers to food security in
Africa; considering the ‘chain’ as a whole allows us to see the challenges at
each stage, which promotes holistic and sustainable improvements. Finally, as
it is couched in the realm of business and markets, it promotes efficiency and
adaptability. This not only applies to the industrial processes of production
and distribution, but also to the inputs into the chain, of which water is one.
Therefore, this body of this post will be divided into two parts: the first
part will aim to illustrate the points above by discussing food storage as a
stage in the chain that has challenges and opportunities specific to Africa;
the second will broadly and briefly consider the role of water in the value
chain.
Storage: hidden
barrier?
Often
highlighted in literature on African agriculture is the need to invest in
infrastructure, however this largely focuses on roads, electricity and
telecommunications. I only considered the necessity of storage for farming when
I heard Dr Annie Kinwa-Muzinga discuss women and agriculture on an episode of
the radio show Congo Live4. Without storage there is waste:
according the FAO, a third of all food produced in sub-Saharan Africa is lost
before it reaches the market6. This is due to storage that is
contaminated, infested with pests, or of inadequate capacity. Poor quality
storage at the transport stage means that produce, particularly staple crops
like grain and oilseed, simply spills from the back of dilapidated trucks7.
Another challenge is ‘forced commerce’: poor smallholders have to sell almost
all of their crops at harvest time for low prices, because they are unable to
store them5. Without investment into the infrastructure that links
each stage of the value chain, the benefits of market involvement will not be
evenly distributed. Private traders will benefit form these low prices, and
poor smallholders will be left without5.
Beyond the necessity of storage to sustain the farmer, it can be considered as an opportunity to add value to produce directly from farms. Kurtna, the aforementioned Kenyan fish farmer, makes high-protein, high-energy biscuits out of his harvest1. These have a long shelf life, thus can be stored far longer and with greater ease than fresh fish, and target new consumers; for example schools have already ordered the biscuits. In a similar vein is an example given by Dr Kinwa-Muzinga of a female farming cooperative in Ghana that salt or smoke the fish they catch4. This preserves it for longer, and makes the product more desirable and worthy of a higher price.
These examples highlight the role of agriculture beyond just food production. It is a business and an agent of positive societal change, in areas like gender equality, malnutrition and education. Catching fresh fish does not improve child education in Africa, but creating nutritious and long-lasting fish biscuits that are sold to schools might be able to. In my opinion, the value chain model reflects and encourages these connections; between different smallholders and farmers, with new consumers, and between small-scale producers and markets at different levels, from local packaging factories to global trade. We need to consider agriculture beyond the initial product.
Beyond the necessity of storage to sustain the farmer, it can be considered as an opportunity to add value to produce directly from farms. Kurtna, the aforementioned Kenyan fish farmer, makes high-protein, high-energy biscuits out of his harvest1. These have a long shelf life, thus can be stored far longer and with greater ease than fresh fish, and target new consumers; for example schools have already ordered the biscuits. In a similar vein is an example given by Dr Kinwa-Muzinga of a female farming cooperative in Ghana that salt or smoke the fish they catch4. This preserves it for longer, and makes the product more desirable and worthy of a higher price.
These examples highlight the role of agriculture beyond just food production. It is a business and an agent of positive societal change, in areas like gender equality, malnutrition and education. Catching fresh fish does not improve child education in Africa, but creating nutritious and long-lasting fish biscuits that are sold to schools might be able to. In my opinion, the value chain model reflects and encourages these connections; between different smallholders and farmers, with new consumers, and between small-scale producers and markets at different levels, from local packaging factories to global trade. We need to consider agriculture beyond the initial product.
Water as a
production input, and some general conclusions
The
relationship between food and water is inescapable: “no other supply chain
needs or consumes a natural resource in the [same] proportions”8. Water
is necessary at almost every stage of the agricultural value chain: to irrigate
land and process produce, in packaging factories, transport and refrigeration3.
Professor Tony Allan asserts that about 90% of the water needed by an
individual or national economy is embedded in their food consumption, as ‘green
water’, ‘food water’ or ‘virtual water’. To me, a recent entrant into this academic
world, it seems obvious that viewing water as a production input into the
agricultural value chain necessitates efficient and sustainable use; it is a resource
with extraction costs, and it has a monetary worth that should be accounted
for. However, throughout history water has been largely ignored as an economic
input, due to an assumption that it is ‘free’ by producers and an overwhelming
push for cheap food by consumers and governments8.
For these reasons, Allan calls for a paradigm change around water use. If the majority of water is used to produce food, then the natural managers of water are not hydrologists and governments, but farmers. Yet, farmers have not been provided with the necessary resources to both sustain a secure livelihood and “[steward] the water ecosystems on which society itself depends”8.
To me, the perspective of agricultural value chains clearly highlights where there needs to be investment to support African farmers. There is infrastructure at every link of the chain that needs to be improved to make agriculture a successful business. Furthermore, infrastructure must come before intensification; any kind of ‘Green Revolution for Africa’ will be futile and damaging if there is nowhere to store the surplus grain. While the agricultural value chain is just a concept, and a complex one at that, it provides an alternative way of looking at food and water in Africa that has the possibility of being profit-oriented and sustainable, with a role for farmers, private corporations and state regulation in turn.
References
1 BBC Africa. 2011. Why young Africans are swapping the office for the farm. Accessed
15/11/16 from: http://www.bbc.co.uk/news/world-africa-36914887
2 Elbehri A & Lee M. 2011. The role of women producer organizations in
agricultural value chains: lessons from Africa & India. FAO: Rome.
3 Besada H & Werner K. 2015. An assessment of
the effects of Africa’s water crisis on food security and management. Int J Wat Res Dev. 31(1): 120-33.
4 Congo Live, 2015. Gender issues in agriculture
in DRC and across Africa. Accessed 10/11/16 from: https://www.mixcloud.com/congolive2/gender-issues-in-agriculture-in-drc-and-across-africa-dr-annie-kinwa-muzinga/
5 Havnevik K, Bryceson D, Birgegård LE, Matondi P & Beyene A. 2007. African Agriculture and the World Bank:
Development or Impoverishment? Nordic Africa Insitute: Uppsala.
FAO. 2011. Global food losses and food waste – Extent,
causes and prevention. FAO: Rome.
6 Wildeboer E & Bosch P. 2015. Why we must invest in local food storage in
sub-Saharan Africa. Guardian sustainable business. Acessed 20/11/16 from: https://www.theguardian.com/sustainable-business/2015/jan/15/invest-local-food-storage-sub-saharan-africa
7 Allan JA. 2015. Water and Food Security: Food-water and Food Supply Value Chains. In
Antonelli M & Greco F (eds.), The
Water We Eat, Springer Water: Switzerland.
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