Practice Sheet: Land Sparing vs Land Sharing PDF

Summary

This practice sheet examines the concept of land sparing versus land sharing, analyzing the trade-offs between biodiversity conservation and food production. It explores different perspectives on food, including food production, food security, and food sovereignty. The practice sheet also discusses the concept of carrying capacity and the limitations of a purely biophysical approach. It encourages a more nuanced understanding of the complexities surrounding food and biodiversity.

Full Transcript

Practice sheet
1 and 2. Demography and Carrying capacity.
Global scale
texts here:

“Land Sparing Versus Land Sharing: Moving Forward”- Joern Fischer ✅
viktige quotes:

The framework on land sparing versus land sharing is essentially an economic one
because it is interested in the efficient allocation of a scarce resource, namely land

Food production: technology-focused. Much literature on the written history of
hunger has come at it from the perspective of “too many people, too little food,”
and thus has looked at remedying famine and chronic hunger through increasing
food production.

Food security: states-focused. Food security can be de- fined as physical and
economic access by all people in a society at all times to enough culturally and
nutrition- ally appropriate food for a healthy and active lifestyle (e.g., Food and
Agriculture Organization of the United Nations [FAO] 1996). This
multidimensional definition was developed in response to research showing that
“starvation is the characteristic of some people not hav- ing enough food to eat.

Food sovereignty: people-focused. Food sovereignty de- fines “the rights of local
peoples to determine their own agricultural and food policy, organize production
and consumption to meet local needs, and secure access to land, water, and seed”

Practice sheet 1
 (Wittman 2010). It is viewed by proponents as a corrective to the inadequacies of
“food security,” which “avoided discussing the social control of the food system

Practice sheet 2
 Indeed, many sustainability problems that in- volve both social and environmental
considerations are “wicked” problems—in such problems there is no “right”
solution, but “only trade-offs that appear more or less favorable depending on your
perspective” (Game et al. 2014)

No matter how biodiversity is defined, by focusing on one part of biodiversity, the
consequences of any given land use strategy on other parts of biodiversity might be
glossed over or underestimated. Management might favor, for example, species that
are rare or those that provide particular ecosystem functions. While many rare
species cannot survive in farmland, many species that provide important ecosystem
functions can. Some of these species, in turn, provide ecosystem services that
positively influence yields (Bommarco et al. 2012).

In a nutshell, the framework fits into discourses on food production and land
scarcity, but says nothing about food security or food sovereignty. It can help to
identify trade-offs, but cannot tell us which of these trade-offs are socially desired.
Its answers on biodiversity are only as good as the ways in which biodiversity is
defined and measured. The framework distinguishes between two hypothetical
conservation mechanisms (sparing versus sharing) but is not well- designed to

Practice sheet 3
 address scale issues or globalization ef- fects. Finally, the viable coexistence of
humans and nature hinges on many additional variables that defy quantification.

The authors identify several points of contention within this framework, one of which is
the focus on food production. Much of the research on land sparing versus land sharing
focuses on minimising harm to biodiversity while producing food. The paper highlights
that the concept of 'food' is studied by scholars from diverse disciplines, leading to
different perspectives on the land sparing versus land sharing framework. These
communities include those focused on ecology, economics, and land use science, as well
as those working on poverty reduction and sustainability.

The authors note that the concept of “food” is often approached from three perspectives:
Food production: This approach concentrates on increasing food production through
technological advancements, with a historical emphasis on addressing hunger by
increasing food supply.

Food security: This perspective considers the availability, access, and utilisation of food,
acknowledging that production alone does not guarantee food security for all.
Food sovereignty: This view emphasizes local control and self-determination over food
systems, promoting local production and consumption, and challenging the dominance of
global market forces in shaping food systems.
The paper also discusses the concept of a production possibility frontier, which shows the
most efficient allocation of land for producing two goods – biodiversity and agricultural
production. Trade-off analysis can help to distinguish between efficient and inefficient
land allocations. However, the authors argue that trade-off analysis often oversimplifies
the issue, neglecting factors like scale effects and teleconnections.

For example, implementing a land sparing system in one region might result in
agricultural activities being shifted to a different region through global trade dynamics, a
phenomenon known as leakage. These spatial interdependencies are often overlooked in
land sparing versus land sharing analyses.

The authors conclude by making several recommendations for moving forward in the
debate on land sparing versus land sharing:

1. Critically evaluate the use of partial trade-off analyses, acknowledging their
limitations.

2. Recognise that choosing how to quantify biodiversity involves subjective decisions.

3. Address the scale effects and teleconnections that impact land-use decisions.

Practice sheet 4
 4. Develop alternative, more holistic frameworks to analyse the relationship between
food and biodiversity. One promising approach is to view agricultural landscapes as
social-ecological systems, considering the interplay of social and ecological factors.

The authors encourage a more nuanced understanding of the complexities surrounding
food and biodiversity, moving beyond the simplistic binary of land sparing versus land
sharing.

“Humanity's Fundamental Environmental Limits” Binder ✅
This paper by Binder et al. explores the concept of Earth's carrying capacity for humans,
focusing on biophysical limits. The authors develop a model to estimate carrying
capacity under various technological scenarios.
While not explicitly discussing land sparing versus land sharing, the paper provides
insights relevant to the debate:

The authors emphasize that technological advancements can significantly impact
carrying capacity estimates. For instance, improvements in agricultural technology
can increase food production per unit of land, potentially allowing for higher
population densities.

The paper highlights the importance of considering multiple resource constraints
simultaneously. Their model incorporates factors like sunlight, water, and essential
nutrients to determine how many people Earth can sustainably support under
different scenarios.

They acknowledge the limitations of a purely biophysical approach, suggesting that
social and cultural factors play a crucial role in defining carrying capacity in
practice. The authors advocate for linking biophysical models with economic models
to assess trade-offs between population, consumption, and technology.

The findings of this study, while not directly addressing the specifics of land sparing or
land sharing, reinforce the need to consider technological possibilities and resource
limitations in conservation and land management decisions.

“Does agroforestry conserve trees?” Lila Nath Sharma, Ole Reidar Vetaas ✅
viktige sitat

We compared different measures of diversity; number of tree species in the sample
plots (alpha diversity), total number of species in each land-use type (gamma
diversity), and the change in species composition along an elevational gradient (beta
diversity), which follows the classical definition of Whittaker (1972) [details in the

Practice sheet 5
 data analysis section]. We consider that trees in farmland are a mixture of natural
forest species and introduced fodder and fruit species.

The balance of the trade-offs between forest harvesting and tree
retention/plantations in farmlands can contribute to conserving forest as well as trees
in an agroforestry landscape. Integrating community forestry under the land-sharing
strategy, therefore, seems a promising option to manage biodiversity in an
agricultural landscape. However, the concept of biodiversity should go beyond
‘greenness’ or ‘forest cover’ to include different aspects of species diversity.
Conservation planning must acknowledge the role of traditional as well as new
agroforestry practices in species maintenance and con- servation in addition to
anthropocentric provisioning ecosystem services (Manning et al. 2006; Tscharntke
et al. 2011). Multipurpose trees on farmland should be promoted because they
provide supplementary habitats and dispersal corridors for other species (Bhagwat
et al. 2008; Harvey and Villalobos 2007; Schuepp et al. 2012; Tadesse et al. 2014)
and also play a role in soil conservation through erosion control and slope stability
(Young 1989).

This study by Sharma and Vetaas examines tree species diversity in farmland and forest
ecosystems in the central hills of Nepal, a region where agroforestry is a common
practice. Agroforestry is a land sharing strategy that integrates trees into agricultural
landscapes, providing a variety of ecosystem services while also potentially supporting
biodiversity.

The authors sought to determine if agroforestry contributes to tree species conservation
in this region. They compared tree diversity in farmland to that of adjacent, sustainably
managed forests.
They tested three specific hypotheses:

1. Alpha diversity is higher in farmland than in forest.

2. Gamma diversity is lower in farmland than in forest, potentially due to the
planting of the same tree species across farmlands, leading to homogenisation.

3. Tree species composition differs between farmland and forest due to the
inclusion of both local forest trees and introduced species on farmlands.

Their findings revealed that:

Farmlands had consistently higher alpha diversity compared to forests.

Practice sheet 6
 While there were many shared species, farmland and forest ecosystems differed in
composition due to varying species abundances and unique species present in each
land use type.

Farmland demonstrated higher gamma diversity compared to the forest,
contradicting their initial hypothesis.

The study highlights that agroforestry plays a significant role in maintaining tree
species diversity in agricultural landscapes. The authors argue that these findings
challenge the common assumption that forests generally harbour higher biodiversity than
open landscapes. They suggest that agroforestry may even enhance biodiversity in certain
cases.
The authors emphasize the need to consider agroforestry in conservation planning. They
note that existing national biodiversity policies in Nepal often overlook the role of trees
on farmlands as a crucial component of agrobiodiversity. They advocate for greater
recognition and support of agroforestry practices to achieve both local and regional
biodiversity conservation objectives.

“Population Growth and Earth's Human Carrying Capacity” - Joel E. Cohen ✅
This article by Cohen discusses the concept of human carrying capacity and its
implications for sustainability. The author surveys various methods for estimating
carrying capacity and examines the limitations of each approach.
The paper does not explicitly address land sparing and land sharing. However, it provides
a broader context for understanding the challenges of balancing human population
growth with resource availability and environmental conservation.
Key points relevant to the debate include:

Cohen highlights the inherent uncertainty in estimating carrying capacity due to
constantly changing technological, social, and environmental factors. This dynamic
nature makes it difficult to define a fixed carrying capacity for humans.

The article emphasizes the importance of considering multiple, interdependent
factors that can constrain human population growth. These can include food, water,
energy, and other resources, as well as environmental impacts like pollution and
climate change.

Cohen critiques deterministic and static approaches to estimating carrying capacity,
advocating for models that incorporate stochastic variability and dynamic
interactions between human and environmental systems.

Practice sheet 7
 These insights underscore the need for a nuanced and adaptive approach to managing
land for both human needs and biodiversity conservation, acknowledging the
uncertainties and complexities involved.

Agroforestry: a refuge for tropical biodiversity? ✅
vikitge sitater:

Therefore, any approach that aims to mitigate tropical deforestation and protect
biodiversity should address the livelihoods and needs of local communities

First, we highlight the changing concept of ‘pristine nature’ by arguing that people
have played a key role in shaping many of the so-called pristine forests of today and
empha- sise that future approaches to conservation need to con- sider agroforestry.
Second, we recognise the so-called matrix effect on species diversity in landscape
mosaics with native tree cover, and suggest that agroforestry sys- tems can provide
corridors that connect distant reserves

Although there is no doubt that protected areas do contribute hugely to preserving
large parts of the biodiversity on Earth, such areas often fail to cover the entire
diversity of ecological habitats and species and, as crucially, strict protection of such
areas is often resented by local people. In a recent debate over the future of
tropical forest species, it has been suggested that although some forest specialists
need ‘intact’ forest habitat, the bulk of tropical species will be forced to persist in
degraded and secondary habitats outside forest reserves in the future (see Ref.
and references therein). There- fore, the need for biodiversity conservation in
human- dominated landscapes in the tropics is greater today than ever

First, many agroforestry systems are shown to be important for the protection of
species and habitats outside formally protected areas. For example, Williams-
Guillen and colleagues found that shade coffee plantations in Nicaragua can
serve as alternative wildlife habitats and as corridors between forest fragments for
mantled howling monkeys Alouatta palliata

Second, agroforestry systems maintain heterogeneity at the habitat and landscape
scales. For example, Parikesit and colleagues identified 12 different plant
assem- blages in Kebon Tatangkalan agroforests of the Upper Citarum Watershed,
West Java, Indonesia. These agrofor- ests are maintained by small households
spread across the watershed and contribute to the highly heterogeneous species
assemblages in the regional flora.

Third, trees in agroforestry landscapes reduce pressure on formally protected forest
reserves. Murniati and col- leagues studied the availability of forest resources

Practice sheet 8
 in mixed gardens and village forests in the northern part of the Kerinci Seblat
National Park, Sumatra, Indonesia. They found that households that owned mixed
gardens depended much less on national park resources than households which
cultivated wetland rice fields alone.

Although agroforestry systems cannot stand alone as conservation areas, they can
buffer existing reserves and provide corridors for persist- ence and movement of
species across landscapes (e.g. Ref. ). Such systems offer a useful means for
combating species loss as a result of tropical forest fragmentation
3

The literature reviewed suggests that agroforests with less intensive management
and high canopy cover have high species richness and are more similar to
neighbouring forest reserves than intensively managed agroforests with open
canopies. Effective management of agroforestry sys- tems, therefore, entails several
aspects (see Box 1). First, we suggest an integrated approach to reserve networks
that includes agroforestry systems as an important con- servation tool. Second, we
recommend that farmers who maintain agroforests might, in particular
circumstances, be offered compensation in the form of various incentives for
biodiversity-friendly farming practices. Third, we advo- cate that awareness and
education programmes are crucial to make farmers self-sufficient and to harness the
potential of agroforests for biodiversity conservation

This opinion piece by Bhagwat et al. explores the potential of agroforestry for
biodiversity conservation in tropical regions facing deforestation and habitat loss.
The authors challenge the traditional conservation focus on ‘pristine nature’ within
protected areas. They argue that many seemingly pristine forests have a history of human
influence, and that future conservation strategies must consider the importance of human-
modified landscapes.
The authors reviewed numerous studies comparing species richness and composition in
agroforestry systems to neighbouring forest reserves. They found that:

Agroforestry systems can support a significant proportion of the biodiversity found
in forests, with average richness exceeding 60% of forest values.

The similarity in species composition between agroforestry and forests varies
depending on the taxa and management intensity. For instance, mobile taxa like bats,

Practice sheet 9
 mammals, and birds exhibited higher similarity values compared to plants.

Agroforestry systems tend to have higher species richness and greater similarity to
forests when: (1) conversion from forest to agroforestry occurred relatively recently;
(2) management is less intensive; and (3) canopy cover of native trees is high.

The authors highlight three key reasons why agroforestry systems are valuable for
biodiversity conservation:

1. They provide habitat for species outside of protected areas. For example, shade
coffee plantations can serve as habitat for various forest-dwelling species and act as
corridors between forest fragments.

2.They maintain habitat heterogeneity at both the habitat and landscape scales. This
is because farmers often manage their agroforestry plots differently, leading to a mosaic
of different tree species and vegetation structures across the landscape.
3.Trees in agroforestry landscapes can reduce pressure on protected forest reserves.
By providing resources like timber and fuelwood, agroforestry can alleviate the need for
communities to extract these resources from protected forests.

The paper discusses the concept of ‘countryside biogeography’, which emphasizes the
importance of considering the surrounding landscape matrix in conservation planning.29
The authors argue that agroforestry systems can play a crucial role in connecting
protected areas and facilitating species movement across fragmented landscapes.

They conclude that while agroforestry systems cannot replace protected areas, they can
serve as valuable complements, offering a means to conserve biodiversity within human-
dominated landscapes. thr authors recommend:

1. Integrating agroforestry into conservation planning.

2. Providing incentives for farmers who engage in biodiversity-friendly agroforestry
practices.

3. Raising awareness and providing education about the importance of agroforestry for
conservation.

Definitions and Terminologies

Land Sparing:

A conservation framework proposing the separation of conservation and production
activities. It often involves intensifying agriculture in some areas to maximise yields,

Practice sheet 10
 thereby allowing other areas to be set aside for biodiversity conservation. seperate
between agirculture and conservation

seperation

Land Sharing:
A conservation framework suggesting the integration of conservation and production
within the same landscape. This typically involves implementing wildlife-friendly
farming practices that support biodiversity within agricultural areas.

rather about integrating both,

integration

Land Scarcity:
A concept highlighting the increasing demand for land for various purposes, including
food production, housing, and infrastructure development, which can compete with
biodiversity conservation goals.

Food Security:
A state where all people at all times have physical and economic access to sufficient,
safe, and nutritious food to meet their dietary needs and preferences for an active and
healthy life.

Food Sovereignty:
A concept emphasising people's rights to define their own agricultural and food policies,
control their food systems, and prioritize local needs over global market demands.

Production Possibility Frontier:
A graphical representation showing all efficient combinations of producing two goods or
services (e.g. biodiversity and agricultural production) given current technology. It
illustrates the trade-offs between maximising one good at the expense of the other.

Trade-off Analysis:
A process of evaluating the costs and benefits of different land use options, considering
the potential impacts on multiple goods and services, such as biodiversity, agricultural
production, and ecosystem services.

Agroforestry:
An agricultural system that intentionally integrates trees and shrubs into crop and
livestock production systems, creating a more diverse and potentially biodiverse
agricultural landscape.

Practice sheet 11
 Alpha Diversity:

A measure of species richness within a specific area or habitat.

Beta Diversity:
A measure of species turnover or dissimilarity in species composition between different
areas or habitats.

Gamma Diversity:

The total species diversity within a larger region, encompassing multiple habitats or
areas.

Teleconnections:
The interconnectedness of land use activities across different geographical locations,
often through global trade networks. These connections can lead to the displacement of
land use impacts and affect biodiversity in distant areas.

Carrying Capacity:
The maximum population size of a species that an environment can sustain indefinitely,
given the available resources, environmental conditions, and the species' consumption
patterns.

stoichiometric
stoichiometric" refers to the balance of chemical elements required for biological
processes, such as the ratios of carbon, nitrogen, and phosphorus in organisms.
The concept of stoichiometric constraints is discussed in the context of Earth's carrying
capacity. For example, Binder et al.12 explain that even if there is sufficient energy
(calories) available to support a large human population, limitations in the availability
of essential nutrients, particularly phosphorus, could create a binding
stoichiometric constraint on population growth.

The sources also suggest that there are limitations associated with the land sparing vs. land
sharing framework and that understanding scale issues and teleconnections is crucial in
conservation planning. They also highlight the need for more holistic frameworks that
consider social-ecological systems in addressing food security and biodiversity conservation.
Additionally, they discuss the concept of "cultural carrying capacity," which takes into
account not just biological needs but also social and cultural values in determining sustainable
population levels.

Practice sheet 12
 the framwork built on the concept on land sharing and land sparing is in essencse an
economic framework- how do you get enough money kinda?

Beyond "Sparing" vs. "Sharing": A Deeper Look at
Conservation Strategies
The sources frame the debate on balancing food production and biodiversity conservation
around two main strategies: land sparing and land sharing. While these terms provide a
useful starting point, they also acknowledge that this dichotomy is overly simplistic and
advocate for a more nuanced understanding.

Land Sparing:

This strategy focuses on intensifying agricultural production in specific areas,
aiming to maximise yields while minimising land use. This allows for designating
separate areas for conservation, such as protected areas.

From an economic standpoint, land sparing aligns with the principle of efficiency:
allocating land to its most productive use. By concentrating agricultural activities on
land most suitable for high yields, the logic goes, we can produce more food with a
smaller footprint, leaving more land for nature.

However, the sources raise several economic and social critiques of this approach:

Food Security vs. Food Production: Simply producing more food does not
guarantee everyone has access to it. Issues of distribution, affordability, and
power dynamics within food systems are crucial for achieving food security.

Neglecting Food Sovereignty: This concept emphasizes local control over food
systems, allowing communities to define their food needs and priorities. Land
sparing, driven by global market forces, can undermine food sovereignty by
prioritising export-oriented crops over local food needs.

Overlooking Ecosystem Services: Focusing solely on agricultural yields
disregards other valuable services provided by ecosystems, such as pollination,
water regulation, and carbon sequestration. These services can be crucial for
both human well-being and agricultural productivity itself.

Ignoring Displacement Effects: Intensification in one area can lead to the
displacement of agricultural activities to other, often more ecologically sensitive
regions. This phenomenon, known as leakage, can result in deforestation and
biodiversity loss elsewhere.

Land Sharing:

Practice sheet 13
 This approach advocates for integrating conservation and production within the
same landscape. This often involves promoting wildlife-friendly farming
practices, such as agroforestry, organic farming, and habitat heterogeneity.

Land sharing resonates with a more holistic perspective on sustainability,
recognizing that agricultural landscapes can support biodiversity.

However, the effectiveness of land sharing for conservation depends on several
factors:

Species-Specific Outcomes: While some studies show increased species
richness in certain agroforestry systems compared to forests, others suggest a
decline in specialist or rare species. The conservation value of land sharing
varies depending on which species are prioritized and the specific management
practices implemented.

Management Intensity: Less intensive systems with higher canopy cover and
native tree diversity tend to support more biodiversity than intensively managed
monocultures.

Landscape Context: The effectiveness of land sharing also depends on the
surrounding landscape context. Small, isolated patches of habitat within a
heavily modified matrix might not provide sufficient connectivity or resources
for many species.

Economic Considerations:

Market Mechanisms: The success of both land sparing and land sharing depends on
aligning economic incentives with conservation goals. This could involve payments for
ecosystem services, certification schemes for sustainable products, or market premiums
for biodiversity-friendly goods.

Valuing Ecosystem Services: Incorporating the economic value of ecosystem services
into decision-making processes can help justify investments in conservation and
sustainable practices. This requires developing methods for quantifying and valuing these
services, which can be challenging.

Equity and Social Justice: Conservation strategies should address issues of equity and
social justice. Who benefits from land sparing or land sharing? How do these strategies
impact the livelihoods and well-being of local communities? These questions are crucial
for ensuring equitable outcomes.

Moving Forward:

Practice sheet 14
 The sources emphasize the need to move beyond the binary of "sparing" vs. "sharing" and
embrace a more integrated approach to conservation and production:

Context Specificity: There is no one-size-fits-all solution. Conservation strategies must
be tailored to the specific ecological, social, and economic context.

Multiple Scales and Connections: Conservation planning should account for global
market forces, teleconnections, and the interconnectedness of landscapes.

Holistic Frameworks: We need analytical approaches that consider the complex
interplay of ecological, economic, and social factors within social-ecological systems.

Open Dialogue and Value Articulation: Honest discussions about trade-offs, societal
values, and different perspectives on the human-nature relationship are crucial for
navigating these complex challenges.

The sources highlight the importance of ongoing research, innovation, and collaboration to
develop and implement sustainable and equitable land management practices that balance the
needs of both people and nature.

3. Contested farming styles
texts:

“Contested farming styles” - Giller ✅
This academic paper focuses on regenerative agriculture, examining its origins,
definitions, and potential to address soil and biodiversity crises. The authors note that
regenerative agriculture is a relatively new term, gaining popularity in the 1980s with the
work of the Rodale Institute. However, it remains poorly defined and is often conflated
with other alternative agricultural approaches.

The paper identifies soil health and reversal of biodiversity loss as the two major
challenges regenerative agriculture seeks to address. The authors then discuss various
practices associated with regenerative agriculture, such as minimizing tillage,
maintaining soil cover, building soil carbon, agroforestry, relying on biological nutrient
cycles, fostering plant diversity, integrating livestock, and avoiding pesticides.
While acknowledging the potential benefits of these practices, the authors also emphasize
the need to carefully consider their effectiveness in different contexts. They argue that a
universalist approach to "fixing" agriculture may not be appropriate due to the
complexity of local realities.

Practice sheet 15
 The authors conclude by urging research agronomists to critically evaluate the claims of
regenerative agriculture and engage constructively with its proponents. They suggest
focusing on five key questions:

1. What is the specific problem that Regenerative Agriculture seeks to address in a
given context?

2. To what extent are these problems real, and how are they framed?

3. To what extent do the specific regenerative practices address these problems?

4. Are the purported benefits of Regenerative Agriculture demonstrably greater than
those offered by other types of agriculture?

5. Are there any unintended negative consequences associated with these practices?

intressante sitat
Robert Rodale (1983) defined Regenerative Agriculture as ‘one that, at increasing
levels of productivity, increases our land and soil biological production base. It has
a high level of built-in economic and biological stability. It has minimal to no
impact on the environment beyond the farm or field boundaries. It produces
foodstuffs free from bio- cides. It provides for the productive contribution of
increas- ingly large numbers of people during a transition to minimal reliance on
non-renewable resources’

Agriculture from an agronomic perspective. By this we mean a perspective steeped
in the use of plant, soil, ecological and system sciences to support the production of
food, feed and fibre in a sustainable manner. Specifically, we address two
questions: 1) What is the agronomic problem analysis that motivates the
Regenerative Agriculture movement and what is the evidence base for this analysis?
2) What agro- nomic solutions are proposed, and how well are these sup- ported by
evidence?

Harwood summarizes the ‘Regenerative Agriculture Philosophy’ in 10 points (Box
1). He further states that this philosophy emphasizes: ‘1) the inter-relatedness of all
parts of a farming system, including the farmer and his family; 2) the importance of
the innumerable biological balances in the system; and 3) the need to maximise
desired biological relationships in the system, and minimise use of materials and
practices which disrupt those relationships’.

1. Agriculture should produce highly nutritional food, free from biocides, at high
yields.

Practice sheet 16
 2.. Agriculture should increase rather than decrease soil productivity, by
increasing the depth, fertility and physical characteristics of the upper soil
layers.

3.. Nutrient-flow systems which fully integrate soil flora and fauna into the
pattern of are more effi- cient and less destructive of the environment, and
ensure better crop nutrition. Such systems accom- plish a new upward flow of
nutrients in the soil profile, reducing or eliminating adverse environ- mental
impact. Such a process is, by definition, a soil genesis process.

4.. Crop production should be based on biological interactions for stability,
eliminating the need for synthetic biocides. 5.

5. Substances which disrupt biological structuring of the farming system (such as
present-day synthetic fertilizers) should not be used.

6. 6. Regenerative agriculture requires, in its biological structuring, an intimate
relationship between man- ager/participants of the system and the system
itself.

7. 7. Integrated systems which are largely self-reliant in nitrogen through
biological nitrogen fixation should be utilized.

8. 8. Animals in agriculture should be fed and housed in such a manner as to
preclude the use of hormones and the prophylactic use of antibiotics which are
then present in human food.

9. 9. Agricultural production should generate increased levels of employment.

10. 10. A Regenerative Agriculture requires national-level planning but a high
degree of local and regional self-reliance to close nutrient-flow loops.

To date the discussion around Regenerative Agriculture has taken little account of
the wide variety of initial starting points defined by the variation in local contexts
and farming systems and the scales at which they operate. For example, the
problems caused by over-use of fertilizer or manure in parts of North America,
Europe and China may well allow for reductions in input use and result in
significant environ- mental benefits, without necessarily compromising crop yields
or farmer incomes. In contrast, in many developing countries, and especially in
Africa, crop productivity, and thus the food security and/or incomes of farming
households, is tightly constrained by nutrient availability (i.e. because of highly
weathered soils, and the limited availability of fertili- zer, manure and compostable
organic matter) (e.g. Rufino et al., 2011). Under such circumstances continued
cultivation inevitably leads to soil degradation, and the use of external inputs,

Practice sheet 17
 including fertilizer, is essential to increase crop yields, sustain soils and build soil C
(Vanlauwe et al., 2014, 2015)

“How sustainable is sustainable intensification?” - Joao ˜ Vasco Silva ✅
This academic paper examines the concept of sustainable intensification in the context
of achieving food security and reducing the environmental impacts of agriculture. The
paper analyses three contrasting farming systems—mixed crop-livestock systems in
southern Ethiopia, specialized rice-based farming systems in Central Luzon
(Philippines), and arable farming systems in the Netherlands—to evaluate the
environmental and socio-economic sustainability of sustainable intensification at the
farm level.
The study found significant potential for future intensification of cereal production in
southern Ethiopia. However, the current input use in these farming systems is deemed
not economically and environmentally sustainable at the farm level. Similarly, in
Central Luzon, while sustainable intensification can potentially narrow yield gaps and
improve nitrogen use efficiency, profitability remains a challenge due to the reliance on
costly hired labor. In contrast, arable farms in the Netherlands exhibit high economic
performance and nitrogen use efficiency, but require further improvements in
resource-use efficiency to enhance environmental sustainability.

The paper highlights the importance of public investments in promoting innovation and
making sustainable intensification technologies accessible and affordable to farmers.
These investments are deemed crucial in ensuring that yield gaps can be narrowed
while simultaneously meeting sustainability objectives at the farm level.

intressante quotes
Yield gaps are defined as the difference between the potential (Yp) or the water-
limited yield (Yw) and the actual yield (Ya) observed in farmers’ fields under
irrigated or rainfed conditions, respectively (van Ittersum et al., 2013).
Decomposing yield gaps into efficiency, resource and technology yield gaps is
helpful to identify the management drivers of existing yield gaps (Silva et al.,
2017b). The efficiency yield gap is defined as the difference between the technically
efficient yield (YTEx, the maximum yield that can be achieved for a given input

Practice sheet 18
 level) and Ya and captures the contribution of sub-optimal time, form and/or space
of crop management practices. The resource yield gap is defined as the difference
between the highest farmers’ yield (YHF) and YTEx and it is attributed to a sub-
optimal amount of inputs applied. Finally, the technology yield gap is defined as
the difference between Yp or Yw and YHF and it can be attributed to the use of
inferior technologies (e.g., varieties or balanced nutrition) in farmers’ fields than
those needed to reach Yp or Yw.

Sustainable intensification involves trade-offs between ‘sustainabil­ ity’ and
‘intensification’ (Struik et al., 2014). Such trade-offs are likely to occur at the farm
level given resource constraints and the timing of activities; some objectives are
then prioritized over others. Few studies have paid attention to this in the past.
Hence it remains unclear how sustainable intensification of crops (at field level)
works out at farm level, given constraints of land, labour and capital availability
and farmers’ decisions on resource allocation coupled with their prioritiza­ tion of
crop management activities. Farmers’ decisions can be classified as strategic,
tactical and operational in terms of long, intermediate and immediate time scales
(de Koeijer et al., 1999). Their decisions deter­ mine actual resource-use efficiencies
and the extent to which growth-defining, -limiting and -reducing factors are
optimised for a specific crop in the biophysical environment of the farm (Giller et
al., 2011). In turn, management decisions are strongly conditional on the socio-
economic environment of the farm and the farmers’ personal priorities.

“Divergent understandings of agroecology in the era of the African Green Revolution” -
Imogen Bellwood-Howard ✅
Understandings of agroecology within mainstream development and how these relate to
different agricultural development narratives. Using a "knowledge politics" approach, the
authors identify five understandings of agroecology:

1. No knowledge of agroecology: This pertains to individuals or institutions unfamiliar
with the concept.

2. Descriptive science: Agroecology as the scientific study of interactions between
livestock, crops, and the environment.

3. Science for sustainability: Agroecology as a science geared towards designing
sustainable agricultural systems, encompassing socio-economic and environmental
considerations.

Practice sheet 19
 4. Environmentally sustainable farming practices: Agroecology as a set of practices
aimed at minimizing external inputs and promoting environmental sustainability.

5. Political agroecology: Agroecology as a movement advocating for human and
environmental well-being, food sovereignty, and social justice.

The paper further identifies four agricultural development "regimes," each associated
with specific understandings of agroecology:

1. African Green Revolution: Focused on increasing agricultural productivity through
modern technologies and inputs.

2. 21st-Century Agroecology: Promoting a transition towards agroecological food
systems based on principles of ecological sustainability, social justice, and food
sovereignty.

3. Large-scale agriculture: Emphasizing large-scale agricultural production, often for
export markets.

4. Smallholder agriculture: Characterized by small, diverse, low-input, low-output
farms, primarily focused on subsistence farming.

The authors argue that proponents of these different regimes often emphasize the
distinctions between their favored understandings of agroecology, while neglecting to
acknowledge the historical evolution and diverse framing of agroecological science.32
This tendency obscures the political nature of scientific knowledge construction and how
different interpretations of agroecology can support contrasting development paradigms.

intressante sitat
Many contemporary agroecological publications consider social or political science
concerns such as food sover- eignty, community empowerment and environmental
jus- tice (e.g. de Molina, 2013), rather than interactions between crops, livestock
and their physical environment

Especially since the 1990s, varied understandings of agroe- cology have interacted
with proposed regimes of agricul- tural development. Recognition of either a more
political or a more technical understanding can be one factor contribut- ing to
dominance of a given development paradigm. As different development trajectories
can have far-reaching economic, environmental and cultural implications, the
definition of agroecology is more than just an academic preoccupation. Although
different actors may not recog- nize the discursive power exercised by promoting
various definitions, groups with different perspectives on agroecol- ogy have

Practice sheet 20
 occasionally done discursive work on the term’s definition. An absence of such
debate in some contexts also has a bearing, albeit likely unintentional, on the
trajectory of agricultural development.

Both paradigms also have a common root in agroecolo- gical science. Thus, Altieri’s
(1995) book, published as the political understanding of agroecology was taking
shape, is called ‘Agroecology: The Science of Sustainable Agricul- ture’. The 21st-
century agroecology regime in particular relies on the definition of agroecology as a
science being used alongside the political agroecology definition. With- out this,
there is no basis for claiming that certain practices are environmentally desirable,
and therefore that political and economic systems should be managed to maintain
them. Simultaneously, Conway’s (1997) book, the ‘Doubly Green Revolution: Food
for all in the 21st Century’, which can be seen as a precursor to the AGR, draws on
a deep understanding of the ecology of agricultural systems to advocate extensive
use of advanced technologies to pro- mote food security

The least political approach takes it for granted that the attainment of yield is the
primary objective of agriculture and agronomy, so agroecological science is
understood as mobilizing the understanding of ecological processes towards that
end. Simultaneously, since its earli- est mention, there has been a perspective that
agroecology is about using ecological understanding to ensure agricul- ture is
environmentally and socially ‘harmonious’: Hanson (1939, p.113) proposed ‘the
need for natural areas as checks, or standards, by which the values and effects of
tillage, irrigation, drainage, grazing, lumbering, and other uses may be measured’.
Much later, Gliessman (2015) pre- sented the same ecological processes and
ecosystem com- ponents in such a way as to explicitly promote a specific vision of
sustainable agricultural development

Navigating the Complexities of Sustainable Agriculture: A
Synthesis of Key Concepts
The sources explore different farming styles and approaches aimed at achieving sustainable
food production amidst a growing global population. They highlight the complexities and
challenges inherent in balancing productivity, environmental sustainability, and social equity.
A core theme that runs throughout the sources is that no single solution fits all contexts;
local realities must be carefully considered when evaluating the applicability and

Practice sheet 21
 effectiveness of different agricultural practices. Let's examine some of the key concepts
discussed:

Sustainable Intensification:

This concept emphasises increasing agricultural output on existing farmland while
minimising environmental impact. It involves closing yield gaps, which are the
differences between potential and actual crop yields. Sustainable intensification seeks to
achieve "more output with less input". However, this is often easier said than done, as
illustrated by the case studies presented by Silva et al. In southern Ethiopia, for example,
intensification is needed to improve food security, but current practices are not
economically or environmentally sustainable. This highlights the need to tailor
intensification strategies to local conditions and consider social and economic factors
alongside environmental concerns.

Regenerative Agriculture:

This relatively new concept focuses on restoring and enhancing natural systems
within agricultural landscapes. It emphasizes soil health, biodiversity conservation, and
carbon sequestration as key outcomes. Proponents of regenerative agriculture advocate
for practices such as minimizing tillage, maintaining soil cover, and integrating livestock
to improve soil fertility and biodiversity. However, Giller et al. caution against a
universalist approach to regenerative agriculture, arguing that the effectiveness of
specific practices can vary significantly depending on the local context. They urge
researchers to critically evaluate the claims of regenerative agriculture and consider
potential unintended consequences.

Agroecology:
This concept is particularly contested due to its various interpretations and the political
dimensions associated with it. It encompasses a range of perspectives, from a purely
scientific approach to a political movement advocating for social justice and food
sovereignty. Bellwood-Howard and Ripoll identify five distinct understandings of
agroecology: descriptive science, science for sustainability, environmentally sustainable
farming practices, political agroecology, and a lack of awareness of the concept
altogether. These diverse interpretations often lead to confusion and disagreement over
what constitutes "true" agroecology. The authors argue that acknowledging the historical
evolution of agroecology and understanding the different ways it has been framed can
help clarify these debates.

The sources also touch upon other important aspects of sustainable agriculture, such as:

Yield Gaps and Their Drivers:

Practice sheet 22
 The concept of yield gaps is central to understanding the potential for sustainable
intensification. Yield gaps can be decomposed into efficiency, resource, and technology
gaps, helping to identify the specific factors limiting agricultural productivity. These
factors can include sub-optimal management practices, insufficient input use, and the
adoption of inferior technologies.

Farm Size and Labour Use:

The scale of agricultural operations and the availability of labor are crucial factors
influencing sustainable intensification strategies. The Silva et al. study highlights the
contrasts between smallholder farming systems in Ethiopia and the Philippines, where
labor is abundant and capital is scarce, and large-scale farming systems in the
Netherlands, characterized by high levels of mechanisation and capital investment.

Economic and Social Sustainability:

Sustainable agriculture requires considering not only environmental impacts but also
economic viability and social equity. Ensuring that farmers can make a living from
sustainable practices is crucial for their adoption and long-term success. This may
involve supporting innovation, making technologies accessible and affordable, and
promoting fair market access for smallholder farmers.

In summary, the sources paint a complex picture of the challenges and opportunities
associated with sustainable agriculture. They emphasize the need for context-specific
solutions, critical evaluation of different approaches, and consideration of both
environmental and socio-economic factors. The sources provide a valuable framework for
understanding the key concepts and debates surrounding sustainable food production and
offer insights that can inform the development of more effective and equitable agricultural
practices.

Terminologies and Definitions
Agroecology: A multifaceted concept with various interpretations, encompassing
scientific study, social movement, and farming practices. It can be understood as:

Descriptive science: Studying ecological interactions within agricultural systems.

Science for sustainability: Applying ecological knowledge to design sustainable
agricultural systems, often considering socio-political aspects like food sovereignty
and environmental justice.

Environmentally sustainable farming practices: Low-external-input practices
promoting environmental sustainability, like composting, intercropping, and crop

Practice sheet 23
 rotations.

Political agroecology: Advocating for food sovereignty, social justice, and
transformative change in food systems.

Agronomic practices: Specific methods and techniques used in agricultural production.
The sources discuss various practices associated with regenerative agriculture, including:

Zero tillage/Reduced tillage/Conservation agriculture: Minimizing soil
disturbance to preserve soil structure and organic matter.

Cover cropping: Growing non-cash crops to protect and improve soil health.

Mulching: Applying organic or inorganic materials to the soil surface for moisture
retention, weed suppression, and temperature regulation.

Biochar: Charred organic matter added to soil to improve fertility and carbon
sequestration.

Compost/Green manures/Animal manures: Organic amendments to enhance soil
fertility and nutrient cycling.

Agroforestry/Silvopasture/Tree crops: Integrating trees into agricultural systems
for various benefits, including carbon sequestration and biodiversity enhancement.

Permaculture: A design system aiming to create sustainable human settlements by
mimicking natural ecosystems.

Biodiversity:
The variety of life in a particular habitat or ecosystem. Regenerative agriculture often
claims to reverse biodiversity loss.

Efficiency yield gap:

The difference between the technically efficient yield (achievable with optimal
management for given inputs) and the actual yield, reflecting sub-optimal timing, form,
or placement of crop management practices.

Good Agricultural Practices:
Established guidelines for environmentally and socially responsible farming,
encompassing various practices.

Green Revolution:

A period of significant agricultural productivity increases in the mid-20th century, driven
by technological advancements like high-yielding varieties and synthetic fertilizers.

Practice sheet 24
 African Green Revolution: Similar aims to the Green Revolution, but focused
on increasing agricultural productivity in Africa.

Integrated Pest Management (IPM):
An ecosystem-based strategy emphasizing pest prevention and minimizing pesticide use
through various methods.

Nitrogen surplus:
The excess nitrogen input into agricultural systems beyond what crops can uptake,
potentially leading to environmental pollution.

Nitrogen use efficiency (NUE):
A measure of how effectively plants utilize nitrogen fertilizer.

Organic agriculture:
A farming system emphasizing ecological principles and minimizing synthetic inputs.

Regenerative agriculture:
An approach aiming to regenerate and enhance agricultural ecosystems, often focusing
on soil health, biodiversity, and ecosystem services.

Regenerative organic agriculture: A subset of regenerative agriculture that
adheres to organic farming principles.

Resource yield gap:
The difference between the highest farmer's yield (achievable with best practices and
available resources) and the technically efficient yield, indicating limitations from
insufficient inputs.

Soil health:

A complex concept often lacking precise definition, referring to the capacity of soil to
function as a living ecosystem supporting plant growth and other ecosystem services.

Sustainable intensification:
Increasing agricultural productivity while minimizing environmental impact and
promoting social equity.

Technology yield gap:

The difference between the potential yield (achievable with optimal conditions and
technologies) and the highest farmer's yield, indicating limitations from using inferior
technologies.

Practice sheet 25
 Yield gap:
The difference between the potential yield (or water-limited yield in rainfed conditions)
and the actual yield achieved by farmers, indicating the potential for improvement.

Yield gap decomposition:

Analyzing the yield gap by breaking it down into different components, such as
efficiency, resource, and technology yield gaps.

4. Resilience and Food Systems
texts:

Food System Resilience: Concepts, Issues, and Challenges ✅
intressante sitater

We present four questions to frame food system resilience (Resilience of what?
Resilience to what? Resilience from whose perspective? Resilience for how long?)
and three approaches to enhancing resilience (robustness, recovery, and
reorientation—the three “Rs”)

Shocks are abrupt events of differing probability of occurrence and severity of
impact, and may even be wholly unimagined: a surprise (32). Analysis of a half-
century of drivers of shocks for both land- and marine-based food systems around
the world identified extreme weather events, geopo- litical events, financial market
crashes, and short-term cost spiraling of fertilizer and other inputs, disease
outbreaks, and conflict as major shocks (33), often compounded by policy change
and mis- management. Food safety scares can also significantly “shock” the system
(34). The impacts of a combination of shocks, such as extreme weather and disease
outbreak, can be particularly signifi- cant, as exemplified in the sidebar titled
Interacting Shocks to Banana Production in Colombia

Compared with shocks, food system stresses are longer-term drivers or conditions
that are more easily perceived. Examples of stresses include gradual changes in
landscape-level land use and agrochemical use, dietary shifts, climate change,
demographic change, regulatory alterations, trends in commodity prices, and
functional biodiversity loss (35–39).

Practice sheet 26
 Fan et al. (30) refer to risks as decision-making situations in which the likelihoods
of potential outcomes are known to the decision-maker (whereas in uncertain
situations, they are not). Risks can vary in detectability, the likelihood of an adverse
current or future occurrence, and the severity of their impact (49). They can be
examined through, for example, foresight and scenario analysis (48). However, risk
percep- tion is often heavily dependent on contextual factors (50). Hazards that
provoke a particular sense of dread, are unfairly distributed, or are unmitigable may
prompt heightened risk perceptions (50, 51). Social processes may amplify risk
perception through media (52), which can produce a knock-on effect, such as the
panic buying witnessed during the COVID-19 pandemic (53, 54)

Holling (59) coined the now common ecological systems definition of resilience as a
measure of the persistence of systems and their ability to absorb change and
disturbance and still maintain the same relationships between populations or state
variables. This equates to our concept of the functioning of the system. Thresholds
are central to this definition of resilience. Severe perturba- tions can potentially
trigger numerous reactions across spatial or temporal scales that can bring the
system over a threshold, causing it to shift to a new state. Similarly, small shifts in
system func- tioning, which are not visible, can move system functioning toward a
precipice, where additional perturbation creates a systemic change in ecosystem
functioning (60). Resilience recognizes that a system can have multiple stable states
and can maintain function as a result of internal reorga- nization, i.e., its adaptive
capacity (61). Béné et al. (62) suggested three important components to consider:
the abilities of a system (a) to absorb losses due to disturbances, (b) to adapt through
learning and incremental adjustments, or even (c) to transform through radical
changes in the face of stresses and shocks

Helfgott (13) identified four key framing questions (the four “Qs”), answers to
which help to define the boundaries of the systemic resilience sought; they point to
the inclusion, exclusion, and marginalization of certain stakeholders and the issues
that concern them (87).

1. Resilience of what? Is it the soil, the crop, the farm enterprise, the local
market as an in- stitution, food supply, or the food system more generally? We
can consider the food system activities (the functioning), the outcomes of these
activities (the function), or both. Although certain individuals may have a
particular interest in specific activities (e.g., farmers in farm- ing, caterers in
catering), we argue that from a societal-level viewpoint, the interest lies in the
resilience of the overall food system outcomes (Figure 1) rather than in the

Practice sheet 27
 individual activities per se; food security is one of the four highly valued
features in a society (88).

2. Resilience to what? We need to understand the nature of the individual shocks
and stresses that affect the food system and how they may interact to amplify
the overall impact. Re- silience depends largely on the severity and frequency
of the shock or stress to which the system is exposed. The shock or stress can
be external to the food system (e.g., an extreme weather event or demographic
change) or internal (e.g., a food safety outbreak or dietary change).

3. Resilience from whose perspective? Is it from the perspective of a given actor
in the sys- tem (e.g., a farmer or a retailer) or from that of a policymaker, or
company CEO, or society at large? We need to know which features of the
system need to be preserved, which can change, and what constitutes desirable
change (improvement) for whom, and from whose perspective. This question is
important for understanding power, justice, and equity, as well as trade-offs
between food system outcomes, relative to different system actors.

4. For what time period do we need to build resilience? It is important to
distinguish short-term interruptions due to shocks (e.g., bad weather or an IT
malfunction interrupting just-in-time fresh grocery deliveries) from disruptions
due to stresses that affect the longer term (e.g., changing dietary preferences,
shifting cropping regions). It is also important to understand the interactions
between the two and the notion of temporal mismatches (89). In the context of
dynamically shifting risk environments, strategies to enhance resilience over a
shorter timescale may deplete resilience over the longer term, necessitating
specification of the time frame over which resilience is being considered (90).
Resilience-building measures need to account for temporal dimensions

Practice sheet 28
 This article, authored by Martin Zurek and colleagues, explores the multidimensional
nature of food system resilience, drawing on concepts from both food system studies
and resilience research.

Food Systems as Social-Ecological Systems: The authors emphasize the
understanding of food systems as complex social-ecological systems (SES) that
operate across multiple scales—spatial, temporal, and jurisdictional. These systems
involve various actors driven by diverse forces, resulting in a range of outcomes,
including food security, environmental impacts, and socio-economic effects.

Shocks and Stresses: The article distinguishes between shocks, which are sudden,
disruptive events (e.g., extreme weather, pandemics), and stresses, which are longer-
term, gradual pressures (e.g., climate change, demographic shifts). Both shocks and
stresses can significantly affect food system outcomes and require different
resilience-building approaches.

Framing Resilience: The authors identify four key questions (referred to as the four
"Qs") that are essential for framing food system resilience. These questions help
define the boundaries of the system and guide the development of appropriate
strategies:

Resilience of what? (the activities/functions, outcomes/functions, or both?)

Resilience to what? (specific shocks and stresses)

Resilience from whose perspective? (farmers, policymakers, society, etc.?)

Resilience for how long? (short-term, long-term)

The Three "Rs" of Resilience: The article proposes three main approaches to
enhancing food system resilience:

Robustness: This involves maintaining the status quo of desired food system
outcomes by preventing shocks and stresses from disrupting them. It often
focuses on absorbing the impacts of disruptions and requires adapting activities
to withstand them. For example, a retailer may adapt their supply chain to
maintain stock even if one source is disrupted.

Recovery: This approach focuses on returning the system to its original state
after being disrupted. It emphasizes bouncing back from shocks and stresses and
requires adapting activities to facilitate recovery. For example, a farmer might
implement better seed storage to recover from a poor harvest.

Practice sheet 29
 Reorientation: This involves rejecting the status quo and accepting
alternative food system outcomes, potentially before or after a disruption occurs.
It requires adapting activities to achieve the desired transformed outcomes. For
instance, this could involve shifting to more sustainable farming practices or
promoting local food production.

The authors acknowledge that operationalizing these strategies involves normative
choices and negotiating trade-offs between different food system actors and their
desired outcomes.

Adaptation and Transformation: The article differentiates between adaptation as
changing food system activities and transformation as changing food system
outcomes. It argues that transforming an outcome from state A to state B requires
actors to adapt their activities, highlighting the need for changing drivers like
policies and economic incentives to stimulate those adaptations.

Assessing Resilience: The authors highlight the challenges in assessing food system
resilience, noting that most efforts have focused on specific contexts, like
development or food security, with limited consideration of broader components
and objectives. They call for the development of more comprehensive metrics and
indexes to accurately assess resilience across multiple dimensions.

Questions and Issues: The article concludes by raising several questions and issues
that need further exploration:

To what degree is food system resilience an emergent property influenced by the
shape and structure of the system?

How do we balance the resilience of individual actors with the resilience of the
system as a whole?

How do we assess food system resilience effectively, considering the
complexity of relationships between multiple variables?

How do we manage potential trade-offs between resilience and sustainability
aims?

Addressing these questions is crucial for developing more resilient food systems that
can withstand future shocks and stresses.

An Indicator Framework for Assessing Agroecosystem Resilience ✅
intressante sitater

Essentially, resilience is measured in three ways: (1) the amount of change the
system can undergo and still retain the same controls on function and structure; (2)

Practice sheet 30
 the degree to which the system is capable of self- organization; and (3) the ability to
build and increase the capacity for learning and adaptation

We use intentionality to bound the agroecosystem (Bland and Bell 2007); as such,
the agroecosystem can be defined as an ecosystem managed with the intention of
producing, distributing, and consuming food, fuel, and fiber. Its boundaries
encompass the physical space dedicated to production, as well as the resources,
infrastructure, markets, institutions, and people that are dedicated to bringing food
to the plate, fiber to the factory, and fuel to the hearth. The agroecosystem operates
simultaneously at multiple nested scales and hierarchies, from the field to the globe.
Here, we are concerned with a scale greater than the individual farmer and his or her
farm, but a scale small enough that an individual’s voice can still make a difference.
This is because no farmer operates in a vacuum, and the decisions he or she makes
are based in large part on outside influences (Darnhofer et al. 2010b). However,
those outside influences should still be subject to feedback from those who are
affected by them.

This article, written by Joshua F. Cabell and Myles Oelofse, focuses on applying
resilience theory to agroecosystems, which are ecosystems managed for food, fuel, and
fibre production. The authors acknowledge the complexity of these systems and argue
that resilience cannot be directly measured. Instead, they advocate for using behaviour-
based indicators to assess resilience, drawing on the concept of biotic indicators used
in ecosystem monitoring.

Challenges in Measuring Resilience: Cabell and Oelofse agree with Darnhofer et
al. (2010a) that the complexity and variability of agroecosystems make precise
measurement of resilience impractical. They highlight the challenges in defining the
“resilience of what to what” due to the nested nature of these systems.

Behavior-Based Indicators: Instead of direct measurement, the authors propose
using a set of behaviour-based indicators, which are observable characteristics that
suggest resilience when present. They compiled 13 such indicators from resilience
literature, including:

Socially self-organized: This refers to communities having the capacity to
manage their own resources and adapt to change without excessive external
control.

Practice sheet 31
 Ecologically self-regulated: This indicates that the agroecosystem can regulate
essential processes, like nutrient cycling and pest control, with minimal human
intervention.

Appropriately connected: This highlights the importance of diverse and
flexible relationships between different components of the system, as opposed to
rigid dependencies.

High degree of functional and response diversity: This includes having a
variety of species and farming practices that contribute different functions and
respond differently to disturbances, increasing the system’s adaptability.

Optimally redundant: This refers to having “backups” or alternative options
within the system to compensate for potential failures. While redundancy may
reduce efficiency, it can be crucial for resilience during shocks and stresses.

Spatial and temporal heterogeneity: This relates to the diversity of landscape
features and farming practices across space and time, contributing to greater
ecological and social resilience.

Manages slow variables and feedbacks: This emphasizes the importance of
managing key processes that change slowly over time, such as soil health, water
cycles, and biodiversity.

Responsibly coupled with local natural capital: This indicator suggests that
the agroecosystem operates within the limits of its local resource base and
minimizes reliance on external inputs.

Reflective and shared learning: This highlights the importance of learning
from past experiences and sharing knowledge within the community to enhance
adaptive capacity.

Embraces innovation: This refers to the willingness to adopt new technologies
and practices that can contribute to resilience, while also considering their
potential risks.

Maintains human capital: This involves investing in the skills, knowledge,
and well-being of the people involved in the agroecosystem.

Adequate financial capital: This emphasizes the importance of having access
to financial resources to invest in resilience-building measures and cope with
unexpected events.

Polycentric governance: This suggests a system of governance where multiple
actors and institutions share power and responsibility, contributing to greater

Practice sheet 32
 flexibility and responsiveness.

The presence of these indicators can help identify resilient agroecosystems, while their
absence reveals vulnerabilities that require attention. This approach provides a practical
framework for assessing and enhancing the resilience of farming and food systems to
ensure long-term sustainability.

Do you bend or break? System dynamics in resilience planning for food security -
Hugo Jose Herrera de Leon* and Birgit Kopainsky ✅
intressante quotes

Food systems are a particular type of social–ecological system (SES) man- aged
with the primary purpose of producing food and, more specifically, of providing
food security to their stakeholders (Ericksen, 2008a). FAO (2002, p. 50) defines
food security as follows: “all people, at all times, have physical and economic
access to sufficient, safe and nutritious food to meet their die- tary needs and food
preferences for an active and healthy life”

In their 2018 report, the Food and Agriculture Organization of the United Nations
(FAO, 2018, p. 1) reported, for example, that “70–80 percent of severely food
insecure people worldwide rely on agriculture-based livelihoods”. All these
households are on the verge of disaster as climate becomes unpredictable and
extreme events such as floods and droughts are more common

Resilience, at a basic level, can be understood as the ability of a system to cope
with, and adapt to, changes (Holling, 1996; Folke, 2006; Marshall and Marshall,
2007). Resilience is used in both theoretical and practical settings as a means to
characterise systems but also as a framework to improve its adaptive capacity
(Folke et al., 2004; Walker et al., 2006). In this paper we focus on the latter, and
particularly on the way resilience is applied as a framework to study how systems
can withstand bigger and/or more frequent changes. We look at resilience as an
outcome of the planning and risk man- agement processes (Berkes and Folke, 1998;
Chapin et al., 2009) and empha- sise those attributes that can help a system to live
with, learn from and adapt to change

In the past, case study research has been used to identify system attributes and
characteristics that contribute to resilience. By studying systems that have been
identified as resilient, researchers have proposed that attributes such as redundancy,
connectivity or polycentrism contribute to enhance systems’ resilience.

Practice sheet 33
 “Hardness” indicates the threshold between stability and adaptation, i.e. the degree
of disturbance needed to perturb the outcome’s stability (see Figure 2). Similarly,
the measure “elasticity” indicates the threshold between adaptation and
transformation, and the “index of resil- ience” indicates the probability of reaching
this threshold (see Figure 2).

Practice sheet 34
 summary

This article, written by Hugo Jose Herrera de Leon and Birgit Kopainsky, explores the
use of system dynamics in creating resilience plans for food security in Guatemalan
communities facing climate pressures. The authors criticize the traditional deductive
approach to resilience planning, which relies on broadly accepted factors like
redundancy, connectivity, and polycentrism. They argue that this approach is often too
simplistic and advocate for a more nuanced understanding of the structure-behaviour
relationship in complex dynamic systems.

What is Resilience? The authors define resilience as a system's ability to cope with
and adapt to change. They emphasize the importance of planning and risk
management in achieving resilience.

System Dynamics in Resilience Planning: The paper advocates for using system
dynamics (SD) to explore the complex mechanisms behind resilience. They
highlight the success of SD in areas like water management and CO2 emissions
reduction. SD focuses on how stocks, flows, and feedback structures influence a
system’s behaviour, which makes it particularly well-suited for resilience planning.

Case Study in Guatemala: The authors used SD to study resilience planning for
food security in subsistence food systems in Guatemala. They focused on two
districts, Huehuetenango and Jutiapa, and developed a general model to
understand the behaviour and processes of maize-dominated agriculture systems.
The model was based on publicly available data and validated through continuous
engagement with stakeholders.

Feedback Loops and Policies: The model identified key feedback loops
influencing food security resilience, including:

Commercial agriculture: Increased maize revenue allows for more spending
on farming, leading to better yields and further revenue increases.

Poverty trap: Dedicating a larger proportion of maize to self-consumption
reduces sales and may lead to a cycle of lower revenues.

Market’s invisible hand: High production reduces demand and lowers prices,
while low production increases demand and raises prices.

The study also tested the resilience of food consumption to drought intensification,
using historical data and simulating various drought scenarios. The authors facilitated
discussions with stakeholders to propose policies for enhancing resilience, including

Practice sheet 35
 promoting home gardens, increasing poultry farming, improving market
infrastructure, and supporting irrigation systems. Policy 2, increasing poultry
farming, was found to be most effective in increasing system elasticity, particularly in
Huehuetenango. The authors stress that resilience planning requires understanding the
dynamic complexity of the systems involved and that policy recommendations should
vary from case to case.

Briefing Doc: Food System Resilience
This document provides an overview of food system resilience, drawing on three key sources.
It explores the concept of resilience, its application to food systems, frameworks for
understanding and enhancing resilience, and the challenges in assessing it.
What is Resilience?
Resilience is broadly defined as the ability of a system to cope with and adapt to change. This
concept is particularly relevant for food systems, which face various shocks and stresses, such
as climate change, extreme weather events, economic fluctuations, and pandemics.

Food Systems as Complex Adaptive Systems
Food systems are viewed as complex adaptive systems, operating across multiple scales and
involving various actors, activities, and outcomes. These systems are characterized by:

Interconnectedness: Different components of the food system, such as production,
processing, distribution, and consumption, are interconnected and influence each other.

Feedback loops: Actions within the food system can create feedback loops that either
reinforce or dampen change.

Non-linearity: The relationships between different components are often non-linear,
meaning small changes can lead to significant and unpredictable outcomes.

Framing Food System Resilience
Before discussing resilience strategies, it's crucial to establish a clear understanding of what
we want to make more resilient and to what threats. This involves answering four key
questions (the four "Qs"):

1. Resilience of what? Are we aiming for the resilience of:

Specific activities or functions within the food system (e.g., farming prac