Masocha et al. Agriculture & Food Security           (2024) 13:51  
https://doi.org/10.1186/s40066-024-00506-z

REVIEW

Systematic review of government strategies 
for sustainable crop production in Botswana: 
navigating climate change challenges
Boitshwarelo Lorato Masocha1*, Paidamwoyo Mhangara1, Botlhe Matlhodi2, Daniel Mmereki3 and 
Oagile Dikinya4 

Abstract 

Changing climate patterns are a major contributing factor in the failure of government initiatives and sustainable 
crop production, particularly for subsistence smallholder farming systems in Botswana. These challenges faced 
by small-scale farmers require more than just programs and policy implementation; continuous assessment is essen-
tial to achieve their mandate. Moreover, there is limited research in Botswana to provide an understanding of issues 
related to policy implementation and the progression of crop production after the implementation of these policies. 
Therefore, this systematic review aims to evaluate government-implemented programs and policies for promoting 
sustainable crop production in Botswana, examining their successes, failures and providing recommendations for sus-
tainable crop production. PRISMA guidelines were followed for systematic review via the Google Scholar database, 
and inclusion and exclusion criteria were observed for the eligibility of the assessed articles. The major findings indi-
cate that several programs and national policies for sustainable crop production have been implemented in Botswana 
over the past decades. However, crop production continues to decline despite governmental efforts. The increas-
ing adverse effects of climate change have contributed to the failure of government efforts. To advance sustainable 
crop production and resilience to climate change, the following adaptation approaches are recommended: efficient 
and sustainable use of water resources in agriculture, policy reformation, capacity building, regional collaboration, 
and climate-smart agriculture. Moreover, extensive evaluations are necessary for policies and implemented programs. 
This includes timely adjustments to policies on the basis of feedback from monitoring and evaluating specific, meas-
urable indicators of ongoing policies and programs. Furthermore, engaging relevant stakeholders and local commu-
nity members in the monitoring and evaluation process can enhance the relevance and accuracy of implemented 
government policies or programs.

Keywords Botswana, Climate change, Crop production, Government initiatives, Smallholder farming systems, 
Sustainable

Open Access

© The Author(s) 2024. Open Access  This article is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 
International License, which permits any non-commercial use, sharing, distribution and reproduction in any medium or format, as long 
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otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not 
permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To 
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Agriculture & Food Security

*Correspondence:
Boitshwarelo Lorato Masocha
blmasocha@gmail.com
Full list of author information is available at the end of the article

http://creativecommons.org/licenses/by-nc-nd/4.0/
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Page 2 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

Introduction
The increasing human population along with climate 
change challenges, has confronted agriculture with 
unprecedented challenges [1]. Agriculture plays a signif-
icant role in poverty reduction, with 75% of the world’s 
poor living in rural areas and working in farming [2, 
3]. In recent years, the issues of climate change and its 
impact on food security have been increasingly recog-
nized in different parts of the world, including Africa [4], 
this which is evident from the growing global discourse 
on the linkages between global climate change and food 
security [5]. Hence, there is a need for sustainable agri-
culture. Agricultural sustainability is a multi-dimensional 
issue, in which economic, social and environmental 
aspects must be equally considered. An appropriate tool 
for a multi-dimensional assessment is to develop a suit-
able set of indicators for measuring agricultural sustain-
ability so that the key problems impeding sustainable 
agriculture can be identified [6]. Sustainable agriculture 
emerged as a key solution to address challenges in Afri-
ca’s diverse agricultural landscape [7].

Crop production is clearly critical to human life and is 
closely linked to sustainable development goals (SDGs) 
[8]. According to the United Nations, sustainability ‘…
calls for a decent standard of living for everyone today 
without compromising the needs of future generations’. 
Sustainable crop production refers to agricultural pro-
duction in such a way that it does not impose any harm 
to the environment, biodiversity, or quality of agricultural 
crops [9]. This underscores the need for coordinated 
efforts at the global level to address climate change and 
promote sustainable agriculture. On the basis of this defi-
nition of ‘sustainability’, most of the world’s crop produc-
tion systems cannot be considered sustainable simply as 
a result of the wide range of impacts—both onsite and 
offsite—associated with crop production [10]. Sustain-
able crop production is an important need for food secu-
rity, livelihoods, and economic development worldwide. 
Producing crops sustainably increases the ability of the 
system to maintain stable levels of food production and 
quality for the long term without increasing the demand 
and requirements of agricultural chemical inputs to con-
trol the system [9]. There is a pressing need to redesign 
agriculture to achieve sustainability [1]. In addressing 
sustainable crop production, increased involvement in 
research projects by other disciplines must become rou-
tine [10].

Crop production performance in Botswana
In Botswana, crop production is limited to a small area of 
approximately 2500–3000 square kilometers on the east-
ern and northern margins of the country [11]. A study by 
[12] reported that only 3% of the country’s land is arable, 

particularly in the northeast, where rainfall is highest. 
Although environmental problems were observed as 
early as 1983, the cultivated areas in Botswana were 
330 and 600 ha, greater than those in recent years. The 
decline in agricultural performance in Botswana in the 
last 30 years (1979–2012) has occurred even during the 
implementation of a variety of policy measures as well 
as the introduction of new technologies designed to 
improve that performance [13]. The annual growth rate 
in national output declined from 7.5% from 1980–1990 
to approximately 3.8% in 2015 [14]. The performance of 
the agricultural sector has remained below 5% in recent 
years, which is unsustainable and leads to a decline in 
farm income [14]. Figure  1 shows the decline in crop 
yield based on the area planted and the area harvested for 
the years 2008–2019. The figure clearly shows a decrease 
in production indicators, i.e., the area planted, and the 
area harvested. Compared with the 2017 cropping sea-
son, the 2019 cropping season included 13.2% of the area 
planted. Additionally, the smaller areas harvested indi-
cate poor crop production; according to [15], poor crop 
performance is attributed to poor rainfall recorded dur-
ing the 2018/2019 cropping season.

For the period 1985–2008 agricultural production in 
Botswana was estimated to have declined by 0.14% per 
annum compared with the average growth of 0.92% per 
annum for Sub-Saharan Africa (SSA). Table 1 shows the 
indicators of the traditional sector/ arable farming for the 
years 2017 and 2019 reported by the agricultural statis-
tics Botswana [15]. Table 1 clearly indicates that the area 
of fallow land has increased recently (2019) compared 
with that in the previous year (2017), which may be due 
to inadequate rainfall and severe soil constraints. Moreo-
ver, total land indicators (planted, harvested, etc.) were 
lower for the year 2019. This indicates that the possibility 
of having increased yields in recent years is lower because 
of the already experienced environmental issues, such as 
climate change. Other challenges faced by the agricul-
tural systems in Botswana are presented in Table 2.

Despite all the evidence highlighted above concerning 
the continuous decline in crop yields in Botswana, there 
is limited research [16, 17] and evaluation of Botswana’s 
government initiatives and climate change challenges, 
which play a major role in sustainable crop production. 
[18] examined smallholder farmers’ perceptions of cli-
mate change and variability in semiarid Palapye, eastern 
Botswana and concluded that there is a need to codevelop 
resilient farming systems with farmers and extension 
workers; however, evaluation of the program that follow 
still needs to be addressed. Retrofitting current farming 
systems to be climate resilient was recommended as the 
first step toward climate-proofing smallholder farmers’ 
livelihoods [16]. [19] also reported that climate change 



Page 3 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

is a major challenge for the arable sector despite large 
resource inputs and subsidies; however, the effectiveness 
of these programs has not been explored. [5] differed 
from the findings of [19] who emphasized the need for 
a greater understanding of the political economic con-
straints that influence smallholder farming livelihoods 
and rural food security in Botswana. The findings of [5] 
revealed minimal direct impacts of climate change on 
food security. However, that is not convincing enough, 
as the study was based on surveys and interviews, which 
could be affected by the respondent bias. A survey to pro-
vide an overview of the chances of advancing sustainable 
agriculture in Botswana findings show that only half of 

0

50

100

150

200

250

300

2008 2009 2010 2011 2012 2013 2014 2015 2017 2019

Area Planted ("000 Ha) Area Harvested ('000 Ha)

A
re

a 
('0

00
 H

a)

Year

Fig. 1 Area planted versus area harvested trends from 2008 to 2019.  Source: Modified from Statistics Botswana Annual Agricultural Survey Report 
2019 [15]

Table 1 Indicators of the traditional sector in Botswana for the 
years 2017–2019

Source: Modified from an agricultural statistics report [15]

Indicators 2017 2019

Land holdings 35,173 30,212

Holdings planted 33,399 24,396

Holdings harvested 28,585 10,956

Total land area (ha) 135,315 117,416

Total area planted (ha) 126,821 88,288

Total area harvested (ha) 92,942 22,866

Fallow land area (ha) 8494 29,128

Land area not planted (%) 6.3 24.8

Table 2 Climate change challenges and possible solutions in arable farming systems

Challenges in arable farming systems Possible solutions

Physiological droughts [44] Use of best management practices related to plant genotype, soil, etc. [45]

Irregular rainfall patterns and catastrophic floods [46, 47] Develop genetically modified and drought-tolerant crops that can effectively respond to cli-
mate change [48]

Significant soil moisture depletion during the arid 
seasons [49]
Excessive dryness or moisture prior to the scheduled 
planting period [39]

Usage of highly hydrophilic superabsorbent polymers which are believed to function 
as a reservoir for both nutrients and water [50]

Exceedingly high temperatures [51] Amendments of organic fertilizers in the soil, the organic fertilizers have the capacity to retain 
soil moisture that helps to reduce water stress when temperatures are high and rainfall 
is limited [52]

Accumulation of soil salts [51, 53] Phytoremediation approach which involves plant-based strategies for reclaiming degraded 
soils [54]



Page 4 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

Batswana (51%) have heard of climate change [20], which 
indicates that climate change issues are not efficiently 
addressed during the implementation of programs for 
sustainable crop production. [21] study reported that the 
El Niño southern oscillation (ENSO) is the most domi-
nant factor influencing the local climate across Botswana 
accounting for 85% and 78% of the variation in maize 
and sorghum yields, respectively, indicating that revising 
agricultural policies and programs is crucial.

Although there are still different views and findings 
from different studies, the international policies are 
still advised for sustainable agriculture on the basis of 
the adverse effects of climate change [22]. Therefore, 
expanded efforts to respond to climate change in Bot-
swana are needed immediately to ensure sustainable crop 
production and food security. Hence, this review aims to 
assess the current state of crop production in Botswana 
in the context of changing climate patterns and environ-
mental challenges. Moreover, this review aims to analyze 
the how effective government programs and policies have 
contributed to promoting sustainable crop production 
in Botswana, identify successes and shortcomings, chal-
lenges and barriers to sustainable crop production; and 
propose adaptation approaches and future directions. 
The novelty of this review is the evaluation of crop pro-
duction in the context of climate change in Botswana, 
the analysis of the effectiveness of government initia-
tives and the emphasis of continuous assessment aimed 

at promoting sustainable crop production in Botswana. 
Moreover, the review sheds light on the successes and 
failures of government initiatives and programs, empha-
sizing the involvement of stakeholders, particularly 
small-scale farmers, in efforts to ensure future food secu-
rity in Botswana.

Overview of Botswana’s agricultural landscape
The agricultural landscape in Botswana is character-
ized by predominantly arid to semiarid conditions and 
is prone to drought, with highly erratic rainfall ranging 
from 250 mm in the southwest to approximately 650 
mm in the north, making it inherently vulnerable to cli-
mate variability and change [5, 11, 23–26] with high 
atmospheric pressure and being landlocked [11, 25]. The 
majority of districts in Botswana face unpredictable and 
inconsistent yearly precipitation (Fig.  2), ranging from 
250 mm/annum in the southwest to 650 mm/annum in 
the north (average of 425 mm) [27, 28]. Among the four 
downscaled global climate models that have been used in 
Botswana (IPCC Fourth Assessment Report, Common-
wealth Scientific & Industrial Research Organization and 
Model for Interdisciplinary Research on Climate), most 
predict a 50–100 mm decline in rainfall in the southern 
and southeastern parts of the country and an increase in 
the annual maximum temperature from 1.5 to 2.5°C [5]. 
Different climate change scenarios make varying predic-
tions for the 2000–2050 period.

Fig. 2 Yearly climate profile of Botswana.  Source: Adapted from [35]



Page 5 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

Botswana is also susceptible to prolonged periods of 
drought, which are characterized by extremely dry con-
ditions and elevated temperatures from October to April 
[12, 17, 29] as shown in Fig.  2. The average minimum 
temperature demonstrated a rising trend, increasing by 
14.7°C from the reported value of 12.6°C from 1971 to 
2016. During the 2016/2017 season, exceptionally high 
temperatures were recorded in Ghanzi, Shakawe, Tsa-
bong, and Tshane, with values of 41.4, 41.6, 40.7, and 
41.0°C, respectively, surpassing typical conditions [30]. 
Botswana is likely to suffer greatly from climate change 
because of its climatic conditions. Intergovernmental 
Panel on Climate Change (IPCC) data indicate that Bot-
swana experienced an average temperature increase of 
1–2°C between 1970 and 2004 [31]. Moreover, the coun-
try is projected to experience a temperature increase of 
1–3°C, making it one of the hottest places in Sub-Saharan 
Africa. As reported by Botswana’s Communication to 
the United Nations Framework Convention on Climate 
Change (UNFCCC), Botswana intends to achieve an 
overall emission reduction of 15% by 2030, taking 2010 
as the base year [17, 32, 33]. The increasing frequency of 
extreme weather conditions, such as heatwaves, drought 
and flooding, dramatically negatively affects agricultural 
productivity [34].

Challenges facing crop production in Botswana
The challenges of adverse weather conditions includ-
ing climate-related factors (Table  2), greatly hinder the 
advancement of sustainable crop production in Bot-
swana [13, 36–39]. Moreover, low levels of adoption of 
improved technologies [13] contribute to poor agricul-
tural performance. Arable farming remains dominant 
among resource-limited smallholder farmers in Bot-
swana [14, 23, 30, 40–42]. Approximately 70% of the 

population in rural area heavily depends on arable farm-
ing for their livelihoods [27]. As a result, obtaining sus-
tainable crop production is challenging because of the 
susceptibility of arable farming to droughts and its vul-
nerability to climate change [38] and constraints related 
to funding, infrastructure, knowledge dissemination 
and market access. Furthermore, inappropriate policies 
and poor planning, coupled with hostile climatic condi-
tions such as floods and droughts, have had a significant 
impact on arable farming and the sector’s contribution to 
GDP [43].

Despite the extreme weather conditions, the agricul-
tural sector, particularly arable farming still plays a sig-
nificant role in Botswana’s economy, especially at the 
subsistence level [31]. However, the reliance on rainfall 
poses a significant challenge for ensuring food security 
and sustainable crop production in Botswana in the face 
of climate change. For the past three decades, Botswana 
has experienced stagnant agricultural productivity due to 
a variety of socioeconomic, environmental, and techno-
logical factors [5, 38]. Moreover, real wages in agriculture 
have also fallen compared with those in other sectors, 
such as manufacturing and services [13]. The other 
obstacles that have negatively impacted crop productiv-
ity include a lack of infrastructure, support services, and 
education, as well as limited access to financing [55].

As more challenges were experienced in the crop pro-
duction sector, a considerable decline in the agricultural 
contribution to gross domestic product (GDP) was noted. 
The decline in the agriculture sector’s share of GDP is 
another factor that indicates poor agricultural perfor-
mance in Botswana. Historical data show that the agri-
cultural of share to GDP has declined from 43.6% in 1960 
to 1.74% in 2022 (Fig. 3). However, the sector increased 
by 0.1 percent in real value added during the fourth 

Fig. 3 Historical chart of Botswana: GDP share of agriculture. Source: [57]



Page 6 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

quarter (Q4) of 2023, relative to a decrease of 0.6 percent 
registered in the same quarter of 2022 [56]. Although, a 
slight increase was observed in 2023 Q4, with a decrease 
of approximately 40% to 1.72% in GDP in 2023, the sec-
ond quarter was shown [5, 14, 25, 38] in comparison with 
the earlier contribution since Botswana gained inde-
pendence in 1966 [41]. Although the agricultural sector’s 
contribution to GDP has been relatively small in recent 
years, it is still essential for the livelihoods of subsistence 
farmers in Botswana [13, 38].

The impact of climate change on crop production
Climate change has become a mandatory agenda item in 
most twenty-first-century national, regional, and inter-
national forums [58]. It is a unique but important exog-
enous determinant of crop productivity [59]. Climate 
change manifests through rising temperatures, erratic 
precipitation patterns [23], more frequent droughts and 
floods, and an increased incidence of storms affecting 
agriculture across Africa [24]. The key global climate 
indicators of surface temperature, precipitation, ocean 
heat content, atmospheric carbon dioxide, ocean acidi-
fication, sea level, and Arctic and Antarctic sea ice con-
tents all provide an unfavorable trajectory of the global 
climate situation [58]. Smallholder farmers in Sub-Saha-
ran Africa are particularly vulnerable to the impacts of 
climate change on crop productivity [60]. The vulnerabil-
ity of African countries, including Botswana, to climate 
change is compounded by a strong dependence on rain-
fed agriculture [61] and natural resources, high levels of 
poverty, low levels of human capital, low levels of pre-
paredness for climate events, and poor infrastructure in 
rural areas [17].

Projections also point toward a decrease in rainfall 
(5–15% per century) coupled with hotter climates (a 
temperature increase from 2 to 5°C by 2050), specifically 
within southern Africa [27]. Southern Africa is projected 
to experience longer dry seasons and increased rainfall 
uncertainty [31], leading to adverse consequences such as 
flooding, famine, and drought [5]. [62] has reported that 
these trends could lead tropical areas to lose up to two 
hundred suitable plant growing days annually by the year 
2100. Higher temperatures and increasing rainfall vari-
ability are expected to reduce crop production capacity 
by approximately 50% [27]. According to the IPCC sixth 
assessment report, temperature increases will continue 
in most African regions because global warming leads 
to decreases in crop yields, increases in rainfall vari-
ability and unpredictability [58]. Global warming could 
harm agriculture across various countries studied [43]. 
Changes in precipitation affect crop revenue elasticity, 
but can have negative effects beyond a certain threshold 
[43].

The detrimental effects of climate change are particu-
larly evident in its impact on food security, agricultural 
productivity, and rural development and are among the 
most significant emerging challenges to household live-
lihoods in Africa [17, 30, 31, 37, 61]. Scientific reports 
indicate that crops are already being damaged globally 
due to climate change, with undeveloped nations bear-
ing the brunt of this phenomenon [17, 46, 62, 63]. A 
study conducted by [64] demonstrated significant reduc-
tions in yield for staple crops such as maize, sorghum 
and sunflower, with sorghum showing a comparatively 
lower reduction than maize followed by sunflower. [42] 
reported that maize yield is expected to decrease by an 
average of 18% in southern Africa. According to a study 
by [64], simulated decreases in yield for maize, sorghum, 
and sunflower were observed under various climate 
change scenarios. Notably, warm and dry conditions 
resulted in the greatest reduction in yield based on the 
basis of the Soil Moisture Accounting and Crop Simula-
tion (SMACS) model for assessing the risk, resilience, 
and reliability of rain-fed agriculture [64]. Reference [37] 
further highlighted an estimated decline (2.9% in 2030 
and 5.1% in 2050) and roots and tubers (1% in 2030 and 
1.7% in 2050). Potential substantial reductions antici-
pated across all crop types ranged from 10 to 50% by the 
year 2050 [24].

Climate change poses a significant threat to crop pro-
duction in Botswana, as it does in other regions of the 
world. There is an increased likelihood of increasing 
aridity and drought stress and higher temperatures in 
the country, leading to reduced crop yields [65] as stated 
above. The impacts of climate change also include con-
strained agricultural production, increased food insecu-
rity and negative effects on the economic well-being of 
communities, which will worsen with time, as projected 
[24], given that much of the country’s agriculture relies 
on rainfall for irrigation [5], similar to other African 
countries. The implications of climate change for agri-
culture are significant, compounding the already chal-
lenging conditions confronting farmers in this area [23]. 
Additionally, human-induced negative effects related to 
climate change are anticipated to have far-reaching con-
sequences for biodiversity and ecosystem services, as tra-
ditional water and food supply systems face strain due to 
population growth [31].

Moreover, marginalized communities tend to exces-
sively exploit the environment through intensive farming 
and deforestation, which ultimately results in soil degra-
dation and the loss of essential nutrients. The alterations 
occurring within the soil significantly affect its physi-
cal and chemical properties, ultimately contributing to 
poor plant growth and reduced crop yields. If these cli-
mate change challenges are not addressed, the difficulties 



Page 7 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

associated with climate change in the Botswana crop 
production industry will exacerbate the ongoing decline 
in crop yields, particularly in arable farming. Therefore, 
it is imperative that efforts to address agriculture in the 
context of food security and rural development consider 
climate change. In the absence of interventions, agri-
cultural yields in Botswana could decrease by as much 
as 30% by 2050 [17]. Despite the different challenges 
that have been identified in Botswana’s crop production 
industry, it is important to acknowledge the efforts made 
by the government to address these issues. Through the 
implementation of institutions, the government has 
helped increase crop production and improve food secu-
rity in the country.

Botswana agricultural institutional support 
for sustainable crop production
Government initiatives and adaptation efforts are crucial 
in advancing sustainable crop production in Botswana, 
especially amidst the challenges posed by climate change. 
Despite substantial government support, arable develop-
ment continues to underperform, and its contribution 
to the economy is declining; thus, the country is facing a 
situation of food insecurity [13, 61]. In response to these 
challenges, the Botswanan government has provided sig-
nificant public assistance to promote sustainable crop 
production in Botswana, achieve food security at both 
the household and national levels [41], and promote a 
business-oriented approach to farming [55]. To support 
these objectives, the Ministry of Agriculture Develop-
ment and Food Security and established parastatals such 
as the Botswana Agricultural Marketing Board (BAMB), 
the Botswana Institute for Technology Research and 
Innovation (BITRI), and the Botswana University of 
Agriculture and Natural Resources (BUAN) have been 
set up [55].

In addition to institutions, the government has imple-
mented various initiatives to address issues related to 
agricultural failures in Botswana; however, their goals 
have not been met [66]. Therefore, advancing sustain-
able agriculture is still highly important for improving 
the welfare of the rural population and promoting eco-
nomic diversification in Botswana. In addition to the 
adverse weather conditions faced by smallholder farm-
ers, other challenges include the effective adoption and 
implementation of government programs or initiatives 
designed to improve crop productivity and policy inte-
grations to ensure sustainable crop production in Bot-
swana [41]. Moreover, there is limited research on why 
these programs continue to fail despite government 
efforts and implementation strategies. Hence, this review 
aims to assess the implemented government programs 
and policies in promoting sustainable crop production in 

Botswana and provide recommendations for advancing 
sustainable crop production in Botswana.

Methodology
This systematic review adhered to the Preferred Report-
ing Items and Meta-Analysis for Systematic Reviews 
(PRISMA) guidelines to investigate government strate-
gies for sustainable crop production in Botswana amid 
climate change challenges. Such reviews enable the iden-
tification and exploration of the best available evidence, 
contradictory findings, and gaps in the literature. To be 
considered systematic, a review must aim to answer a 
specific research question, follow a predefined protocol, 
and comprehensively examine all relevant information. 
The PRISMA framework was utilized to ensure the syn-
thesis of literature while maintaining high levels of sci-
entific integrity, transparency, and reproducibility of the 
findings.

Data collection
A desktop research methodology was employed, drawing 
upon Google Scholar databases to collect data on gov-
ernment policies and programs. This involved reviewing 
published, peer-reviewed journal articles as well as rel-
evant reports issued by governmental authorities.

Search strategy
The literature search was conducted via Harzing’s 
Publish or Perish software (Windows GUI Edi-
tion_8.12.4612.8838) to source relevant information from 
the Google Scholar database. These keywords, including 
other databases “Botswana AND Climate change AND 
Crop production AND Government initiatives AND 
Smallholder farming systems AND Sustainable”, were 
used to retrieve information aligned with the research 
objectives. The search was then expanded to include all 
years, to capture the limited available research in this 
field. This broader search query generated 260 papers, 
which were subsequently filtered to remove duplicates 
and select only those relevant articles on the basis of 
country, title, abstract, and full text.

Data screening
Inclusion and exclusion criteria
The search results from Google Scholar were exported 
to Excel and underwent a multistep screening process. 
Only studies directly relevant to the review’s objec-
tives were included in the analysis. Initially, duplicates 
were removed, followed by the exclusion of studies (192) 
that did not align with the review’s geographic scope, 
ensuring the research’s relevance and focus. A second 
round of screening (68 articles) based on the title and 
abstracts further excluded 48 articles, and finally, full text 



Page 8 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

screening excluded (6 articles) primarily because of the 
lack of information on government strategies for sustain-
able crop production. Articles were also excluded if their 
titles and abstracts did not mention key terms such as 
"agricultural sustainability", "advancing sustainable crop 
production", "crop production in Botswana", "Botswana 
initiatives for improving crop production", "sustainable 
agriculture", "effect of climate change on crop produc-
tion", "Botswana climate change", and "climate mitigation 
strategies".

Data analysis
The third step involved a thorough examination of each 
article, extracting key information based on Botswana 
agricultural government’s efforts for sustainable crop 
production. Each included reviewed article focused on 
sections addressing the government’s policy or program 
for promoting sustainable agriculture.

Findings
The overall screening process is presented in Fig.  4. 
Among the 260 identified papers, 14 covered topics 
related to policies and programs that were implemented 
in Botswana for sustainable crop production.

Agricultural policy support by Botswana’s 
government for sustainable crop production
In addition to institutional development, the government 
of Botswana has introduced and implemented a variety 
of policies since the mid-1980s [14]. A summary of the 
implemented agricultural policies is presented in Table 3. 
Various strategies and initiatives have been implemented 
under different policies to successfully achieve the aims 
and objectives of these policies. Botswana adhered to a 
policy of food self-sufficiency in the first few decades fol-
lowing independence. In the early 1980s, however, Bot-
swana transitioned from a policy of food self-sufficiency 
to one of food security in 1991 [5, 11, 58]. Drought is the 

Identification of studies via Google Scholar databases 

Id
en

tif
ic

at
io

n
Sc

re
en

in
g

In
cl

ud
ed

Reports assessed for eligibility
Title, Abstracts (n =20)

Reports excluded:

No or very minimum 
adherence to the topic and 
abstract (n = 48)

Reports assessed for eligibility
Full text (n =14)

Reports excluded:

Full text (n = 6)

Studies included in review
(n = 14)

Records Of Country 
screened
(n = 68)

Records excluded**
country level (n = 192) 

Records identified from*:

Google Scholar (n = 260)

Records removed before 
screening: 
Duplicates (n = 0)

Fig. 4 Systematic review flowchart (PRISMA diagram)



Page 9 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

Ta
bl

e 
3 

A
gr

ic
ul

tu
ra

l p
ol

ic
y 

su
pp

or
t b

y 
th

e 
go

ve
rn

m
en

t o
f B

ot
sw

an
a 

fo
r s

us
ta

in
ab

le
 c

ro
p 

pr
od

uc
tio

n

Po
lic

y
Ye

ar
O

bj
ec

tiv
e

Ch
al

le
ng

es
Re

fe
re

nc
es

N
at

io
na

l F
oo

d 
St

ra
te

gy
 (N

FS
)

19
85

To
 re

du
ce

 d
ep

en
de

nc
e 

of
 th

e 
na

tio
n 

on
 fo

re
ig

n 
so

ur
ce

s 
of

 fo
od

 s
up

pl
ie

s; 
fo

od
 s

uffi
ci

en
cy

, a
nd

 c
on

se
rv

e 
ag

ric
ul

-
tu

ra
l l

an
d 

an
d 

re
du

ct
io

n 
of

 d
ep

en
de

nc
e 

of
 h

ou
se

ho
ld

s 
on

 g
ov

er
nm

en
t a

nd
 o

th
er

s 
to

 m
ak

e 
up

 fo
od

 d
efi

ci
ts

 
w

hi
ch

 c
an

no
t b

e 
pr

od
uc

ed
 b

y 
th

em
se

lv
es

.

H
ad

 a
 w

ea
k 

lin
k 

to
 c

lim
at

ic
 fa

ct
or

s 
w

hi
ch

 s
ig

ni
fic

an
tly

 
co

nt
rib

ut
e 

to
 c

ro
p 

pr
od

uc
tio

n
[6

7,
 7

2]

N
at

io
na

l P
ol

ic
y 

on
 A

gr
ic

ul
tu

ra
l D

ev
el

op
m

en
t

19
91

To
 im

pr
ov

e 
ag

ric
ul

tu
ra

l p
ro

du
ct

io
n 

th
ro

ug
h 

pr
ov

is
io

n 
of

 s
ec

ur
e 

an
d 

pr
od

uc
tiv

e 
en

vi
ro

nm
en

t f
or

 a
gr

ic
ul

tu
ra

l 
pr

od
uc

er
s.

Re
vi

se
d 

to
 im

pr
ov

e 
fo

od
 s

ec
ur

ity
 a

nd
 n

ut
rit

io
n 

by
 im

pr
ov

in
g 

ac
ce

ss
 to

 p
ro

du
ct

iv
e 

re
so

ur
ce

s 
su

ch
 

as
 la

nd
, fi

na
nc

e,
 in

pu
ts

, i
nf

ra
st

ru
ct

ur
e,

 a
nd

 in
fo

rm
at

io
n.

D
id

 n
ot

 d
is

cu
ss

 o
r c

on
si

de
r t

he
 s

ig
ni

fic
an

t i
nfl

ue
nc

e 
of

 c
lim

at
e 

ch
an

ge
 a

nd
 a

da
pt

at
io

n,
 w

hi
ch

 a
re

 c
ru

ci
al

 fa
c-

to
rs

 im
pa

ct
in

g 
th

e 
su

cc
es

s 
or

 fa
ilu

re
 o

f c
ro

p 
pr

od
uc

tio
n.

[2
6,

 3
2,

 7
3,

 7
4]

N
at

io
na

l A
da

pt
at

io
n 

Pl
an

 (N
A

P)
 a

nd
 A

ct
io

n 
Pl

an
C

lim
at

e 
C

ha
ng

e 
Re

sp
on

se
 P

ol
ic

y
A

im
 is

 to
 b

rin
g 

su
st

ai
na

bi
lit

y 
an

d 
cl

im
at

e 
ch

an
ge

 
re

si
lie

nc
e 

is
su

es
 in

to
 th

e 
m

ai
ns

tr
ea

m
 p

ol
ic

y 
di

sc
ou

rs
e,

 
ad

dr
es

si
ng

 d
ev

el
op

m
en

t p
la

nn
in

g 
w

ith
 th

e 
in

te
n-

tio
n 

of
 e

nh
an

ci
ng

 B
ot

sw
an

a’s
 re

si
lie

nc
e 

an
d 

ca
pa

ci
ty

 
to

 re
sp

on
d 

to
 e

xi
st

in
g 

an
d 

pr
oj

ec
te

d 
cl

im
at

e 
ch

an
ge

 
im

pa
ct

s.

In
su

ffi
ci

en
t r

es
ou

rc
es

, l
im

ite
d 

pu
bl

ic
 k

no
w

le
dg

e,
 

an
d 

in
eff

ec
tiv

e 
co

m
m

un
ic

at
io

n 
m

ay
 im

pe
de

 th
e 

su
c-

ce
ss

fu
l i

m
pl

em
en

ta
tio

n 
of

 th
e 

po
lic

y.

[3
3,

 5
8,

 7
1,

 7
4]

N
at

io
na

l C
om

m
itt

ee
 o

n 
C

lim
at

e 
C

ha
ng

e 
(N

CC
C

)
Re

vi
se

d 
in

 2
01

4
To

 b
ec

om
e 

a 
so

ci
et

y 
th

at
 is

 c
lim

at
e 

re
si

lie
nt

; t
o 

pr
o-

vi
de

, a
m

on
g 

ot
he

r t
hi

ng
s, 

gu
id

an
ce

 o
n 

de
ve

lo
pm

en
t 

ar
ea

s; 
to

 fa
ci

lit
at

e 
na

tio
na

l r
es

ea
rc

h 
pr

og
ra

m
s 

co
nc

er
n-

in
g 

gl
ob

al
 w

ar
m

in
g 

an
d 

cl
im

at
e 

ch
an

ge
; a

nd
 to

 a
dv

is
e 

go
ve

rn
m

en
t

D
is

pa
rit

ie
s 

in
 re

so
ur

ce
 a

cc
es

s 
im

pa
ir 

th
e 

ca
pa

ci
ty

 
of

 in
di

vi
du

al
s, 

ho
us

eh
ol

ds
, a

nd
 c

om
m

un
iti

es
 to

 e
ffe

c-
tiv

el
y 

re
sp

on
d 

to
 d

is
ru

pt
iv

e 
ev

en
ts

 a
nd

 p
re

ss
ur

es
, s

uc
h 

as
 c

lim
at

e 
ch

an
ge

[1
7,

 7
0]



Page 10 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

predominant climate-related stress that has necessitated 
government intervention [67]. The policies were focused 
on encouraging sustainable crop production practices 
and aimed at guiding, enhancing, and advancing the pro-
duction and productivity of agricultural subsectors since 
gaining independence in 1966. The primary objectives 
of agricultural policy are to ensure adequate and secure 
livelihoods for those involved in agriculture, increase 
productivity, achieve food sufficiency, and conserve agri-
cultural land [13, 68]. The government approved a white 
paper on the National Food Strategy in 1985 to facilitate 
the realization of some of these objectives [68]. With 
the introduction of the National Policy on Agricultural 
Development in 1991, a food security strategy focused 
on ensuring that households had access to sufficient food 
[13].

Other objectives of Nation Food are to achieve broad-
base recovery in arable production after the drought 
period, achieve national self-sufficiency in the main sta-
ple crops of maize and sorghum for both food and seed 
as soon as possible, ensure at least a minimum acceptable 
diet for all Botswana people and build up and maintain 
the national capacity to address drought and other emer-
gencies (national strategic grain reserves) [68]. However, 
the outcomes of these policies have not met expecta-
tions since there has been a continuous decline in the 
crop yields of major cereals (sorghum, maize and millet) 
in Botswana [41, 41, 68] and inconsistencies in policies 
[14]. The possible reason for these policy failures may 
be that the packages offered have concentrated mainly 
on providing input subsidies rather than extension ser-
vices and equipping farmers with improved manage-
ment skills [13]. Moreover, the initiatives seem not to 
have aligned with challenges of climate change in previ-
ous years, as climate effects were still manageable in the 
country as indicated by higher yields that were received 
by farmers. Nonetheless, an empirical model used by [13] 
showed positive output growth during the policy periods 
although it was relatively small at an average annual rate 
of 0.072%, which was attributed to increased input use. 
Overall, the climate change mitigation strategies devel-
oped in previous years does not seem to be well adopted 
by farmers; hence, sustainable crop production is still a 
concern in Botswana.

In 2020, the Botswana government developed a 
National Adaptation Plan (NAP) and Action Plan in 
response to the dire climate change situation [58]. The 
framework has several guidelines for ensuring inclusive 
climate change adaptation, which highlight all the pri-
ority areas, including climate-smart agriculture, which 
include techniques such as low to zero tillage and multi-
cropping to increase mulching, which reduces evapo-
transpiration and soil erosion [22].

In addition to the National Adaptation Program, the 
Government of Botswana drafted a climate change 
response policy [58]. The policy includes a range of adap-
tation strategies, categorized into agriculture and food 
security, biodiversity and ecosystems, human health, 
water, infrastructure, disaster risk reduction, forest 
management, land use and land allocation, and human 
settlement [69]. Botswana’s established national poli-
cies indicate the country’s commitment to both climate 
change adaptation and mitigation. The National Com-
mittee on Climate Change (NCCC) in 1999, which was 
reconstituted in 2012, was developed for the country to 
become a society that is climate resilient [70]. Addition-
ally, the National Agricultural Policy was formulated to 
improve food security at both the household and national 
levels [17]. Climate change strategies and policies for 
mitigation and adaptation include the National Climate 
Change Strategy 2018 and action plan, Draft Botswana 
Climate Change Response and  3rd communication to 
UNFCC (2019) [69, 71]. There is still an urgent need to 
propose a systematic evaluation framework so that more 
appropriate policies can be released to facilitate sustain-
able crop production [8]. However, further research is 
needed to verify the success of these measures and to 
scale up climate-smart innovations through policy sup-
port, capacity building, and effective dissemination of 
information. Agricultural policies in Botswana have faced 
little uptake, and practices have usually been discontin-
ued after subsidies have been removed [61].

Botswana is also a signatory to the Kyoto Protocol 
seeking to limit greenhouse gas emissions and the United 
Nations Framework Convention on Climate Change [20, 
32]. The global community has recognized the urgency 
of addressing climate change and promoting sustainable 
development. World leaders at the SDG Summit 2023 
adopted a sweeping political declaration reaffirming their 
commitment to the 2030 Agenda for Sustainable Devel-
opment [2]. Despite national policies and specific ini-
tiatives to enhance sustainable crop production, world 
leaders, including Botswana in 2015, established 17 
global sustainability development goals (SDGs) as a uni-
versal agenda for 2030. Among the set SDGs, SDG 2 (zero 
hunger) aims to eradicate hunger, ensure food security, 
improve nutrition, and encourage sustainable agricul-
ture [75]; however, this goal is still a challenge due to the 
continued adverse impacts of climate change. Therefore, 
efforts must be put into the agricultural crop production 
sector to achieve this goal, which can only occur if gov-
ernment policies are well implemented in line with cur-
rent situations with the involvement of all stakeholders.

Integrating adaptation to climate change into eco-
nomic principles is essential for building resilience and 
protecting vulnerable sectors such as agriculture. The 



Page 11 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

Ta
bl

e 
4 

A
gr

ic
ul

tu
ra

l p
ro

gr
am

s 
fo

r s
us

ta
in

ab
le

 c
ro

p 
pr

od
uc

tio
n 

in
 B

ot
sw

an
a

Pr
og

ra
m

s
Ye

ar
O

bj
ec

tiv
e

Ch
al

le
ng

e
Re

fe
re

nc
e

A
ra

bl
e 

La
nd

s 
D

ev
el

op
m

en
t p

ro
gr

am
s 

(A
LD

EP
)

19
77

To
 a

ss
is

t i
n 

im
pr

ov
in

g 
fa

rm
in

g 
pr

ac
tic

es
 a

nd
 fo

od
 

pr
od

uc
tio

n,
 a

nd
 w

ith
 th

e 
so

le
 a

im
 o

f a
ch

ie
vi

ng
 s

el
f-

su
ffi

ci
en

cy
 in

 s
ta

pl
e 

fo
od

 p
ro

du
ct

io
n

To
p-

do
w

n 
ap

pr
oa

ch
, w

ea
k 

lin
k 

to
 c

lim
at

ic
 fa

ct
or

s, 
an

d 
le

ss
 s

ki
lls

 d
ev

el
op

m
en

t i
n 

co
ns

er
va

tio
n 

til
la

ge
; 

no
 a

dd
iti

on
al

 m
an

po
w

er
 to

 im
pl

em
en

t a
nd

 m
on

ito
r

[3
2,

 4
1,

 6
7]

A
cc

el
er

at
ed

 R
ai

n-
fe

d 
A

gr
ic

ul
tu

re
 P

ro
gr

am
m

e 
(A

RA
P)

19
85

To
 a

ss
is

t a
ra

bl
e 

fa
rm

er
s 

to
 d

e-
st

um
p 

te
n 

he
ct

ar
es

, p
ro

-
vi

de
 s

ee
d 

an
d 

fe
rt

ili
ze

r, 
an

d 
su

bs
id

iz
e 

la
nd

 p
re

pa
ra

tio
n 

an
d 

pl
an

tin
g

Th
e 

go
ve

rn
m

en
t t

er
m

in
at

ed
 th

e 
pr

og
ra

m
 u

po
n 

D
ry

-
la

nd
 C

ro
p 

Pr
od

uc
tio

n 
in

 B
ot

sw
an

a 
af

te
r r

ea
liz

in
g 

th
at

 fa
rm

er
s 

w
er

e 
no

w
 re

ly
in

g 
so

le
ly

 o
n 

th
e 

go
ve

rn
-

m
en

t f
or

 a
ll 

th
ei

r i
np

ut
s

[3
2,

 4
1,

 6
7]

N
at

io
na

l M
as

te
r P

la
n 

fo
r A

gr
ic

ul
tu

ra
l D

ev
el

op
m

en
t 

(N
A

M
PA

A
D

)
20

02
To

 tr
an

sf
or

m
 tr

ad
iti

on
al

 to
 c

om
m

er
ci

al
 fa

rm
in

g 
ac

tiv
-

ity
. I

t a
im

ed
 to

 im
pr

ov
e 

cr
op

 y
ie

ld
s 

an
d 

pr
od

uc
tiv

ity
 

an
d 

to
 c

re
at

e 
vi

ab
le

 b
us

in
es

s 
op

po
rt

un
iti

es
 fo

r f
ar

m
er

s

Th
e 

m
an

po
w

er
, e

xp
er

tis
e,

 a
nd

 in
fra

st
ru

ct
ur

e 
re

qu
ire

d 
to

 im
pl

em
en

t i
s 

lim
ite

d,
 a

nd
 c

lim
at

ic
 is

su
es

 a
re

 
no

t a
de

qu
at

el
y 

fa
ct

or
ed

 in
.

[1
4,

 6
6,

 6
7]

In
te

gr
at

ed
 S

up
po

rt
 fo

r A
ra

bl
e 

A
gr

ic
ul

tu
ra

l P
ro

du
ct

io
n 

(IS
PA

A
D

)
20

08
To

 in
cr

ea
se

 g
ra

in
 p

ro
du

ct
io

n,
 p

ro
m

ot
e 

fo
od

 s
ec

ur
ity

 
at

 th
e 

ho
us

eh
ol

d 
an

d 
na

tio
na

l l
ev

el
s, 

co
m

m
er

ci
al

iz
e 

ag
ric

ul
tu

re
 th

ro
ug

h 
m

ec
ha

ni
za

tio
n,

 fa
ci

lit
at

e 
ac

ce
ss

 
to

 fa
rm

 in
pu

ts
 a

nd
 c

re
di

t, 
an

d 
im

pr
ov

e 
ex

te
ns

io
n 

ou
tr

ea
ch

IS
PA

A
D

 in
iti

at
iv

e 
fa

ile
d 

to
 re

co
gn

iz
e 

th
e 

ag
ro

ec
ol

og
y 

of
 th

e 
co

un
tr

y 
as

 a
 s

em
ia

rid
 a

re
a 

in
cl

ud
in

g 
is

su
in

g 
no

n-
su

ita
bl

e 
cr

op
s 

an
d 

va
rie

tie
s 

fo
r t

he
 p

re
va

ili
ng

 c
lim

at
e.

[1
4,

 4
1,

 5
9,

 6
1,

 6
6,

 7
7]



Page 12 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

Botswanan government’s initiatives are commendable, 
but more work is necessary to ensure the long-term via-
bility of agricultural production in Botswana in the face 
of climate change. Given the significance of the agricul-
tural sector and the ongoing decline in crop productivity 
despite government interventions, developing effective 
policies is essential. Botswana’s agricultural sector pol-
icy focuses on addressing the impact of climate change, 
promoting backyard gardening as an adaptation strategy 
to support poor populations, and providing safety nets 
to poor urban and rural residents. Therefore, Botswana 
has transitioned from a policy emphasizing food self-suf-
ficiency to a focus on food security, which incorporates 
increasing imports.

By aligning with global sustainability targets and local 
action, adopting adaptive approaches, and integrating 
policies, Botswana can enhance its agricultural resilience 
and contribute to sustainable development goals while 
increasing crop production and enhancing food stabil-
ity. Although there are set and implemented policies, it 
is essential to offer integrated and coherent policies that 
promote sustainable growth and benefit the poor. Pro-
viding targeted support for small farmers, particularly 
women, who cultivate a significant portion of farmland 
and deliver a substantial harvest [5]. Moreover, policies 
should effectively address issues such as soil degradation 
and low crop yields to advance to sustainable crop pro-
duction. Understanding the potential impacts of climate 
change on crop production is key for formulating and 
establishing policies for sustainable crop production and 
improved food security in Botswana. Furthermore, inte-
grating policies across sectors such as agriculture, water 
resource management, and climate change adaptation is 
crucial for sustainable food security in Botswana.

Agricultural programs for sustainable crop 
production in Botswana
Since 1980, the government has allocated funds for agri-
cultural programs that amount to approximately 40% 
of agricultural GDP, surpassing the Sub-Saharan Afri-
can average of 25–29% [13]. Moreover, the Botswana 
government has been supported by introducing pro-
grams tailored for farmers (producers) [66]. Table  4 
presents a summary of programs implemented by the 
Botswana government for sustainable crop production. 
These programs include the Arable Lands Development 
Programme (ALDEP), the Accelerated Rainfed Arable 
Programme (ARAP), the Irrigation and Water Develop-
ment Project, Dairy Improvement and other ventures 
funded under the Financial Assistance Policy (FAP) [13, 
66]. Furthermore, conservation agriculture (CA) has 
been introduced as a strategy to increase crop produc-
tion in drylands; however, smallholder systems continue 

to experience low crop yields of less than one ton per 
hectare [41]. The Arable Land Development Program 
(ALDEP), launched in 1979 to assist small-scale farmers 
(representing almost 70–75% of traditional arable farm-
ers), did not produce satisfactory outcomes as stated 
by Morapedi (2016). There are constraints linked to the 
implementation of competing programs in the same sec-
tor, in addition to problems of climate variability [67].

The implementation of the Accelerated Rainfed Arable 
Programme (ARAP) in 1985 was subsequently intro-
duced as an inclusive initiative supporting farmers 
involved in rain-fed arable agriculture. ARAP helped 
with grants for ploughing, access to improved seeds and 
fertilizers, and water development initiatives, which led 
to notable increases in cultivated area, output, and yields 
of 27, 120 and 74%, respectively, according to [14] find-
ings. However, the ARAP initiative was discontinued in 
1990 and was only reintroduced in a modified format in 
1993 as Drought Relief to Arable Farmers (DRAF) [13]. 
Both ALDEP and ARAP provided complimentary capital 
and operating inputs to farmers with the goals of pro-
moting technology adoption and enhancing rain-fed ara-
ble agriculture productivity, as documented in the study 
by [13]. The initiatives survived only for as long as there 
was a government subsidy.

In 2008, ALDEP was rebranded the Integrated Arable 
Agriculture Development Support Program (ISPAAD) 
because of its failure to achieve its goals amid a continu-
ous decline in crop production [13, 76]. ISPAAD aimed 
to supply farmers with free inputs and equipment, and 
provides financing at low interest rates [14, 77]. The 
implementation of the ISPAAD program in 2008 led to 
an improvement in arable farming, reflected by a slight 
increase in the total cultivated area between 2010 and 
2011 (220,059 ha and 261,967 ha, respectively). In 2010, 
64.2% of the total area was harvested, whereas in 2011 
the total harvested area was 66.4% (Botswana, 2008). 
However, there was a subsequent reduction in the total 
cultivated area during 2017 and 2019 compared with that 
in the previous year [14, 15]. Despite overall improve-
ments in agricultural efficiency, both the total planted 
and harvested areas have considerably declined recently. 
The low crop yields during the ISPAAD program period 
given the free input support to farmers suggest that the 
current adaptation practices used in rain-fed crop pro-
duction were inadequate [59]. Consequently, despite 
substantial investment in ISPAAD, Botswana’s agricul-
tural productivity levels have not significantly increased 
relative to those of other countries within Sub-Saharan 
Africa [13]. The findings of [59] suggested that current 
adaptations were inadequate and that the implementa-
tion of the ISPAAD program required fine-tuning to be 
more effective; hence, the program was unsuccessful.



Page 13 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

On the basis of the findings of a study by [13], the sto-
chastic frontier approach model was employed to exam-
ine literature related to ALDEP, ARAP and ISPAAD 
outcomes. The results indicate that only ISPAAD is sta-
tistically significant and has a positive effect, suggest-
ing that the program contributed to agricultural output 
growth from 2009 to 2012. Records from the ISPAAD 
show an increase in the number of beneficiaries impacted 
compared to previous programs, as well as an expansion 
in cultivated area since its introduction in 2008. However, 
crop production yields have been lower than expected 
with increased fallow land, which clearly indicates that 
there are external factors contributing to the failure of 
these programs, with climate change being among them, 
as has been observed around the world.

Botswana suffers from endemic droughts that are 
becoming more frequent and severe due to climate 
change [61]. Recently, in 2023, Botswana’s government 
declared the year 2022/2023 a severe drought period 
for agriculture due to significantly low rainfall levels, 
extremely elevated temperatures, and prolonged dry 
spells. A government press release on drought and house-
hold food security relief measures for the 2023/2024 sea-
son dated 20 June 2024 indicates that the declaration of 
the drought season was based on the reported outcomes 
of drought and household food security vulnerability and 
analysis exercise. Some outcomes of the report were as 
follows: (1) the rainy season (October 2023–March 2024) 
exceptionally dry with below average rainfall throughout 
the entire country; (2) the February month was harsh, 
experiencing the driest conditions since 1980; (3) water 
levels in dams and rivers across the country significantly 
declined, with some dams at critically low levels (below 
30% capacity), with major rivers (Thamalakane & Chobe) 
experiencing the lowest water levels in a decade; (4) 
currently, a moderate hydrological drought is in effect, 
necessitating close monitoring of water usage; (5) delayed 
rains and extended dry spells severely impacted crops 
(wilting & failed early in the season; and (6) deterioration 
of the grazing areas.

Owing to these challenges, a drought relief program 
for 2022/2023 was initiated with measures and sup-
port during the drought period because of Botswana’s 
rural context, that of a “dual society”, i.e., a large num-
ber of smallholder farmers using low technology and 
dependent on drought relief [61]. However, it is still 
to be understood whether this initiative aligns with the 
current experienced situation of climate change in the 
crop production sector. Furthermore, Temo Letlotlo was 
implemented to improve food security at the household 
and national levels, with the main intention of the pro-
gram being to help farmers achieve commercial opera-
tion. The chances that these programs will be effective for 

sustainable agricultural productivity are unknown; there-
fore, it is highly recommended that these new initiatives 
be consistently evaluated due to climate change chal-
lenges otherwise the same results from past initiatives 
may be experienced. Investment in sustainable crop pro-
duction practices is essential not only for food security, 
but also for economic development and poverty allevia-
tion. For Botswana to achieve sustainable growth while 
benefiting its impoverished population, it is crucial to 
implement integrated and reliable policies addressing the 
multifaceted challenges posed by climate change, water 
scarcity, and agricultural waste management [5]. The 
lack of comprehensive studies exploring the effectiveness 
of government programs aimed at promoting sustain-
able crop production in arable farming underscores the 
need for additional research in this area. Considering the 
pressing need to address climate change and its impact 
on sustainable crop production, it is essential to evaluate 
initiatives and implement effective mitigation strategies. 
In the following section, we explore various approaches 
that can help overcome these challenges.

Approach strategies for sustainable crop 
production amidst climate change
Advancing sustainable crop production in Botswana 
requires a multifaceted approach that includes govern-
ment initiatives, international cooperation, and adapta-
tion efforts to mitigate the impacts of climate change 
on agriculture. Mitigating the impact of climate change 
is crucial in southern Africa, particularly in Botswana, 
which is affected by frequent and prolonged droughts as 
high temperatures [64]. Inventive techniques and adapt-
able strategies are necessary to reduce susceptibility and 
promote resilience in rain-fed agricultural systems to 
maintain food security. For instance:

• Policy reforms: By harmonizing policies and strate-
gies across sectors, Botswana can effectively address 
the intersection of climate change, crop production, 
and national initiatives aimed at increasing crop 
yields. The current national policy on agricultural 
development should be evaluated to assess its align-
ment with and potential for climate-smart agricul-
ture [17], investment priorities, and research pri-
orities, for example, considering  CO2 fertilization 
to potentially mitigate the adverse effects of climate 
change through adaptation [42].

• Conservation agriculture: Practices should be 
adopted to increase soil health and fertility while 
minimizing erosion. Enhancing soil water productiv-
ity through conservation agriculture practices such as 
reduced tillage, retaining crop residues, and on-farm 



Page 14 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51 

water conservation has been suggested as a means of 
mitigating climate change effects [64].

• Genetic diversity  in crops is also essential for ena-
bling adaptation to changing environmental condi-
tions. The use of drought-resistant crop varieties can 
improve crop production despite changing climatic 
conditions [17]. The use of improved crop varie-
ties [78, 79] alongside better management practices 
with suitable fertilizers also aids in enhancing yields 
amidst changing climates [80].

• Indigenous and emerging plant resources that 
have been overlooked by policymakers, research-
ers, and consumers are promising for addressing 
food security, income generation and climate change 
impacts [81].

• The adoption of sustainable irrigation methods 
may involve advocating for the efficient and sustain-
able use of water resources in agriculture, and the 
creation of viable irrigation systems.

• Implementing climate-smart agriculture: Includes 
beneficial climate information, such as accurate 
weather forecasts, enabling smallholder farmers 
to make informed decisions regarding their crops. 
Furthermore, implementing early warning systems 
helps alert farmers about impending weather events, 
allowing them sufficient time to safeguard their crops 
against potential damage [82–84].

• Adequate capacity-building initiatives for further 
advancing sustainable crop production in Botswana 
amidst climate change involving training smallholder 
farmers on climate-resilient agricultural practices 
play an important role in facilitating their adaptation 
efforts amidst evolving climatic conditions [85–87].

• Regional collaboration helps smallholder farm-
ers, establish institutional frameworks that promote 
collaboration among different stakeholders. This 
approach is essential for effective climate change mit-
igation across Southern Africa; modeling approaches 
can serve as decision support tools when assessing 
rain-fed farming systems interventions against cli-
mate impacts involving smallholder farmers [64].

Conclusion
Advancing sustainable crop production amidst climate 
change challenges is urgent worldwide. This review 
assessed crop production sustainability in Botswana 
based on government initiatives and policies. The find-
ings of the review highlighted that the government has 
been providing input subsidies through different agri-
cultural policies since independence. However, a signifi-
cant decline in crop productivity has occurred in recent 
decades despite the government’s efforts to improve 

food security. Climate change, with erratic rainfall 
and higher temperatures, a lack of a skilled workforce, 
inconsistent policies and low adoption of agricultural 
technologies, may have contributed to the failure of 
these initiatives. Recently, 2022/2023 was declared a 
drought year, indicating the need for advanced strat-
egies for sustainable crop production in Botswana. 
Additionally, this implies that Botswana is likely to 
continue importing cereals from other neighboring 
countries soon. To address this situation, comprehen-
sive and inclusive approaches are urgently needed for 
sustainable crop production. For instance, emphasizing 
adaptation, collaboration, and stakeholder commitment 
can ensure sustainable crop production and future food 
security in Botswana. This review’s main limitation 
was the reliance on limited data, and there is limited 
information on the subject matter in Botswana. Hence, 
future research focusing more on surveys and field vis-
its, and engaging relevant stakeholders in government 
institutions to understand the reasons behind govern-
ment initiative failures is highly recommended. Reas-
sessing initiatives before implementation is also highly 
important.

Abbreviations
ALDEP  Arable Lands Development Programme
ARAP  Accelerated Rainfed Arable Programme
BAMB  Botswana Agricultural Marketing Board
BITRI  Botswana Institute for Technology Research and Innovation
BUAN  Botswana University of Agriculture and Natural Resources
CA  Conservation Agriculture
DRAF  Drought Relief to Arable Farmers
ENSO  El Niño southern oscillation
FAP  Financial Assistance Policy
GDP  Gross domestic product
IPCC  Intergovernmental Panel on Climate Change
ISPAAD  Integrated Arable Agriculture Development Support Program
NAMPAAD  National Master Plan for Agricultural Development
NAP  National Adaptation Plan
NCCC   National Committee on Climate Change
NFS  National Food Strategy
PRISMA  Preferred Reporting Items and Meta-Analysis for Systematic 

Reviews
SDGs  Sustainable Development Goals
SMACS  Soil Moisture Accounting and Crop Simulation
SSA  Sub-Saharan Africa
UNFCCC   United Nations Framework Convention on Climate Change

Author contributions
BLM and BM conceived and designed the structure of the review manu-
script. All the authors contributed to the review’s conception and design. 
BLM drafted the original manuscript draft, and all the authors contributed 
equally to the reading, critical revision and approval of the final draft of this 
manuscript.

Funding
The authors declare that no funds, grants, or other support was received dur-
ing the preparation of this manuscript.

Availability of data and materials
Data sharing is not applicable to this article as no datasets were generated or 
analyzed during the current study.



Page 15 of 17Masocha et al. Agriculture & Food Security           (2024) 13:51  

Declarations

Ethics approval and consent to participate
Not applicable.

Consent for publication
Not applicable.

Competing interests
The authors declare that they have no competing interests.

Author details
1 School of Geography, Archaeology and Environmental Studies, University 
of the Witwatersrand, Johannesburg 2050, South Africa. 2 Southern African 
Science Service Centre for Climate Change and Adaptive Land Management, 
Gaborone, Botswana. 3 School of Clinical Medicine, University of the Witwa-
tersrand, Johannesburg 2050, South Africa. 4 Department of Environmental 
Science, University of Botswana, Private Bag 00704, Gaborone, Botswana. 

Received: 27 April 2024   Accepted: 30 September 2024

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	Systematic review of government strategies for sustainable crop production in Botswana: navigating climate change challenges
	Abstract 
	Introduction
	Crop production performance in Botswana
	Overview of Botswana’s agricultural landscape
	Challenges facing crop production in Botswana

	The impact of climate change on crop production
	Botswana agricultural institutional support for sustainable crop production
	Methodology
	Data collection
	Search strategy
	Data screening
	Inclusion and exclusion criteria

	Data analysis
	Findings

	Agricultural policy support by Botswana’s government for sustainable crop production
	Agricultural programs for sustainable crop production in Botswana
	Approach strategies for sustainable crop production amidst climate change
	Conclusion
	References