MAINA, Jemimah (2025). A Blockchain-enabled Framework for the Humanitarian Supply Chain in Kenya. Doctoral, Sheffield Hallam University. [Thesis]
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Maina_2025_PhD_BlockchainEnabledFramework.pdf - Accepted Version
Restricted to Repository staff only until 24 July 2026.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
Maina_2025_PhD_BlockchainEnabledFramework.pdf - Accepted Version
Restricted to Repository staff only until 24 July 2026.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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Abstract
As the frequency and intensity of disasters continue to rise globally, there is a growing need
for efficient humanitarian supply chains, which are crucial for delivering lifesaving resources
during emergencies. (HSCs), particularly in resource-constrained environments like Kenya,
face critical challenges of aid diversion and fraud, logistical delays, and a lack of trust amongst
humanitarian partners, which makes information sharing and coordination difficult. Solving
these multi-faceted challenges calls for innovative approaches. Blockchain technology (BCT),
known for its decentralised and immutable features, guarantees data privacy and security, and
provides benefits of enhanced transparency and trust, which are critical in addressing
operational challenges within HSCs.
Numerous authors have recommended the integration of blockchain solutions in HSCs. To date,
there remain few blockchain use-cases that provide evidence on the benefits and limitation of
its implementation. Furthermore, humanitarian organisations (HOs) still face the challenge of
how to implement the blockchain as there is a lack of a framework to guide them on the
implementation process. This thesis aimed at filling this gap, by designing and developing a
blockchain-enabled framework tailored for the HSC in Kenya. The framework shows a clear
roadmap for blockchain implementation stages with distinct phases from initial planning to
full-scale deployment and optimisation of the blockchain.
The research adopted a mixed-method approach, specifically the explanatory sequential design,
which starts with a quantitative phase, followed by a qualitative phase. For the quantitative
phase, a feasibility study was conducted through a questionnaire survey involving key Kenyan
humanitarian stakeholders, to identify the sectoral needs that BCT could address. Further to the
feasibility study, the survey explored stakeholder’s awareness about the blockchain. Statistical
analysis for hypothesis testing was conducted using SPSS statistical software. Insights from
the analysis, supplemented by secondary literature, guided the development of the blockchain-enabled framework. The qualitative phase involved the validation of the framework, and deeper
exploration, and explanation of the quantitative results, which was done through in-depth
interviews, with Kenya humanitarian experts. The interviews were coded and analysed
thematically, using Nvivo software.
The finetuned blockchain-enabled framework consisted of nine stages. Findings indicate that
the awareness stage was the most critical for the wide-scale adoption of BCT. BCT promises
to significantly reduce most operational challenges within the Kenya HSC, ultimately
strengthening disaster resilience of the country. To achieve these benefits, blockchain design
should consider users experience, and interoperability with existing systems and HOs’ values.
Leaders must also support BCT implementation to ensure strategic buy-in. Respondents were
worried about BCT’s privacy and security due to association with fraudulent activities like the
Silk Road, and therefore, stronger regulations and compliance to ethical standards in BCT
usage is required to mitigate system risks. Future studies should focus on validating the
blockchain-enabled framework in other countries to enhance the generalisation of results in
HSCs. Further exploration of the benefits and drawbacks of using BCT in third-party and cloud
computing infrastructure such as Microsoft Azure in HSCs is required
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