Supply Chain Disruption Risk Management with Blockchain: A Dynamic Literature Review
Abstract
:1. Introduction
2. Materials and Methods
3. First Phase of SLNA Methodology: SLR
3.1. Scope of the Analysis
- RQ1: What are the latest blockchain applications focused on disruption risk management?
- RQ2: How is blockchain solutions used to identify potential disruption risks?
3.2. Locating Studies
3.3. Study Selection and Evaluation
4. Second Phase of SLNA Methodology: BNA
5. Results
5.1. Citation Network Analysis (CNA)
5.1.1. The Biggest Connected Component
5.1.2. The Louvain Communities’ Analysis
Community A—Disruption Risk Management by Blockchain
Community C—A Digital Record of Every Transaction and Interaction
Community D—Integration of Blockchain with IoT to Solve Privacy and Security Vulnerabilities
Community E—Transparency and Traceability in Information Exchange by Blockchain Technology
Community F—Anti-Counterfeiting by Blockchain
Community G—Information Privacy by Blockchain
Community H—Safety and Security Aspects of the Blockchain
5.1.3. Main Path Analysis
5.1.4. General Comments on the Connected Components’ Analyses
5.2. Global Citation Score Analysis
5.3. Co-Occurrence Analysis of Author Keywords
5.3.1. Cluster 1: Digitalization for Improved Supply Chain Resilience
5.3.2. Cluster 2: Employing Blockchain Technology with Smart Contracts in Supply Chain Management
5.3.3. Cluster 3: Traceability Database Systems to Ensure Food Safety and Security
5.3.4. Cluster 4: Blockchain’s Benefits in Strengthening Cybersecurity and Cryptography
5.3.5. Cluster 5: Privacy and Security Challenges and Blockchain Solutions
5.3.6. Cluster 6: Security of Smart Contracts in Ethereum Platforms
5.3.7. Cluster 7: Monitoring Counterfeited Products in the Supply Chain
6. Discussion of Findings and Future Research Directions
7. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
References
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Authors | Topic | Main Issues | Contribution |
---|---|---|---|
[6,28] | Integration of blockchain and the Internet of things (IoT) |
|
|
[63,64] | Use of blockchain for supply chain securityblockchain-enabled supply chain activities |
|
|
[44] | Adoption, benefits, and challenges |
|
|
[46] | Blockchain solutions for IoT and IIoT |
|
|
[65] | Adoption, drivers, and challenges |
|
|
[66] | Cross-border e-commerce supply chain and traceability |
|
|
[67] | Food supply chain and traceability |
|
|
[68,69] | Automation of the transaction process |
|
|
[23,25] | Digital technologies and resilient supply chain |
|
|
[26] | Sustainability and traceability |
|
|
[27] | Humanitarian logistics and supply chain |
|
|
Title | Author | Source | Year | GCS | Main Path | Louvain Community |
---|---|---|---|---|---|---|
Can Blockchain Strengthen the Internet of Things? | [28] | IT Professional | 2017 | 213 | YES | G |
Blockchain’s roles in meeting key supply chain management objectives | [64] | International Journal of Information Management | 2018 | 175 | YES | B |
A supply chain traceability system for food safety based on HACCP, blockchain and the Internet of things | [67] | 14th International Conference on Services Systems and Services Management, ICSSSM 2017—Proceedings | 2017 | 120 | YES | A |
Blockchain’s roles in strengthening cybersecurity and protecting privacy | [6] | Telecommunications Policy | 2017 | 110 | YES | H |
When intrusion detection meets blockchain technology: A review | [59] | IEEE Access | 2018 | 108 | NO | H |
A Novel Blockchain-Based Product Ownership Management System (POMS) for Anti-Counterfeits in the Post Supply Chain | [51] | IEEE Access | 2017 | 98 | NO | F |
The impact of digital technology and Industry 4.0 on the ripple effect and supply chain risk analytics | [25] | International Journal of Production Research | 2019 | 81 | YES | A |
Blockchain adoption challenges in the supply chain: An empirical investigation of the main drivers in India and the USA | [65] | International Journal of Information Management | 2019 | 54 | YES | A |
Blockchain application in food supply information security | [47] | IEEE International Conference on Industrial Engineering and Engineering Management | 2018 | 51 | NO | E |
The impact of the blockchain on the supply chain: a theory-based research framework and a call for action | [48] | Supply Chain Management | 2018 | 41 | NO | E |
Main Subjects | Keywords |
---|---|
Cluster 1: Digitalization for improved supply chain resilience | Additive manufacturing; blockchain technology; cryptocurrency; industry 4.0; RFID; supply chain resilience; supply chain risk management |
Cluster 2: Employing blockchain technology with smart contracts in supply chain management | Blockchain; IoT; risk management; smart contracts; supply chain management |
Cluster 3: Traceability database systems to ensure food safety and security | Distribute ledger technology; food safety; food security; food supply chain; traceability |
Cluster 4: Blockchain’s roles in strengthening cybersecurity | cloud computing; cryptography; cybersecurity; Internet of things |
Cluster 5: Privacy and security challenges and blockchain solutions | Blockchain; distributed ledger; privacy; security |
Cluster 6: Security of smart contracts in Ethereum platforms | Ethereum; smart contract |
Cluster 7: Monitoring counterfeited products in the supply chain | Counterfeit; supply chain |
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Etemadi, N.; Borbon-Galvez, Y.; Strozzi, F.; Etemadi, T. Supply Chain Disruption Risk Management with Blockchain: A Dynamic Literature Review. Information 2021, 12, 70. https://doi.org/10.3390/info12020070
Etemadi N, Borbon-Galvez Y, Strozzi F, Etemadi T. Supply Chain Disruption Risk Management with Blockchain: A Dynamic Literature Review. Information. 2021; 12(2):70. https://doi.org/10.3390/info12020070
Chicago/Turabian StyleEtemadi, Niloofar, Yari Borbon-Galvez, Fernanda Strozzi, and Tahereh Etemadi. 2021. "Supply Chain Disruption Risk Management with Blockchain: A Dynamic Literature Review" Information 12, no. 2: 70. https://doi.org/10.3390/info12020070