AgriTrace™ Dissertation Proposal

A Blockchain-Enabled, AI-Augmented Traceability and Sustainability Framework for Agricultural and Agroforestry Supply Chains

ABSTRACT

This dissertation proposes AgriTrace™, an integrated framework combining permissioned blockchain, AI-driven analytics, and digital traceability to enhance transparency, trust, and sustainability in agricultural and agroforestry supply chains. The study designs, implements, and evaluates a scalable system that links farm-level data capture to verifiable market authentication while enabling ESG reporting and carbon credit generation. Using mixed methods (design science + empirical evaluation), the research assesses system performance, data integrity, user adoption, and economic impact.

CHAPTER 1: INTRODUCTION

1.1 Background of the Study

Global agricultural supply chains face increasing demands for traceability, sustainability, and compliance. Fragmented recordkeeping and weak verification mechanisms lead to fraud, inefficiency, and limited market access. Advances in blockchain, AI, and IoT present opportunities to build secure, transparent, and intelligent systems that can transform how agricultural products are tracked and valued.

1.2 Research Problem

Despite technological advances, there is no widely adopted framework that integrates:

  • End-to-end traceability
  • Tamper-proof verification
  • Real-time data capture
  • Sustainability and carbon accounting
  • Market-facing authentication

1.3 Research Questions

  1. How can blockchain enhance trust and data integrity in agricultural supply chains?
  2. What system architecture best supports scalable traceability from farm to market?
  3. How can AI improve data validation, anomaly detection, and analytics?
  4. What is the impact of traceability on market value and stakeholder trust?
  5. How can carbon credit systems be integrated into traceability platforms?

1.4 Objectives

General Objective

To design, develop, and evaluate an integrated traceability and sustainability framework.

Specific Objectives

  • Develop blockchain-based traceability architecture
  • Implement AI-assisted data validation and analytics
  • Integrate QR-based authentication
  • Develop ESG and carbon tracking modules
  • Evaluate system performance and adoption

1.5 Hypotheses

H1: Blockchain-based systems significantly improve data integrity.
H2: Traceability increases buyer trust and willingness to pay.
H3: AI-assisted validation reduces data anomalies.

1.6 Significance of the Study

  • Academic: advances in agri-blockchain systems
  • Industry: improved transparency and market access
  • Policy: supports regulatory compliance

1.7 Scope and Limitations

Scope includes system design, prototype development, and pilot testing. Limitations include scalability constraints and simulated data environments.

CHAPTER 2: REVIEW OF RELATED LITERATURE

2.1 Blockchain in Supply Chains

Explores decentralized ledgers, consensus mechanisms, and applications in traceability.

2.2 Agricultural Traceability Systems

Discusses existing systems and their limitations.

2.3 Artificial Intelligence in Agriculture

Covers predictive analytics, anomaly detection, and decision support systems.

2.4 Sustainability and Carbon Markets

Examines carbon accounting, ESG frameworks, and credit certification.

2.5 Research Gap

Current systems lack integration of blockchain, AI, and sustainability into a unified platform.

CHAPTER 3: RESEARCH METHODOLOGY

3.1 Research Design

Design Science Research (DSR) combined with quantitative evaluation.

3.2 System Architecture

  • User Layer
  • Application Layer
  • AI Analytics Layer
  • Blockchain Layer
  • Data Layer

3.3 Development Approach

Agile iterative development with prototyping cycles.

3.4 Data Collection

  • Surveys
  • Interviews
  • System logs

3.5 Evaluation Methods

  • Usability testing (SUS)
  • Performance benchmarking
  • Statistical analysis (t-test, regression)

CHAPTER 4: SYSTEM DESIGN AND IMPLEMENTATION

4.1 System Overview

AgriTrace™ integrates multiple modules into a unified platform.

4.2 Modules

  • Registration
  • Data Capture
  • Batch Processing
  • Blockchain Verification
  • QR Authentication
  • Sustainability Tracking

4.3 AI Components

  • Anomaly detection
  • Predictive analytics

4.4 Implementation Tools

  • Frontend: React
  • Backend: Node.js
  • Blockchain: Hyperledger/Ethereum
  • Database: SQL/NoSQL

CHAPTER 5: RESULTS AND DISCUSSION

5.1 System Testing

Performance, usability, and security results.

5.2 Data Analysis

Statistical validation of hypotheses.

5.3 Discussion

Interpretation of findings and implications.

CHAPTER 6: CONCLUSIONS AND RECOMMENDATIONS

6.1 Conclusions

AgriTrace™ demonstrates the viability of blockchain-based traceability systems.

6.2 Recommendations

  • Scale deployment
  • Integrate IoT
  • Expand carbon credit systems

CONTRIBUTIONS OF THE STUDY

  • Novel integrated framework
  • AI-enhanced blockchain traceability
  • ESG and carbon integration model

TIMELINE (3–4 YEARS)

Year 1: Literature & proposal
Year 2: System development
Year 3: Testing & data collection
Year 4: Writing & defense

REFERENCES

(To be developed in APA/Scopus-indexed sources)