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Electronic Commerce Research

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27.04.2023

Securing blockchain-based crowdfunding platforms: an integrated graph neural networks and machine learning approach

verfasst von: Karim Zkik, Anass Sebbar, Oumaima Fadi, Sachin Kamble, Amine Belhadi

Erschienen in: Electronic Commerce Research | Ausgabe 1/2024

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Abstract

Blockchain-based crowdfunding is a form of crowdfunding that uses blockchain technology to facilitate the fundraising process. Blockchain technology provides a decentralized, transparent, and secure platform for crowdfunding by allowing the creation of smart contracts and the issuance of digital tokens. However, Blockchain-based crowdfunding systems suffer from a few security issues, such as the possibility of fraud, risk assessment, smart contracts bugs, and cyber-attacks. This paper proposes integrating artificial intelligence models to prevent smart contract vulnerabilities and anomaly detection. Thus, we will deploy Graph Neural Networks models to protect Blockchain-based crowdfunding platforms from smart contracts-based attacks such as reentrancy and infinite loop attacks. Then, we will use a machine learning model for anomaly detection and prevent attacks such as advanced persistent threats, malware, and distributed denial of service attacks. An experimental study is conducted in a real crowdfunding platform to prove the feasibility of our framework and to draw lessons from the real-life implementation of such models. Our results show that our approach can accurately identify both normal and abnormal traffic and classify correctly specific types of attacks. We also evaluate the performance of our framework using various evaluation metrics to ensure its effectiveness in detecting anomalies.

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Moritz, A., & Block, J. H. (2016). Crowdfunding: A literature review and research directions. Crowdfunding in Europe (pp. 25–53). Springer.CrossRef

Frydrych, D., Bock, A. J., Kinder, T., & Koeck, B. (2014). Exploring entrepreneurial legitimacy in reward-based crowdfunding. Venture capital, 16(3), 247–269.CrossRef

Mochkabadi, K., & Volkmann, C. K. (2020). Equity crowdfunding: A systematic review of the literature. Small Business Economics, 54(1), 75–118.CrossRef

Salido-Andres, N., Rey-Garcia, M., Alvarez-Gonzalez, L. I., & Vazquez-Casielles, R. (2021). Mapping the field of donation-based crowdfunding for charitable causes: systematic review and conceptual framework. VOLUNTAS: International Journal of Voluntary and Nonprofit Organizations, 32(2), 288–302.CrossRef

Montgomery, N., Squires, G., & Syed, I. (2018). Disruptive potential of real estate crowdfunding in the real estate project finance industry: A literature review. Property Management.

Zhao, Y., Harris, P., & Lam, W. (2019). Crowdfunding industry—History, development, policies, and potential issues. Journal of Public Affairs, 19(1), e1921.CrossRef

Cumming, D., Meoli, M., & Vismara, S. (2021). Does equity crowdfunding democratize entrepreneurial finance? Small Business Economics, 56(2), 533–552.CrossRef

Mollick, E., & Robb, A. (2016). Democratizing innovation and capital access: The role of crowdfunding. California management review, 58(2), 72–87.CrossRef

Belhadi, A., Kamble, S., Benkhati, I., Gupta, S., & Mangla, S. K. (2023). Does strategic management of digital technologies influence electronic word-of-mouth (eWOM) and customer loyalty? Empirical insights from B2B platform economy. Journal of Business Research, 156, 113548.CrossRef

10.

Madsen, J. M., & McMullin, J. L. (2020). Economic consequences of risk disclosures: Evidence from crowdfunding. The Accounting Review, 95(4), 331–363.CrossRef

11.

Yeon, A. L., Yaacob, N., Hussain, M. A., & Ismail, C. T. M. (2022). Equity Crowdfunding Vs Cybercrime: A Legal Protection. BiLD Law Journal, 7(1), 139–150.

12.

Wasiuzzaman, S., Chong, L. L., & Ong, H. B. (2021). Influence of perceived risks on the decision to invest in equity crowdfunding: A study of Malaysian investors. Journal of Entrepreneurship in Emerging Economies., 14(2), 208–230.CrossRef

13.

Andryukhin, A. A. (2019). Phishing attacks and preventions in Blockchain based projects. In 2019 International Conference on Engineering Technologies and Computer Science (EnT) (pp. 15–19). IEEE.

14.

Brabham, D. C. (2017). How crowdfunding discourse threatens public arts. New Media and Society, 19(7), 983–999.CrossRef

15.

Hartmann, F., Grottolo, G., Wang, X., & Lunesu, M. I. (2019). Alternative fundraising: success factors for blockchain-based vs. conventional crowdfunding. In 2019 IEEE international workshop on Blockchain oriented software engineering (IWBOSE) (pp. 38–43). IEEE.

16.

Baber, H. (2020). Blockchain-based crowdfunding. Blockchain technology for industry 4.0 (pp. 117–130). Singapore: Springer.CrossRef

17.

Nguyen, L. T., Hoang, T. G., Do, L. H., Ngo, X. T., Nguyen, P. H., Nguyen, G. D., & Nguyen, G. N. (2021). The role of Blockchain technology-based social crowdfunding in advancing social value creation. Technological Forecasting and Social Change, 170, 120898.CrossRef

18.

Kamble, S. S., Gunasekaran, A., Subramanian, N., Ghadge, A., Belhadi, A., & Venkatesh, M. (2021). Blockchain technology's impact on supply chain integration and sustainable supply chain performance: Evidence from the automotive industry. Annals of Operations Research, 1–26.

19.

Bogusz, C. I., Laurell, C., & Sandström, C. (2020). Tracking the digital evolution of entrepreneurial finance: The interplay between crowdfunding, blockchain technologies, cryptocurrencies, and initial coin offerings. IEEE Transactions on Engineering Management, 67(4), 1099–1108.CrossRef

20.

Saad, M., Spaulding, J., Njilla, L., Kamhoua, C., Shetty, S., Nyang, D., & Mohaisen, D. (2020). Exploring the attack surface of Blockchain: A comprehensive survey. IEEE Communications Surveys and Tutorials, 22(3), 1977–2008.CrossRef

21.

Aggarwal, S., & Kumar, N. (2021). Attacks on blockchain. Advances in Computers (Vol. 121, pp. 399–410). Elsevier.

22.

Siddiqui, S. T., Ahmad, R., Shuaib, M., & Alam, S. (2020). Blockchain security threats, attacks and countermeasures. Ambient communications and computer systems (pp. 51–62). Springer.CrossRef

23.

Fadi, O., Karim, Z., & Mohammed, B. (2022). A survey on Blockchain and Artificial intelligence technologies for enhancing security and privacy in smart environments. IEEE Access, 10, 93168–93186.CrossRef

24.

Asongu, S. A., & De Moor, L. (2015). Recent advances in finance for inclusive development: A survey.

25.

Zhou, S., Ma, T., & Liu, Z. (2021). Crowdfunding as a screener for collective investment. Electronic Commerce Research, 21(1), 195–221.CrossRef

26.

Rijanto, A. (2018). Donation-based crowdfunding as corporate social responsibility activities and financing. Journal of General Management, 43(2), 79–88.CrossRef

27.

Shneor, R., & Munim, Z. H. (2019). Reward crowdfunding contribution as planned behaviour: An extended framework. Journal of Business Research, 103, 56–70.CrossRef

28.

De Buysere, K., Gajda, O., Kleverlaan, R., Marom, D., & Klaes, M. (2012). A framework for European crowdfunding.

29.

Slimane, F. B., & Rousseau, A. (2020). Crowdlending campaigns for renewable energy: Success factors. Journal of Cleaner Production, 249, 119330.CrossRef

30.

Ramos, J., & Stewart, J. (2014). Crowdfunding and the role of managers in ensuring the sustainability of crowdfunding platforms. JRC Scientific and Policy Reports, 85752.

31.

Huang, A. (2018). A risk detection system of e-commerce: Researches based on soft information extracted by affective computing web texts. Electronic Commerce Research, 18(1), 143–157.CrossRef

32.

Kleist, V. F. (2004). A transaction cost model of electronic trust: Transactional return, incentives for network security and optimal risk in the digital economy. Electronic Commerce Research, 4(1), 41–57.CrossRef

33.

Oudani, M., Sebbar, A., Zkik, K., El Harraki, I., & Belhadi, A. (2023). Green Blockchain based IoT for secured supply chain of hazardous materials. Computers and Industrial Engineering, 175, 108814.CrossRef

34.

Jain, G., Kamble, S. S., Ndubisi, N. O., Shrivastava, A., Belhadi, A., & Venkatesh, M. (2022). Antecedents of Blockchain-Enabled E-commerce Platforms (BEEP) adoption by customers–A study of second-hand small and medium apparel retailers. Journal of Business Research, 149, 576–588.CrossRef

35.

Rashid, M. A., Deo, K., Prasad, D., Singh, K., Chand, S., & Assaf, M. (2020). TEduChain: A blockchain-based platform for crowdfunding tertiary education. The Knowledge Engineering Review, 35, e27.CrossRef

36.

Ajienka, N., Vangorp, P., & Capiluppi, A. (2020). An empirical analysis of source code metrics and smart contract resource consumption. Journal of Software: Evolution and Process, 32(10), e2267.

37.

Schär, F. (2021). Decentralized finance: On blockchain-and smart contract-based financial markets. FRB of St. Louis Review.

38.

Verma, S., & Sheel, A. (2022). Blockchain for government organizations: Past, present and future. Journal of Global Operations and Strategic Sourcing, 15(3), 406–430.CrossRef

39.

Liu, N., Lin, J., Guo, S., & Shi, X. (2022). Fashion platform operations in the sharing economy with digital technologies: recent development and real case studies. Annals of Operations Research, 1–21.

40.

Kolade, O., Adepoju, D., & Adegbile, A. (2022). Blockchains and the disruption of the sharing economy value chains. Strategic Change, 31(1), 137–145.CrossRef

41.

Zhu, H., & Zhou, Z. Z. (2016). Analysis and outlook of applications of blockchain technology to equity crowdfunding in China. Financial innovation, 2(1), 1–11.CrossRef

42.

Yadav, N., & Sarasvathi, V. (2020). Venturing crowdfunding using smart contracts in Blockchain. In 2020 Third International Conference on Smart Systems and Inventive Technology (ICSSIT) (pp. 192–197). IEEE.

43.

Gada, S., Dhuri, A., Jain, D., Bansod, S., & Toradmalle, D. (2021). Blockchain-based crowdfunding: A trust building MODEL. In 2021 International conference on artificial intelligence and machine vision (AIMV) (pp. 1–7). IEEE.

44.

Madaan, L., Jindal, D., Kumar, A., Kumar, S., & Naruka, M. S. (2022). Secure and enhanced crowdfunding solution using blockchain technology. Transforming management with AI, big-data, and IoT (pp. 293–310). Springer.CrossRef

45.

Kaur, J., Kumar, S., Narkhede, B. E., Dabić, M., Rathore, A. P. S., & Joshi, R. (2022). Barriers to blockchain adoption for supply chain finance: The case of Indian SMEs. Electronic Commerce Research, 1–38.

46.

Zkik, K., Belhadi, A., Rehman Khan, S. A., Kamble, S. S., Oudani, M., & Touriki, F. E. (2022). Exploration of barriers and enablers of blockchain adoption for sustainable performance: implications for e-enabled agriculture supply chains. International Journal of Logistics Research and Applications, 1–38.

47.

Cai, C. W. (2018). Disruption of financial intermediation by FinTech: A review on crowdfunding and Blockchain. Accounting and Finance, 58(4), 965–992.CrossRef

48.

Yadav, S. P., Agrawal, K. K., Bhati, B. S., Al-Turjman, F., & Mostarda, L. (2020). Blockchain-based cryptocurrency regulation: An overview. Computational Economics, 59(4), 1659–1675.CrossRef

49.

Hasanova, H., Baek, U. J., Shin, M. G., Cho, K., & Kim, M. S. (2019). A survey on blockchain cybersecurity vulnerabilities and possible countermeasures. International Journal of Network Management, 29(2), e2060.CrossRef

50.

Hirai, Y. (2017). Defining the ethereum virtual machine for interactive theorem provers. International conference on financial cryptography and data security (pp. 520–535). Springer.CrossRef

51.

Liu, C., Liu, H., Cao, Z., Chen, Z., Chen, B., & Roscoe, B. (2018). Reguard: finding reentrancy bugs in smart contracts. In 2018 IEEE/ACM 40th International Conference on Software Engineering: Companion (ICSE-Companion) (pp. 65–68). IEEE.

52.

Rodler, M., Li, W., Karame, G. O., & Davi, L. (2018). Sereum: Protecting existing smart contracts against re-entrancy attacks. arXiv preprint arXiv:1812.05934.

53.

Shafqat, W., Byun, Y. C., & Park, N. (2020). Effectiveness of machine learning approaches towards credibility assessment of crowdfunding projects for reliable recommendations. Applied Sciences, 10(24), 9062.CrossRef

54.

Wang, W., Zheng, H., & Wu, Y. J. (2020). Prediction of fundraising outcomes for crowdfunding projects based on deep learning: A multimodel comparative study. Soft Computing, 24(11), 8323–8341.CrossRef

55.

Yeh, J. Y., & Chen, C. H. (2020). A machine learning approach to predict the success of crowdfunding fintech project. Journal of Enterprise Information Management.

56.

Smith, R., & Shao, J. (2007). Privacy and e-commerce: A consumer-centric perspective. Electronic Commerce Research, 7(2), 89–116.CrossRef

57.

Yu, P. F., Huang, F. M., Yang, C., Liu, Y. H., Li, Z. Y., & Tsai, C. H. (2018). Prediction of crowdfunding project success with deep learning. In 2018 IEEE 15th international conference on e-business engineering (ICEBE) (pp. 1–8). IEEE.

58.

Qian, P., Liu, Z., He, Q., Zimmermann, R., & Wang, X. (2020). Towards automated reentrancy detection for smart contracts based on sequential models. IEEE Access, 8, 19685–19695.CrossRef

59.

Liu, Z., Qian, P., Wang, X., Zhuang, Y., Qiu, L., & Wang, X. (2021). Combining graph neural networks with expert knowledge for smart contract vulnerability detection. IEEE Transactions on Knowledge and Data Engineering.

60.

Liang, H., Zhu, L., Yu, F. R., & Wang, X. (2022). A cross-layer defense method for blockchain empowered CBTC systems against data tampering attacks. IEEE Transactions on Intelligent Transportation Systems.

61.

Kumar, R., Kumar, P., Tripathi, R., Gupta, G. P., Garg, S., & Hassan, M. M. (2022). A distributed intrusion detection system to detect DDoS attacks in blockchain-enabled IoT network. Journal of Parallel and Distributed Computing, 164, 55–68.CrossRef

62.

Altarawneh, A., & Skjellum, A. (2020). The security ingredients for correct and byzantine fault-tolerant blockchain consensus algorithms. In 2020 International symposium on networks, computers and communications (ISNCC) (pp. 1–9). IEEE.

63.

Akbar, N. A., Muneer, A., ElHakim, N., & Fati, S. M. (2021). Distributed Hybrid Double-Spending Attack Prevention Mechanism for Proof-of-Work and Proof-of-Stake Blockchain Consensuses. Future Internet, 13(11), 285.CrossRef

64.

Rahman, Z., Yi, X., & Khalil, I. (2022). Blockchain based AI-enabled industry 4.0 CPS protection against advanced persistent threat. IEEE Internet of Things Journal.

65.

Kamboj, P., Khare, S., & Pal, S. (2021). User authentication using Blockchain based smart contract in role-based access control. Peer-to-Peer Networking and Applications, 14(5), 2961–2976.CrossRef

66.

Kumar, R., Zhang, X., Wang, W., Khan, R. U., Kumar, J., & Sharif, A. (2019). A multimodal malware detection technique for Android IoT devices using various features. IEEE access, 7, 64411–64430.CrossRef

67.

Asif, M., Aziz, Z., Bin Ahmad, M., Khalid, A., Waris, H. A., & Gilani, A. (2022). Blockchain-based authentication and trust management mechanism for smart cities. Sensors, 22(7), 2604.CrossRef

68.

Hjálmarsson, F. Þ., Hreiðarsson, G. K., Hamdaqa, M., & Hjálmtýsson, G. (2018, July). Blockchain-based e-voting system. In 2018 IEEE 11th international conference on cloud computing (CLOUD) (pp. 983–986). IEEE.

69.

Kamble, S. S., Gunasekaran, A., Kumar, V., Belhadi, A., & Foropon, C. (2021). A machine learning based approach for predicting blockchain adoption in supply Chain. Technological Forecasting and Social Change, 163, 120465.CrossRef

70.

Kipf, T. N., & Welling, M. (2016). Semi-supervised classification with graph convolutional networks. arXiv preprint arXiv:1609.02907.

71.

Xu, K., Hu, W., Leskovec, J., & Jegelka, S. (2018). How powerful are graph neural networks?. arXiv preprint arXiv:1810.00826.

72.

Brody, S., Alon, U., & Yahav, E. (2021). How attentive are graph attention networks?. arXiv preprint arXiv:2105.14491.

73.

Schapire, R. E. (2013). Explaining adaboost. Empirical inference (pp. 37–52). Springer.CrossRef

74.

Chen, T., He, T., Benesty, M., Khotilovich, V., Tang, Y., Cho, H., & Chen, K. (2015). Xgboost: Extreme gradient boosting. R Package Version 0.4-2, 1(4), 1–4.

75.

Biau, G., & Scornet, E. (2016). A random forest guided tour. TEST, 25(2), 197–227.CrossRef

76.

Chen, X. W., & Jeong, J. C. (2007, December). Enhanced recursive feature elimination. In Sixth International Conference on Machine Learning and Applications (ICMLA 2007) (pp. 429–435). IEEE.

77.

Liu, Z., Qian, P., Wang, X., Zhu, L., He, Q., & Ji, S. (2021). Smart contract vulnerability detection: from pure neural network to interpretable graph feature and expert pattern fusion. arXiv preprint arXiv:2106.09282.

Titel: Securing blockchain-based crowdfunding platforms: an integrated graph neural networks and machine learning approach
verfasst von: Karim Zkik
Anass Sebbar
Oumaima Fadi
Sachin Kamble
Amine Belhadi
Publikationsdatum: 27.04.2023
Verlag: Springer US
Erschienen in: Electronic Commerce Research / Ausgabe 1/2024
Print ISSN: 1389-5753
Elektronische ISSN: 1572-9362
DOI: https://doi.org/10.1007/s10660-023-09702-8

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