Tallinn University of Technology (Estonia)|Wismar Business School|Wismar University (Germany)
Tallinn University of Technology (Estonia).
The access to common-pool resources, i.e. to resources in limited common property, are legally distributed in a far more diverse way than limited private property resources. In transportation, a critical case for common-pool resources appear in Green Transport Corridors (GTC), that has been coined by European Union as being «sustainable logistics solutions for cargo transportation’ with a shared pool of resources aiming for multimodal trans-shipment routes with a concentration of freight traffic between significant hubs». Although there are already existing implementations of GTC concepts, there are still a lot of open questions concerning GTC governance and ownership models hindering easy marketing of the GTC approach. This paper discusses how and to which extent smart contracts in combination with blockchain technology as innovative solutions are able to facilitate GTC governance and how smart contracts can be applied to provide legal certainty by managing and allocating distributed access to common-pool resources. Smart contracts can be considered as computerised transaction protocols for the execution of underlying legal contracts, and they do not only target reducing transaction costs by realising trackable and irreversible transactions through blockchain technology for distributed databases, but also show high potential to strengthen cooperative business structures and to facilitate the entrepreneurial collaboration of cross-organisational business processes. From a legal perspective, it is controversial whether the use of smart contracts to distribute access to resources in terms of both general common-pool resources. GTCs implies an added value automatically for legal certainty and fair balance among different forms and degrees of access granted to different members of the cooperative. In cases of incorrect performance, change of circumstances or unduly induced contracts smart contracts fall considerably short on the protection of weaker parties, which the paper illustrates at the example of GTCs to be a decisive detriment of the cooperative members. The paper analyses these potentials and risks of smart contracts for the case of GTCs and showcases from both business and legal perspective in terms of their potential as viable means of distributing access to common-pool resources comprising infrastructure.
Keywords: common-pool resources, cooperative governance, blockchain, smart contracts, Green Transport Corridors.
JEL Classification: M1, M2, K4.
Cite as: Prause, G., Hoffmann., T. (2020). Innovative Management of Common-Pool Resources by Smart Contracts. Marketing and Management of Innovations, 1, 265-273. https://doi.org/10.21272/mmi.2020.1-22
This work is licensed under a Creative Commons Attribution 4.0 International License
- COM. (2007). Communication from the Commission: Freight Transport Logistics Action Plan. Commission of European Communities. Brussels, 18.10.2007. Retrieved from http://aei.pitt.edu/96122/1/COM_(2007)_607_final.pdf
- COM. (2011). Roadmap to a Single European Transport Area – Towards a competitive and resource efficient transport system. Commission of European Communities. Brussels, 28.03.2011. Retrieved from https://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=COM:2011:0144:FIN:EN:PDF
- De Filippi, P., & Wright, A. (2019). Blockchain and the Law. The Rule of Code, Harvard University Press, ISBN 9780674241596
- EWTC 2. (2012). Green Corridor Manual–Task 3B of the EWTC II project. Femern (2019). Retrieved from https://femern.com/en
- Hoffmann, T. (2019a). Smart Contracts and Void Declarations of Intent. Cappiello, C.; Ruiz Carmona, M. (Ed.). Information Systems Engineering in Responsible Information Systems (168−175). Heidelberg: Springer International Publishing. [CrossRef]
- Hoffmann, T., & Prause, G. (2018). On the regulatory framework for last-mile delivery robots. Machines, 6(3) (33). [Google Scholar] [CrossRef]
- Hoffmann, T., & Skwarek, V. (2019b). Blockchain, Smart Contracts und Recht Smart Contracts als Risiko für Informatiker. Informatik Spektrum, 42 (3), 197−204. [Google Scholar] [CrossRef]
- Hofmann, E., Strewe, U., & Bosia, N. (2018). Supply Chain Finance and Blockchain Technology, Springer. [Google Scholar]
- Hunke, K., & Prause, G. (2013). Management of green corridor performance. Transport and Telecommunication, 14(4), 292-299. [Google Scholar] [CrossRef]
- Jacobs, F. R., Chase, R. B. (2014). Operations and Supply Chain Management (14th edition). New York, NY McGrawHill. [Google Scholoar]
- Mannan, M. (2018). Fostering Worker Cooperatives with Blockchain Technology: Lessons from the Colony Project. Erasmus L. Review, 3, 190. [Google Scholar] [CrossRef]
- Metzger, A., Neubauer, A., Bohn, P., & Pohl, K. (2019). proactive process adaptation using deep learning ensembles. In: Giorgini, P.; & Weber, B., (eds), 31st Int’l Conference on Advanced Information Systems Engineering (CAiSE 2019), Rome, Springer.
- Norta, A. (2016, November). Designing a smart-contract application layer for transacting decentralised autonomous organisations. In International Conference on Advances in Computing and Data Sciences (pp. 595-604). Springer, Singapore. [Google Scholar]
- Norta, A., Grefen, P., & Narendra, NC. (2014). A reference architecture for managing dynamic inter-organisational business processes. Data & Knowledge Engineering, 91, 52-89. [Google Scholar][CrossRef]
- Norta, A., Ma, L., Duan, Y., Rull, A., Kolvart, M., & Taveter, K. (2015). eContractual choreography-language properties towards cross-organisational business collaboration. Journal of Internet Services and Applications, 6(1), 8. [Google Scholar] [CrossRef]
- Olaniyi, EO, & Reidolf, M. (2015). Organisational innovation strategies in the context of smart specialisation. Journal Security and Sustainability Issues, 5. [Google Scholar]
- Osterwalder, A. (2004). The business model ontology a proposition in a design science approach (Doctoral dissertation, Universite de Lausanne, Faculte des hautes etudes commerciales). [Google Scholar]
- Ostrom, E. (1990). Governing the commons: The evolution of institutions for collective action, Cambridge university press. [Google Scholar]
- Ostrom, E. (2009). A general framework for analysing sustainability of social-ecological systems. Science, 325(5939), 419-422. [Google Scholar] [CrossRef]
- Philipp, R., Prause, G., & Gerlitz, L. (2019). Blockchain and Smart Contracts for Entrepreneurial Collaboration in Maritime Supply Chains. Transport and Telecommunication Journal, 20(4), 365−378. [Google Scholar] [CrossRef]
- Prause, G., & Boevsky, I. (2019). Smart contracts for smart rural supply chains. Bulgarian Journal of Agricultural Science, 25(3), 454−463. [Google Scholar]
- Prause, G., & Hoffmann, T. (2017). Cooperative Business Structures for Green Transport Corridors. Baltic Journal of European Studies, 7(2), 3–27. [Google Scholar]
- Prokopenko, O., Omelyanenko, V., & Tirto, T. (2019). Security issues of system innovation strategies. In Web of Conferences (Vol. 65, p. 03006). EDP Sciences. [Google Scholar] [CrossRef]
- Szabo, N. (1997). Formalising and securing relationships on public networks. First Monday 2(9). [Google Scholar]
- Udokwu, C., Kormiltsyny, A., Thangalimodziz, K., & Norta, A. (2018). The state of the art for blockchain-enabled smart-contract applications in the organisation.In 2018 Ivannikov Ispras Open Conference (ISPRAS) (pp. 137-144). IEEE. [Google Scholar] [CrossRef]