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Dirk Draheim

and 3 more

Our aim is to understand technological and socio-economic barriers to blockchain solutions that are intrinsic in the blockchain technology stack itself (permissionless as well as permissioned). On the basis of that, we want to understand the future potentioal impact of blockchain technology. We provide an argumentation against the theoretical background of Williamson’s instutional analysis framework, and triangulate the insights with results from four design science research efforts. We (i) characterize cryptocurrency as one-tiered collateralized money. We (ii) review potential blockchain solutions against defined essential modes of communications. We review (iii) well-known scalability issues and potential denial-of-service attacks through a new probabilistic model. We (iv) characterize a typical neglection of physical network infrastructure in blockchain technology discussions. We (v) describe four successful blockchain solutions and explain their design. There is (vi) no evidence that the proclaimed “blockchain revolution” can disrupt our institutional stack; instead, it can only happen in the boundaries of the current institutional stack. Nevertheless, it is possible to (vii) design useful blockchain solutions. The findings of this research enable policy makers, decision makers and information systems architects alike to make informed decisions about blockchain technology and its application. Given its theoretic foundation in new institutional economics, triangulated with comprehensive results from design science efforts, this study is the first of its kind in the area of blockchain technology research.

Dirk Draheim

and 3 more

The Web3 vision takes blockchain disintermediation to a next level by making it ubiquitous, encompassing not only payments and financial services but also digital identities, data and business models. Recently, Web3 has gained massive attention by major analysts such as Gartner, Forrester, Forbes Technology Council and the Harvard Business Review. Albeit the current enthusiasm about Web3, we are lost in a state of confusion about what Web3 actually is - or could be. The purpose of this paper is to mitigate the gap between the perceived usefulness of Web3 and its potential implementation. We take a descriptive design science approach. We provide informed arguments for a potential foundation of Web3 in terms of fundamental components,  architectural principles and a Web3 design space. We demonstrate the usefulness of the provided Web3 foundation by describing Alphabill, a platform that allows for universal asset tokenization and transfer as a global medium of exchange. The findings of this research enable policy makers, decision makers and information systems architects alike to make informed decisions about Web3 and its potential implementation as follows: (i) The Web3 can be characterized as the integration of digital rights exchange into the (application layer) internet protocols. (ii) The Web3 has the potential to revolutionize today’s information systems’s landscape by turning today’s information systems into deeply standardized views on a huge, single underlying information structure. The killer application of a well-founded Web3 is the Web3 itself – being the currently missing backbone (value-added middleware) for all of today’s and future enterprise applications and business-to-business communication. (iii) The scenario-based evaluation of the provided Web3 foundation reveals the described Alphabill platform as a Web3 enabling technology.

Ahto Buldas

and 9 more

Since its introduction with Bitcoin in 2009, blockchain technology has received tremendous attention by academia, industry, politics and media alike, in particular, through extended blockchain-based visions such as smart contracts, decentralized finance, and, most recently, Web3. The critical prerequisite for any such blockchain-based vision to be turned into reality is uncapped scalability. Furthermore, and equally important, blockchain technology needs to transcend the stage of specialized tokens into an adaptive, heterogeneous tokenization platform. In this paper, we explain the Alphabill family of technologies that addresses both unlimited scalability and unrestricted adaptivity. We deliver a sharded blockchain technology with unlimited scalability and performance, called KSI Cash, which is based on a new form of electronic money scheme, the bill scheme. We present performance tests of KSI Cash that we have conducted with the European Central Bank and a group of eight national central banks from the Eurosystem in order to assess the technological feasibility of a digital euro, showing the system operating with 100 million wallets and 15 thousand transactions per second (under simulation of realistic usage), having an estimated carbon footprint of 0.0001g CO2 per transaction (Bitcoin = 100 kg and more); furthermore, showing the system operating with up to 2 million payment orders per second, an equivalent of more than 300.000 transactions per second (in a laboratory setting with the central components of KSI Cash), scaling linearly in terms of the number of deployed shards.  We explain, in detail, the key concepts that unlock this performance (i.e., the concepts of the bill money scheme). The results provide evidence that the scalability of our technology is unlimited in both permissioned and permissionless scenarios, resulting into the Alphabill Money technology. Next, we contribute the architecture of a universal tokenization platform that allows for universal asset tokenization, transfer and exchange as a global medium of exchange,  called Alphabill platform. We reveal the crucial conceptual and technical contributions of the platform’s architecture and their interplay, including the data structures of KSI Cash and Alphabill Money, the dust collection solution of Alphabill Money, and the  atomic swap solution of the Alphabill platform.