Blockchain Integration in the Era of Industrial Metaverse
Abstract
:1. Introduction
- Significant technical challenges still need to be addressed:
- ○
- Cybersecurity issues;
- ○
- Energy consumption of blockchain;
- ○
- Interoperability.
- Regulatory challenges protecting human rights:
- ○
- Privacy issues;
- ○
- Web 3.0’s copyright promises to support the creator economy by ensuring the fair use of assets;
- ○
- Enforceability of regulatory frameworks.
- Economic challenges for a successful metaverse:
- ○
- Stability of tokens, currencies, and blockchain systems;
- ○
- The high concentration of financial players and institutions in the metaverse.
- Ethical challenges for a human-centric metaverse:
- ○
- What ethical standards and limitations will govern this new cyber-physical metaverse, where identity will be a fluid concept and regulatory oversight will be weak?
- 5G technology opportunities:
- ○
- Immersion;
- ○
- Immediacy;
- ○
- Consistency.
- Blockchain-as-a-service and application programming interface (API) opportunities.
2. Historical Evolution of the Blockchain
2.1. Blockchain 1.0
- Enhanced network reliability is achieved by masking the identity of users or organizations, thus increasing the privacy of users.
- Transparent communication between the network participants is possible as long as the users satisfy the conditions of the consensus mechanism.
- Operation costs are reduced due to the use of a decentralized and distributed network versus the higher cost of conventional systems.
- For the validation of transactions, miners are obliged to work simultaneously in order to solve a cryptographic puzzle and adhere to the principles of the Proof of Work (PoW) consensus mechanism. By extension, multiple computing resources and increased computational time are required. Therefore, PoW is not efficient enough.
- Due to the increased computational time and computational resources required, delays in the execution of transactions are induced in the system, which leads to a less-than-optimal user experience.
- Security risks are still present, as there might be corrupt miners within the network who try to corrupt the ledger in an attempt to extract additional revenue/rewards.
2.2. Blockchain 2.0
- The addition of Ethereum to Blockchain 2.0 has extended its usability for financial organizations as a result of its enhanced security and privacy.
- The level of transparency in the communication between users has been enhanced by the integration of smart contracts.
- By integrating smart contracts, an increased data rate for digital transactions can be achieved.
2.3. Blockchain 3.0
2.3.1. Proof of Work (PoW)
2.3.2. Proof of Stake (PoS)
2.3.3. Delegated Proof of Stake (DPoS)
2.3.4. Proof of Activity (PoA)
2.3.5. Proof of Authority (PoA)
2.3.6. Proof of Burn (PoB)
2.3.7. Proof of Capacity/Proof of Space (PoC/PoSpace)
2.3.8. Proof of Elapsed Time (PoET)
2.3.9. Proof of History (PoH)
2.3.10. Proof of Importance (PoI)
2.4. Blockchain 4.0
3. Beyond the Current Implementations—Blockchain 5.0
- User digital transactions are stored in a single system in order to ensure data confidentiality for information related to health care or governance.
- Features of advanced digital technologies, such as AI, are exploited for the creation of secure and reliable smart contracts in the network.
- Improvement of industrial performance with the implementation of complex projects with Blockchain 5.0.
3.1. Blockchain and Education
- Reduction of costly academic bureaucracy;
- Laggs in technology adoption;
- Democratization and automation of higher education.
3.2. Blockchain and Digital Twin
3.3. Data Management and Cybersecurity
4. Blockchain in the Era of Society 5.0
5. Blockchain Integration in Metaverse
- Investing in financial products and services now has a lower barrier to entry.
- Assisting individuals in monetizing their work and experiences (such as gaming) in order to compensate for income losses due to inflation and the pandemic.
- Reducing costs and increasing transaction efficiency by eliminating middlemen in procedures such as money transfers.
- Creating interest from a diverse range of demographic groups outside of the traditional financial sector and presenting novel concepts and opportunities.
- Managing community-involved and connected projects.
5.1. Technical Framework for the Blockchain in Metaverse
5.1.1. Data Acquisition
Challenges of Data Acquisition in the Metaverse
Blockchain Contribution
Challenge/Limitation
5.1.2. Data Storage
Challenges of Data Storage in the Metaverse
Blockchain Contribution
Challenge/Limitation
5.1.3. Data Sharing
Challenges of Data Sharing in the Metaverse
Blockchain Contribution
Challenge/Limitation
5.1.4. Data Interoperability
Challenges of Data Interoperability in Metaverse
Blockchain Contribution
Challenge/Limitation
5.1.5. Data Privacy Preservation
Privacy Preservation in the Metaverse and the Corresponding Challenges
Blockchain Contribution
Challenge/Limitation
5.2. Blockchain Case Studies in Metaverse
5.3. Regulatory Challenges Protecting Human Rights in Metaverse
- (1)
- Privacy regulations;
- (2)
- Copyright laws and regulations;
- (3)
- Mechanisms to enforce regulatory regimes.
5.4. Comparison of Current Paper Versus the State of Knowledge
6. Concluding Remarks and Outlook
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Nomenclature
AI | Artificial Intelligence |
AR | Augmented Reality |
DApps | Digital Applications |
DLT | Digital Ledger Technology |
DOS | Denial Of Service |
DPoS | Delegated Proof of Stake |
HCI | Human-Computer Interaction |
HEI | Higher Education |
IoT | Internet of things |
NFT | Non-Fungible Token |
NSA | National Security Agency |
PII | Personally Identifiable Information |
PoA | Proof of Activity |
PoA | Proof of Authority |
PoB | Proof of Burn |
PoC | Proof of Capability |
PoET | Proof of Elapsed Time |
PoH | Proof of History |
PoI | Proof of Importance |
PoS | Proof of Stake |
PoSpace | Proof of Space |
PoW | Proof of Work |
RSA | Rivest Shamir Adleman |
SDG | Sustainable Development Goals |
SGX | Software Guard Extensions |
SHA | Secure Hash Algorithm |
VR | Virtual Reality |
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Parameter | Traditional Contract | Smart Contract |
---|---|---|
Documents required | Several legal documents required | None |
Transaction settlement time | Several hours | ≤60 s |
Availability | Time-consuming | Easily and readily available |
Processing method | Manual | Automatic |
Security | Limited | Cryptographic security |
Transaction cost | Expensive | Virtually free |
Signature | Manual | Digital |
Operation mode | Manual | Automatically triggered |
Parameter | Blockchain 1.0 | Blockchain 2.0 | Blockchain 3.0 | Blockchain 4.0 |
---|---|---|---|---|
Underlying technology | Distributed ledger technology (DLT) | Smart contracts | Decentralized Applications (DApps) | Blockchain with AI |
Consensus mechanism | Proof of Work | Delegated Proof of Work | Proof of Stake, Proof of Authority | Proof of Integrity |
Validation | By miners | Through smart contracts and miners | In-built verification mechanism via DApps | Automated verification via sharing |
Scalability | Non-scalable | Poorly scalable | Scalable | Highly scalable |
Intercommunication | Not possible | Not possible | Possible | Possible |
Data rate | 7 TBS | 15 TBS | 1000 s of TBS | 106 TBS |
Cost | Expensive | Cheaper | More cheaper | Cost effective |
Energy consumption | Highest | Moderate | Energy efficient | Highly efficient |
Example | Bitcoin | Ethereum | IOTA, Cardano, Anion | SEELE, Unibright |
Application | Financial sector | Non-financial sector | Business platforms | Industry 4.0 |
Case Study | Advantage | Ref. |
---|---|---|
Data Sharing | Verify the data review procedure. | [88] |
A flexible privacy protection system. | [89] | |
Data Storage | High-efficiency access to data. | [90] |
Identify and fix the storage capacity issue with the blockchain. | [91] | |
Virtual Economy Ecosystem | Support anonymous payment. | [92] |
Assume machine-to-machine (M2M) and Internet of Things (IoT) payments. | [93] | |
Encourage a transparent environment for system participation. | [94] |
Topic | Current Paper | [97] | [98] | [58] | [76] | [99] | [100] |
---|---|---|---|---|---|---|---|
Blockchain Impact for Metaverse Enablers | X | ||||||
Technical Perspective of Metaverse | X | X | X | X | |||
Blockchain as an Enabling Technology for Metaverse | X | X | X | X | X | X | X |
Applications of Blockchain | X | X | X | X | X | ||
Timeline of Blockchain Evolution | X | ||||||
Technical Perspective of Adoptable Blockchain Methods | X | X | X | ||||
Blockchain for Society 5.0 | X |
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Mourtzis, D.; Angelopoulos, J.; Panopoulos, N. Blockchain Integration in the Era of Industrial Metaverse. Appl. Sci. 2023, 13, 1353. https://doi.org/10.3390/app13031353
Mourtzis D, Angelopoulos J, Panopoulos N. Blockchain Integration in the Era of Industrial Metaverse. Applied Sciences. 2023; 13(3):1353. https://doi.org/10.3390/app13031353
Chicago/Turabian StyleMourtzis, Dimitris, John Angelopoulos, and Nikos Panopoulos. 2023. "Blockchain Integration in the Era of Industrial Metaverse" Applied Sciences 13, no. 3: 1353. https://doi.org/10.3390/app13031353
APA StyleMourtzis, D., Angelopoulos, J., & Panopoulos, N. (2023). Blockchain Integration in the Era of Industrial Metaverse. Applied Sciences, 13(3), 1353. https://doi.org/10.3390/app13031353