https://github.com/olivmath/paper
https://github.com/olivmath/paper
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- URL: https://github.com/olivmath/paper
- Owner: olivmath
- License: mit
- Created: 2025-01-27T02:21:40.000Z (4 months ago)
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- Last Pushed: 2025-01-27T02:37:18.000Z (4 months ago)
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Metadata Files:
- Readme: README.md
- License: LICENSE
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README
# Papers 2025
| Done | Index | Year | Title | Pages | Author |
| ---- | ----- | ---- | ----- | ----- | ------ |
| | 1 | 1948 | A Mathematical Theory of Communication | | Claude E. Shannon |
| | 2 | 1949 | Communication Theory of Secrecy Systems | | Claude E. Shannon |
| | 3 | 1971 | P vs. NP Problem | | Stephen Cook |
| | 4 | 1973 | A Universal Modular ACTOR Formalism for Artificial Intelligence | | Carl Hewitt, Peter Bishop, Richard Steiger |
| | 5 | 1976 | New Directions in Cryptography | | Whitfield Diffie, Martin E. Hellman |
| | 6 | 1978 | A Method for Obtaining Digital Signatures and Public-Key Cryptosystems | | Ronald L. Rivest, Adi Shamir, Leonard Adleman |
| | 7 | 1978 | Time, Clocks, and the Ordering of Events in Distributed Systems | | Leslie Lamport |
| | 8 | 1979 | How to Share a Secret | | Adi Shamir |
| | 9 | 1982 | The Byzantine Generals Problem | | Leslie Lamport, Robert Shostak, Marshall Pease |
| | 10 | 1985 | The Knowledge Complexity of Interactive Proof Systems | | Shafi Goldwasser, Silvio Micali, Charles Rackoff |
| | 11 | 1985 | Impossibility of Distributed Consensus with One Faulty Process (FLP) | | Fischer, Lynch, Paterson |
| | 12 | 1988 | Consensus in the Presence of Partial Synchrony | | Cynthia Dwork, Nancy Lynch, Larry Stockmeyer |
| | 13 | 1990 | Implementing Fault-Tolerant Services Using the State Machine Approach: A Tutorial | | Fred B. Schneider |
| | 14 | 1990 | A Hundred Impossibility Proofs for Distributed Systems | | Nancy A. Lynch |
| | 15 | 1990 | Linearizability: A Correctness Condition for Concurrent Objects | | Maurice P. Herlihy, Jeannette M. Wing |
| | 16 | 1991 | Efficient Identification and Signatures for Smart Cards | | Uriel Feige, Amos Fiat, Adi Shamir |
| | 17 | 1993 | A Response to Cheriton and Skeen's Criticism of Causal and Totally Ordered Communication | | Kenneth P. Birman |
| | 18 | 1993 | Untraceable Electronic Mail, Return Addresses, and Digital Pseudonyms | | David Chaum |
| | 19 | 1993 | Byzantine Chain Replication | | Robbert van Renesse, Fred B. Schneider, Ken Birman, David Dolev, Danny Dolev, Shlomo Moran |
| | 20 | 1994 | A History of the Virtual Synchrony Replication Model | | Kenneth P. Birman, Robbert van Renesse |
| | 21 | 1994 | Consistent Global States of Distributed Systems: Fundamental Concepts and Mechanisms | | Özalp Babaoglu, Keith Marzullo |
| | 22 | 1994 | A Note on Distributed Computing | | Jim Waldo |
| | 23 | 1997 | ZK-SNARKs: Succinct Non-Interactive Arguments of Knowledge | | Eli Ben-Sasson |
| | 24 | 1997 | Consistent Hashing and Random Trees: Distributed Caching Protocols for Relieving Hot Spots on the World Wide Web | | David R. Karger, Eric Lehman, Tom Leighton, Matthew Levine, Daniel Lewin, Rina Panigrahy |
| | 25 | 1998 | The Part-Time Parliament | | Leslie Lamport |
| | 26 | 1999 | Practical Byzantine Fault Tolerance (PBFT) | | Miguel Castro, Barbara Liskov |
| | 27 | 2000 | CRYSTALS-Kyber: Algoritmo pós-quântico selecionado pelo NIST | | Vários autores |
| | 28 | 2001 | Chord: A Scalable Peer-to-peer Lookup Service for Internet Applications | | Ion Stoica, Robert Morris, David Karger, M. Frans Kaashoek, Hari Balakrishnan |
| | 29 | 2001 | Random Oracles are Practical | | Mihir Bellare, Phillip Rogaway |
| | 30 | 2002 | Practical Byzantine Fault Tolerance and Proactive Recovery | | Miguel Castro, Barbara Liskov, |
| | 31 | 2004 | Chain Replication for Supporting High Throughput and Availability | | Robbert van Renesse, Fred B. Schneider |
| | 32 | 2006 | A Byzantine Fault Tolerant Distributed Commit Protocol | | Wenbing Zhao |
| | 33 | 2007 | Paxos Made Live - An Engineering Perspective | | Leslie Lamport |
| | 34 | 2008 | Sinfonia: A New Paradigm for Building Scalable Distributed Systems | | Robbert van Renesse, Fred B. Schneider, |
| | 35 | 2008 | A Simple Totally Ordered Broadcast Protocol | | Benjamin Reed, Flavio P. Junqueira |
| | 36 | 2008 | Bitcoin: A Peer-to-Peer Electronic Cash System | | Satoshi Nakamoto |
| | 37 | 2012 | Sparrow: Distributed, Low Latency Scheduling | | Robert N. M. Watson, John Wilkes, |
| | 38 | 2013 | Ethereum Whitepaper: A Next-Generation Smart Contract and Decentralized Application Platform | | Vitalik Buterin |
| | 39 | 2013 | Elliptic Curve Cryptography in Practice | | Daniel J. Bernstein |
| | 40 | 2013 | Pinocchio: Nearly Practical Verifiable Computation | | Bryan Parno, Jon Howell, Craig Gentry, Mariana Raykova |
| | 41 | 2013 | There Is More Consensus in Egalitarian Parliaments | | Iulian Moraru, David G. Andersen, Michael Kaminsky |
| | 42 | 2013 | RSA Key Extraction via Low-Bandwidth Acoustic Cryptanalysis | | Adi Shamir, Eran Tromer, Daniel Genkin |
| | 43 | 2014 | Zerocash: Decentralized Anonymous Payments from Bitcoin | | Eli Ben-Sasson |
| | 44 | 2014 | Orleans: Distributed Virtual Actors for Programmability and Scalability | | Richard D. Griesemer, William R. Mark, |
| | 45 | 2014 | Ethereum: A Next-Generation Smart Contract and Decentralized Application Platform | | Vitalik Buterin |
| | 46 | 2014 | Raft Consensus Algorithm | | Diego Ongaro, John Ousterhout |
| | 47 | 2014 | SPHINCS: Practical Stateless Hash-Based Signatures | | Daniel J. Bernstein |
| | 48 | 2015 | The Stellar Consensus Protocol: A Federated Model for Internet-Level Consensus | | David Mazières |
| | 49 | 2015 | Practical Secure Aggregation for Federated Learning | | Keith Bonawitz |
| | 50 | 2015 | The Moral Character of Cryptographic Work | | Phillip Rogaway |
| | 51 | 2015 | Large-scale Cluster Management at Google with Borg | | John Wilkes, Robert Stumm, John Hartman, |
| | 52 | 2015 | SoK: Research Perspectives and Challenges for Bitcoin and Cryptocurrencies | | Arthur Gervais |
| | 53 | 2015 | IPFS: Content-Addressed, Versioned, P2P File System | | Juan Benet |
| | 54 | 2016 | NTRU Prime | | Daniel J. Bernstein |
| | 55 | 2016 | The Bitcoin Lightning Network | | Joseph Poon, Thaddeus Dryja |
| | 56 | 2016 | zk-STARKs: Scalable, Transparent Arguments of Knowledge | | Eli Ben-Sasson |
| | 57 | 2016 | The Noise Protocol Framework | | Trevor Perrin |
| | 58 | 2016 | The Bitcoin Lightning Network: Scalable Off-Chain Instant Payments | | Joseph Poon, Thaddeus Dryja |
| | 59 | 2016 | Hashgraph Consensus: Fair, Fast, Byzantine Fault Tolerance | | Leemon Baird |
| | 60 | 2016 | The Bitcoin Backbone Protocol: Analysis and Applications | | Juan Garay, Aggelos Kiayias, Nikos Leonardos |
| | 61 | 2016 | The Quest for Scalable Blockchain Fabric (OmniLedger) | | Eleftherios Kokoris-Kogias |
| | 62 | 2017 | Bulletproofs: Short Proofs for Confidential Transactions | | Benedikt B¨unz |
| | 63 | 2017 | Key Reinstallation Attacks: Forcing Nonce Reuse in WPA2 | | Mathy Vanhoef, Frank Piessens |
| | 64 | 2017 | Algorand: Scaling Byzantine Agreements for Cryptocurrencies | | Silvio Micali |
| | 65 | 2017 | KRACK: Key Reinstallation Attacks (WPA2) | | Mathy Vanhoef, Frank Piessens |
| | 66 | 2018 | Bulletproofs: Short Proofs for Confidential Transactions and More | | Benedikt Bünz, Jonathan Bootle, Dan Boneh, Andrew Poelstra, 1 |
| | 67 | 2018 | Sonic: Zero-Knowledge SNARKs from Linear-Size Universal and Updateable Structured Reference Strings | | Mary Maller |
| | 68 | 2018 | Omniledger: A Secure, Scale-Out, Decentralized Ledger | | Ehsan Toreini, Ittai Abraham, |
| | 69 | 2018 | Ouroboros: A Provably Secure Proof-of-Stake Blockchain Protocol | | Aggelos Kiayias |
| | 70 | 2018 | Decentralized AI: Blockchain-Based Federated Learning | | Yang Liu |
| | 71 | 2019 | PLONK: Permutations over Lagrange-bases for Oecumenical Noninteractive Arguments of Knowledge | | Ariel Gabizon, Zachary J. Williamson, Oana Ciobotaru |
| | 72 | 2019 | Marlin: Preprocessing zkSNARKs with Universal and Updatable SRS | | Alessandro Chiesa |
| | 73 | 2019 | AI and Blockchain: A Disruptive Integration | | K. Salah |
| | 74 | 2019 | Snowflake to Avalanche: A Novel Metastable Consensus Protocol Family for Cryptocurrencies | | Team Rocket |
| | 75 | 2019 | Cosmos: A Network of Distributed Ledgers | | Jae Kwon, Ethan Buchman |
| | 76 | 2019 | Logjam: Breaking TLS with 512-bit DH | | David Adrian |
| | 77 | 2020 | Avalanche: A Novel Metastable Consensus Protocol | | Team Rocket |
| | 78 | 2020 | Polkadot: Vision for a Heterogeneous Multi-Chain Framework | | Gavin Woods |
| | 79 | 2020 | zk-Rollups: Trustless Layer-2 Scaling for Ethereum | | Vitalik Buterin |
| | 80 | 2020 | Halo: Recursive Proof Composition without a Trusted Setup | | Sean Bowe, Jack Grigg, Daira Hopwood |
| | 81 | 2020 | AI-Blockchain: A Framework for Secure and Decentralized AI Training | | M. Al-Rakhami |
| | 82 | 2020 | Real-World Cryptography (RWC) Conference Highlights | | Vários autores |
| | 83 | 2020 | CRYSTALS-Kyber: A Post-Quantum Cryptographic Algorithm | | Vadim Lyubashevsky |
| | 84 | 2020 | Blockchain for Decentralized AI: Challenges and Opportunities | | Q. Xia |
| | 85 | 2021 | Flash Boys 2.0: Front-Running in Decentralized Exchanges, Miner Extractable Value, and Consensus Instability | | Philip Daian |
| | 86 | 2021 | Halo 2: Recursive Proof Composition without a Trusted Setup | | Sean Bowe |
| | 87 | 2021 | SoK: Decentralized Finance (DeFi) | | Lewis Gudgeon |
| | 88 | 2021 | Blockchain-Based Federated Learning for Data Privacy and Security | | Y. Zhao |
| | 89 | 2021 | Smart Contracts for AI: A Blockchain-Based Approach | | S. Wang |
| | 90 | 2021 | Bulletproofs++: Shorter Proofs for Confidential Transactions | | Benedikt Bünz |
| | 91 | 2022 | The Merge: Transitioning Ethereum to Proof-of-Stake | | Ethereum Foundation |
| | 92 | 2022 | AI-Driven Blockchain Oracles for Smart Contracts | | R. Gupta |
| | 93 | 2022 | FHE (Homomorphic Encryption) Advances | | Vários autores |
| | 94 | 2022 | Decentralized AI Marketplaces: A Blockchain-Based Approach | | L. Zhang |
| | 95 | 2022 | zk-EVM: Zero-Knowledge Proofs for Ethereum Virtual Machine | | Ethereum Research Team |
| | 96 | 2022 | Narwhal & Tusk: A DAG-based Mempool and Consensus Protocol | | George Danezis |
| | 97 | 2023 | AI-Driven Smart Contracts: Enhancing Automation and Security | | S. Wang, R. Gupta |
| | 98 | 2023 | Privacy-Preserving Machine Learning in Blockchain Networks | | Zhang |
| | 99 | 2023 | AI-Powered Consensus Mechanisms for Blockchain | | K. Li |
| | 100 | 2023 | Decentralized AI and Blockchain for Autonomous Systems | | S. A. Thompson, M. J. Smith |
| | 101 | 2023 | Quantum-Resistant Blockchain Algorithms for the Post-Quantum Era | | P. Zhang, L. F. Yang |
| | 102 | 2023 | Quantum-Resistant Cryptography: A Comprehensive Survey | | Vários autores |
| | 103 | 2023 | Decentralized Autonomous Organizations (DAOs): Challenges and Opportunities | | Vitalik Buterin, E. Glen Weyl |
| | 104 | 2023 | Scaling Distributed Systems with Sharding: A Deep Dive | | Maofan Yin, Dahlia Malkhi |
| | 105 | 2023 | Post-Quantum Cryptography in Blockchain: Challenges and Solutions | | Daniel J. Bernstein, Vadim Lyubashevsky |
| | 106 | 2024 | Optimizing Smart Contracts with AI for Blockchain Systems | | R. S. Kapoor, N. Jain |
| | 107 | 2024 | Blockchain-Integrated Federated Learning for Privacy-Preserving AI | | Y. Zhao, J. He |
| | 108 | 2024 | Blockchain Consensus Algorithms for Decentralized AI Models | | H. R. Kim, L. M. Torres |