Details
Originalsprache | Englisch |
---|---|
Aufsatznummer | 110297 |
Seitenumfang | 9 |
Fachzeitschrift | Computer networks |
Jahrgang | 243 |
Frühes Online-Datum | 1 März 2024 |
Publikationsstatus | Veröffentlicht - Apr. 2024 |
Abstract
Bitcoin, Ethereum and other blockchain-related globally distributed peer-to-peer networks have become an important payment infrastructure. Because they are naturally decentralized and distributed, they can consume resources unevenly, raising some sustainability concerns. The Lightning Network (LN) is a growing but understudied second layer network built on blockchain infrastructure and designed to make fast and anonymous global multi-pass payments. At a conservative estimate, this infrastructure produces about 1.4 million tons of carbon dioxide (CO2) per year. Thus, in this paper, we aim to justify a general approach to consider topology and the geographical distribution of this type of network in the design and investigate ways to prevent excessive CO2 emissions. While the LN itself shows great promise as a scalable and widely adopted solution, there has been limited research exploring its structure, distribution, and performance from a sustainability perspective. This study contributes to analyzing the LN's topology, geospatial distribution, and pathfinding algorithms. By examining real-world data snapshots of the LN, we investigate the relationship between payment routes that are produced by native pathfinding algorithms, geographical distribution of the network and the carbon intensity of electricity in the countries involved in the final payment paths. Our analysis highlights the important structural and geospatial characteristics of the LN and reveals a significant correlation between the length of payment paths, geographical distance, carbon intensity of electricity and other features. To tackle sustainability concerns, we propose an original pathfinding heuristic that effectively prevents excessive carbon dioxide emissions in LN infrastructure. Our computational experiments have shown that, under optimal parameters, such a heuristic can prevent the associated CO2 emissions both directly – by limiting path lengths, number of intercountry and intercontinental hops – and indirectly — by giving more weight to channels covering places with lower carbon intensity of electricity. Technically, the highest result it achieves is as follows: the average path length reduced by 28.7%, the average number of intercontinental hops by 28.7%, the average number of intercountry hops by 21.3%, and the average carbon intensity by 9.4%. This solution also maintains a compromise between the average locktimes and fee ratios. In conclusion, we discuss that geographic distribution is a rather important characteristic of decentralized peer-to-peer payment networks, which is usually underestimated at the network design stage.
ASJC Scopus Sachgebiete
- Informatik (insg.)
- Computernetzwerke und -kommunikation
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in: Computer networks, Jahrgang 243, 110297, 04.2024.
Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review
}
TY - JOUR
T1 - Reducing CO2 emissions in a peer-to-peer distributed payment network
T2 - Does geography matter in the lightning network?
AU - Valko, Danila
AU - Kudenko, Daniel
N1 - Funding Information: The authors would like to thank Dr.-Ing. Manfred Veenker and the Veenker Fondation, Germany for their support.
PY - 2024/4
Y1 - 2024/4
N2 - Bitcoin, Ethereum and other blockchain-related globally distributed peer-to-peer networks have become an important payment infrastructure. Because they are naturally decentralized and distributed, they can consume resources unevenly, raising some sustainability concerns. The Lightning Network (LN) is a growing but understudied second layer network built on blockchain infrastructure and designed to make fast and anonymous global multi-pass payments. At a conservative estimate, this infrastructure produces about 1.4 million tons of carbon dioxide (CO2) per year. Thus, in this paper, we aim to justify a general approach to consider topology and the geographical distribution of this type of network in the design and investigate ways to prevent excessive CO2 emissions. While the LN itself shows great promise as a scalable and widely adopted solution, there has been limited research exploring its structure, distribution, and performance from a sustainability perspective. This study contributes to analyzing the LN's topology, geospatial distribution, and pathfinding algorithms. By examining real-world data snapshots of the LN, we investigate the relationship between payment routes that are produced by native pathfinding algorithms, geographical distribution of the network and the carbon intensity of electricity in the countries involved in the final payment paths. Our analysis highlights the important structural and geospatial characteristics of the LN and reveals a significant correlation between the length of payment paths, geographical distance, carbon intensity of electricity and other features. To tackle sustainability concerns, we propose an original pathfinding heuristic that effectively prevents excessive carbon dioxide emissions in LN infrastructure. Our computational experiments have shown that, under optimal parameters, such a heuristic can prevent the associated CO2 emissions both directly – by limiting path lengths, number of intercountry and intercontinental hops – and indirectly — by giving more weight to channels covering places with lower carbon intensity of electricity. Technically, the highest result it achieves is as follows: the average path length reduced by 28.7%, the average number of intercontinental hops by 28.7%, the average number of intercountry hops by 21.3%, and the average carbon intensity by 9.4%. This solution also maintains a compromise between the average locktimes and fee ratios. In conclusion, we discuss that geographic distribution is a rather important characteristic of decentralized peer-to-peer payment networks, which is usually underestimated at the network design stage.
AB - Bitcoin, Ethereum and other blockchain-related globally distributed peer-to-peer networks have become an important payment infrastructure. Because they are naturally decentralized and distributed, they can consume resources unevenly, raising some sustainability concerns. The Lightning Network (LN) is a growing but understudied second layer network built on blockchain infrastructure and designed to make fast and anonymous global multi-pass payments. At a conservative estimate, this infrastructure produces about 1.4 million tons of carbon dioxide (CO2) per year. Thus, in this paper, we aim to justify a general approach to consider topology and the geographical distribution of this type of network in the design and investigate ways to prevent excessive CO2 emissions. While the LN itself shows great promise as a scalable and widely adopted solution, there has been limited research exploring its structure, distribution, and performance from a sustainability perspective. This study contributes to analyzing the LN's topology, geospatial distribution, and pathfinding algorithms. By examining real-world data snapshots of the LN, we investigate the relationship between payment routes that are produced by native pathfinding algorithms, geographical distribution of the network and the carbon intensity of electricity in the countries involved in the final payment paths. Our analysis highlights the important structural and geospatial characteristics of the LN and reveals a significant correlation between the length of payment paths, geographical distance, carbon intensity of electricity and other features. To tackle sustainability concerns, we propose an original pathfinding heuristic that effectively prevents excessive carbon dioxide emissions in LN infrastructure. Our computational experiments have shown that, under optimal parameters, such a heuristic can prevent the associated CO2 emissions both directly – by limiting path lengths, number of intercountry and intercontinental hops – and indirectly — by giving more weight to channels covering places with lower carbon intensity of electricity. Technically, the highest result it achieves is as follows: the average path length reduced by 28.7%, the average number of intercontinental hops by 28.7%, the average number of intercountry hops by 21.3%, and the average carbon intensity by 9.4%. This solution also maintains a compromise between the average locktimes and fee ratios. In conclusion, we discuss that geographic distribution is a rather important characteristic of decentralized peer-to-peer payment networks, which is usually underestimated at the network design stage.
KW - Bayesian optimization
KW - Carbon intensity
KW - Geographical analysis
KW - Lightning network
KW - Sustainability
UR - http://www.scopus.com/inward/record.url?scp=85186672513&partnerID=8YFLogxK
U2 - 10.1016/j.comnet.2024.110297
DO - 10.1016/j.comnet.2024.110297
M3 - Article
AN - SCOPUS:85186672513
VL - 243
JO - Computer networks
JF - Computer networks
SN - 1389-1286
M1 - 110297
ER -