Avalanche (AVAX) sustainability report

Avalanche is present on the following networks: Avalanche.

The Avalanche blockchain network implements a sophisticated Proof-of-Stake (PoS) mechanism known as Avalanche Consensus, distinguishing itself from many other PoS protocols by incorporating a novel, subsampling-based approach rather than a traditional Byzantine Fault Tolerant (BFT) consensus. This unique consensus process is built upon three integrated protocols: Snowball, Snowflake, and Avalanche, all working in concert to achieve high throughput, rapid finality, and robust security. The process begins with the Snowball protocol, where each validator randomly samples a small, fixed-size group of other validators. Through repeated polling of these sampled validators, a preference for a particular transaction is established. Validators maintain confidence counters for each transaction, incrementing them as sampled validators express support for their chosen transaction. A transaction is deemed accepted once its confidence counter surpasses a predefined threshold. Building upon Snowball, the Snowflake protocol refines the process by introducing a binary decision system, compelling validators to choose between two conflicting transactions. Binary confidence counters track the preferred binary choice, and once a specific confidence level is attained, the decision becomes final and irreversible. The overarching Avalanche protocol organizes transactions using a Directed Acyclic Graph (DAG) structure. This DAG architecture is crucial for facilitating parallel transaction processing, which significantly enhances the network's overall throughput and efficiency. Transactions are added to the DAG based on their intrinsic dependencies, ensuring a consistent and logical order across the network. Ultimately, validators reach consensus on both the structure and content of this DAG through the iterative application of the Snowball and Snowflake protocols. The Avalanche X-Chain, a component of the broader Avalanche network, also utilizes this Avalanche consensus protocol, emphasizing repeated subsampling of validators to achieve agreement on transactions. Furthermore, networks like Flare integrate the Avalanche Consensus with a Federated Byzantine Agreement (FBA) model to further bolster scalability, security, and decentralization, leveraging a gossip protocol for rapid node communication and transaction confirmation.

Avalanche is present on the following networks: Avalanche.

The Avalanche blockchain network employs a comprehensive system of incentive mechanisms and fees designed to ensure its security, integrity, and efficiency, primarily through its Avalanche Consensus mechanism. Validators, who are critical to the network's operation, are required to stake a certain amount of AVAX tokens. The quantity of staked tokens directly influences their likelihood of being chosen to propose or validate new blocks. In return for their active participation, validators receive rewards, which are calculated proportionally to the amount of AVAX they have staked, as well as their consistent uptime and overall performance in validating transactions. To further decentralize participation, validators can also accept delegations from other token holders. These delegators subsequently share in the earned rewards, thus incentivizing smaller token holders to contribute indirectly to the network's security. The economic incentives for validators extend beyond staking rewards to include block rewards, which are distributed from the inflationary issuance of new AVAX tokens for proposing and validating blocks. Additionally, validators earn a portion of the transaction fees paid by users across the network, covering simple transactions, complex smart contract interactions, and the creation of new assets. Crucially, Avalanche's penalty system differs from some other Proof-of-Stake systems by not employing 'slashing,' which involves the confiscation of staked tokens for misbehavior. Instead, the network relies on the economic disincentive of lost future rewards. Validators who fail to maintain consistent uptime or engage in malicious activities will simply miss out on potential earnings, providing a strong incentive for honest and reliable behavior. The network also imposes clear uptime requirements, where poor performance directly impacts a validator's ability to earn rewards. Fees on the Avalanche blockchain are structured to be dynamic, adjusting based on current network demand and the computational complexity of transactions. This ensures that fees remain equitable and reflect the actual network usage. A significant portion of these transaction fees is 'burned,' meaning they are permanently removed from circulation. This deflationary mechanism helps to offset the inflationary effects of block rewards and aims to enhance the long-term value of AVAX tokens. Fees for deploying and interacting with smart contracts are determined by the required computational resources, promoting efficient resource utilization. Similarly, fees are imposed for creating new assets on the network, a measure designed to deter spam and ensure that network resources are utilized by serious projects. On the Avalanche X-Chain, validator incentives are realized indirectly through the network's overall AVAX issuance, while its transaction fees are fixed and burned to combat spam and progressively reduce the total supply of AVAX.

Avalanche is present on the following networks: Avalanche.

The methodology for assessing the Avalanche network's energy consumption is founded on a 'bottom-up' approach, where individual nodes are identified as the primary contributors to the network's overall energy footprint. This comprehensive calculation aggregates energy usage across various interconnected components of the network. The assumptions underpinning these calculations are derived from extensive empirical findings, utilizing a combination of publicly available information sites, sophisticated open-source crawlers, and proprietary in-house developed crawlers. A key aspect of this methodology involves estimating the hardware deployed within the network. This estimation is primarily driven by the technical specifications and operational requirements for running the client software, which dictates the type and performance of necessary hardware devices. The energy consumption profiles of these identified hardware devices are meticulously measured in certified test laboratories to ensure accuracy. To ensure a broad and precise scope, the Functionally Fungible Group Digital Token Identifier (FFG DTI) is leveraged, whenever available, to pinpoint all relevant implementations of the crypto-asset under consideration. These mappings are regularly updated based on current data provided by the Digital Token Identifier Foundation. The data regarding specific hardware usage and the total number of network participants is based on empirically verified assumptions, consistently updated with best-effort validation. A foundational assumption in this model is that network participants generally behave in an economically rational manner. Furthermore, adhering to a precautionary principle, any uncertainties or doubts during the estimation process lead to conservative assumptions, specifically by making higher estimates for potential adverse environmental impacts. When determining the energy consumption attributable to a specific token within the Avalanche ecosystem, the energy consumption of the entire Avalanche network (including subnets like Avalanche X-Chain) is calculated first. Subsequently, a fraction of this total network energy is allocated to the token, proportional to its activity and footprint within the network. This detailed, multi-layered approach aims to provide a robust and conservative estimate of the energy consumption associated with the Avalanche blockchain.

Avalanche is present on the following networks: Avalanche.

The methodology for determining the key energy sources and the proportion of renewable energy utilized by the Avalanche blockchain network relies on a multi-pronged approach that integrates geographical data with energy mix statistics. To ascertain the percentage of renewable energy consumption, the initial step involves accurately identifying the geographical locations of the network's nodes. This crucial data is gathered through a combination of public information sites, advanced open-source crawlers, and proprietary in-house crawlers developed specifically for this purpose. In instances where comprehensive geographical distribution information for the nodes is not readily available, the methodology pivots to utilizing 'reference networks.' These reference networks are carefully selected for their comparability to Avalanche in terms of their incentivization structures and underlying consensus mechanisms, ensuring that the estimated renewable energy mix remains relevant and reflective of similar blockchain operations. Once the geographical data for the nodes (either directly identified or inferred from reference networks) is compiled, this geo-information is meticulously merged with comprehensive public data sets on electricity generation. A primary source for this integration is the data provided by Our World in Data, which offers detailed insights into the global energy landscape. The energy intensity of the network is then calculated as the marginal energy cost incurred for processing one additional transaction. This granular measurement provides a precise understanding of the energy overhead per unit of network activity. The specific datasets and sources referenced for this methodology include: Ember (2025) and the Energy Institute - Statistical Review of World Energy (2024), both of which undergo significant processing by Our World in Data. The dataset titled “Share of electricity generated by renewables – Ember and Energy Institute” is a key input, comprising original data from Ember’s “Yearly Electricity Data Europe” and “Yearly Electricity Data,” alongside the Energy Institute’s “Statistical Review of World Energy.” This information is publicly accessible at Share of electricity generated by renewables – Ember and Energy Institute.

Avalanche is present on the following networks: Avalanche.

The methodology employed to determine the Greenhouse Gas (GHG) emissions associated with the Avalanche blockchain network involves a detailed process of locating network infrastructure and integrating this geographical data with carbon intensity statistics. The initial step is to precisely identify the locations of the network's nodes, a task accomplished through the diligent use of public information sites, sophisticated open-source crawlers, and specialized in-house crawlers. This geographical mapping is fundamental to understanding the specific energy grids from which the nodes draw their power. In situations where direct geographical information on node distribution is insufficient, the methodology relies on 'reference networks.' These are selected based on their structural similarities to Avalanche, particularly concerning their incentivization mechanisms and consensus protocols, ensuring that the estimates are as representative as possible. The collected geo-information, whether direct or inferred, is then carefully integrated with public data regarding the carbon intensity of electricity generation. A significant source for this critical data is Our World in Data, which provides comprehensive global information on electricity generation’s carbon footprint. The GHG intensity of the network is quantified as the marginal emission generated per additional transaction processed. This metric allows for a precise evaluation of the environmental impact as network activity scales. The foundational data and citations for this methodology include: Ember (2025) and the Energy Institute - Statistical Review of World Energy (2024), which have been extensively processed by Our World in Data. The specific dataset used is titled “Carbon intensity of electricity generation – Ember and Energy Institute,” drawing original data from Ember’s “Yearly Electricity Data Europe” and “Yearly Electricity Data,” as well as the Energy Institute’s “Statistical Review of World Energy.” This crucial resource for carbon intensity data is available under a CC BY 4.0 license at Carbon intensity of electricity generation – Ember and Energy Institute.