No, Nexus is one of the few blockchains which was created from scratch, and mined into existence (like Bitcoin).
The Nexus Embassies are funded by a portion of each NXS block that is mined. The NXS automatically transfers into ‘Keys’ which are allocated between the Embassies.
The first NXS block was mined on September 23rd of 2014 at 16:20:00 GMT – 7. As of March 3rd 2020, the total supply of NXS is $66,264,456, which is 85% of the September 2024 target of 78,000,000. Please read more below.
Cryptocurrency is an important faucet to Nexus, which is why we have our own native currency called ‘NXS’. This currency is the backbone of our ecosystem because it pays miners to build blocks, and gives regular users income for simply holding their coins at a rate of return between 0.5% and 3.0% per annum.
NXS features include:
There are three ways to obtain NXS:
The following digital currency exchanges list NXS, which is tradeable between both digital currencies (e.g. BTC, ETH) and fiat currencies (e.g. USD, EUR, GBP).
Staking is an energy efficient form of mining that provides security to the Nexus Blockchain. NXS can only be staked inside the official Nexus Wallet when in ‘staking mode’ and with a continuous internet connection (24 hours a day, 7 days a week). This ownership represents a ‘stake’ in the sense of an interest in something.In return, ‘stakers’ are rewarded for providing security to the network, and can earn a ‘stake rate’ of between 0.5% and 3.0% per year on their NXS holdings.
Mining is a process in which a computer program is run by high-performance hardware to process transactions and provide security to the Nexus Blockchain. In return, miners earn newly created NXS.
The wallet can be downloaded from the following page
If you have any specific wallet or general enquiries, please use the chat box on the website, or join one of our community channels (Slack or Telegram), and post a message asking for help.
The fundamental issue of scaling comes down to what is termed the ‘Blockchain Trilemma’, an opinion that only two of the three qualities, Security, Decentralization and Scalability, are achievable concurrently.
Please read the The Three Dimensional Chain for details on how Nexus is implementing an architecture that is a promising candidate to solving the ‘Blockchain Trilemma', and The Ethereum Blockchain is over 1TB for further reading.
As the protocol is further developed, the above three forms of consensus will become the three layers of the Three Dimensional Chain (3DC). The architecture will reduce miner centralization, and will be more efficient in on-chain scaling.
The 3DC will transform the ledger into a multi-layered processing system, in order to scale securely and maintain a high degree of decentralization. It is a promising candidate for solving the ‘Blockchain Trilemma’, an opinion that only two of the three qualities, Security, Decentralization and Scalability, are achievable concurrently.
It chains together cryptographic primitives into a multi-dimensional immutable object, and has three core dimensions: pBFT + reputation channels (X), immutability or authenticity (Y), and time (Z). The upgrades of Amine and Obsidian will add another layer of transaction processing ‘L2’ and ‘L3’, to the base layer ‘L1’.
Nexus is unique among blockchain technology in that we use three channels to secure the network: two Proof of Work (PoW) channels (Prime and Hashing) and one Proof of Stake (PoS) channel. Consensus is balanced between all three channels as it is based on collective chain weight, providing a higher resistance to 51% attacks compared to single algorithm blockchains. As the TAO framework is developed, these three forms of consensus will become the three layers of the 3DC.
Nexus can respond to an increased hashrate in the space of one block, while each of the channels scales independently of the other. This stabilizes block time at ~50 seconds and ensures no single channel can monopolize block production. Every 20 minutes, the Nexus protocol automatically creates a checkpoint. This prevents blocks from being created or modified prior to this checkpoint, thus protecting the chain from malicious attempts to introduce an alternate chain.
Two Proof of Work (PoW) channels (Prime and Hashing) and one Proof of Stake (PoS) channel are used to secure the network. Consensus is balanced between all three channels as it is based on collective chain weight, providing a higher resistance to 51% attacks compared to single algorithm blockchains. As the TAO framework is developed, these three forms of consensus will become the three layers of the 3DC.
The Prime Channel is a Proof-of-Work consensus mechanism that uses 308-digit dense prime clusters. This makes the Prime Channel more ASIC resistant than usual hash mining.
This second channel is another Proof-of-Work channel, but it uses Hashcash as its mining algorithm. This has miners searching for SHA-3 hashes, which is similar to the Bitcoin SHA-256 hashes, but four times the size of the Bitcoin block hashes.
Proof of Stake Channel
The final channel is a reputation-based staking consensus method where users mint new NXS by holding and staking the coins that they hold. Four attributes determine the rate of return:
Nexus implements a reputation mechanism called ‘trust’ that records the consistent time that a node contributes to the validation process. Trust decreases three times faster than it accrues and translates into a variable stake reward of between 0.5% to 3% per annum. Trust also benefits the Network layer, where nodes can determine the reputation or reliability of the nodes they are talking to, increasing security against ‘Sybil Attacks’.
Yes, the Nexus architecture has a 64-bit register-based Virtual Machine for contract processing.
Through our research we found that most projects built on Ethereum do not use the Ethereum Virtual Machine (EVM) for its turing completeness, i.e. its ability to do universal computation. What businesses require from blockchain technology are contracts that function more like real world actions between people, with the addition of an immutable data layer capable of managing rights and ownership. Therefore, Nexus developed an easily accessible and versatile Software Stack where data can be operated on, its ownership transferred between users, and whereby conditions define the behavior of actions. The design not only provides numerous ready-made contract functionalities, it is also able to scale with the growing demand of smart contracts.
The Nexus architecture is designed as a seven-layered software stack that includes a 64-bit register-based contract engine. Each layer is designated to carry out a specialized process independently of one another, providing additional functionality to the existing Internet stack, the OSI model.
Register-Based Contact Engine
A register is the fastest storage medium inside your computer’s CPU (Central Processing Unit), that the processor uses to cache data in between calculations. The Nexus Contract engine follows this architecture as an improvement to other blockchain-powered virtual machines such as the EVM (Ethereum Virtual Machine) that still use the older stack architecture. The improved efficiency gained through the use of registers makes developing on Nexus not only easier, but also much more efficient and scalable.
Nexus Contracts facilitate the function of intermediaries and are governed solely by the mathematics and code that runs on our 64-bit Register Virtual Machine.
Nexus Contracts are designed to feel like ‘actual’ real world contracts between people. A basic Nexus contract is comprised of three layers: data (Registers), programmable actions (Operations), and accounts (Signature Chains). Together, these layers verify the information of a system or Decentralized Application (DApp), following logic that closely relates to agreements and contracts between people. These actions are filtered through the use of ‘programmable conditions’ that define a more complex contract between two or more users. All the layers together form the foundation of the Dapp following the philosophy: “A blockchain is a verification system, not a computation engine.”
Nexus has followed this approach for the primary reason that smart contracts cannot be realized with existing language designs, they require a new architecture. This is in direct contrast to EOS’ use of Web Assembly (WASM), which was designed for web development rather than building secure financial applications. Conditional Contracts allow a user to set requirements in order for a contract to be fulfilled, such as contract time expiration, the decentralized exchange of an asset, or a non-custodial escrow services.
Smart Contracts are self-executing. Their design is to enforce the terms and conditions of a contract through programmable logic, reducing the need for third party intermediaries such as brokers and banks. Smart Contracts are an additional layer of processing above the ledger layer, i.e what is known as ‘the blockchain’, and are comparable to small computer programs that hold a state of information. The calculations of the contract are carried out by the processing nodes of a blockchain, which change the state of the information. Given that the calculations or processing is carried out by distributed consensus, the state of a Smart Contract is immutable.
Bitcoin was introduced with built-in Smart Contract functionality, which it calls ‘scripts’. Ethereum augmented these capabilities into its ‘Turing Complete Smart Contracts’, through a custom programming language called Solidity, which is then compiled into assembly language that is run on the Ethereum Virtual Machine (EVM).
Though very capable, Ethereum has experienced some issues in regards to security, performance, and ease-of-use, largely because of its Turing complete and 256-bit native design. Some notable cases include the $75m DAO hack on Ethereum, and the $286m Parity bug. Vulnerabilities existed due to the large complexity of a Turing complete system, and the resulting difficulty of resolving bugs in a protocol written in immutable code.
The complexity of operations that support universal computation or Turing complete designs also limit scalability. A universal system has a higher degree of complexity, and can not therefore compete with technology that is designed for more specialized tasks. An example of this observation would be the comparison between a CPU (Central Processing Unit) with an ASIC (Application Specific Integrated Circuit) in the mining of cryptocurrency. A CPU can’t compete against a SHA256 miner, as its complexity and design is geared to support universal general computation, not specialized computation. A similar conclusion could be drawn when a comparison is made between the system design of Ethereum (universal), and Nexus (specialized).
Nexus has moved away from the UTXO transaction-based system and has implemented an architecture named Signature Chains. When a user makes a transaction, it is chained to the users previous transactions, creating a chain of signatures. Alternatively, when a user transfers an asset to another user, this is again recorded on their Signature Chain.
Signature Chains are comparable to a personal blockchain, and provide the foundation for features such as Managing Assets, whilst maintaining pseudo-anonymity for privacy. This type of architecture offers higher scaling potential, as only one signature needs to be verified per transaction. Comparing a single UTXO transaction could contain 1000’s of inputs, to transact even a small amount of coins.
Signature Chains also provide an automated key management system through a decentralized login technology This technology still uses public key cryptography, but rather than maintaining the keys on disk or the cloud, they are stored as a lock in ‘mathematical hyperspace’, that only your login credentials (username, password and pin) can unlock.
Signature Chains support the Nexus Wallet, making it accessible from any computer simply by logging in with your credentials. This removes the need for a wallet.dat file to access private keys, constantly rescanning the database, the inconvenience of having to make regular wallet backups, loss or theft of hard drives, and the risk of sending funds to unspendable addresses.
Signature Chains are also available for DApp developers to build with, furthering Nexus’ mission of increasing the accessibility of blockchain technology. Signature Chains are comparable to a personal blockchain, and provide the foundation for features such as Managing Assets, whilst maintaining pseudo-anonymity for privacy.
An API is an Application Programming Interface. While a user interacts with a system through a user interface, an API allows developers to interact through a programmatic interface. The API provides a list or set of simple commands that execute a series of operations, which would otherwise require specialist programming knowledge. This allows a developer to request or submit data to a system providing functionality to a higher-level application. For example, Facebook’s Graph API allows access to 'Login with Facebook' and other features of their system.
The Nexus wallet provides a HTTP powered API. This layer provides an interface that allows developers to gain direct access to blockchain functionality. The Nexus API is for developers to build DApps and Hybrid Networks. Developers can use the API to build with contracts, which can facilitate the management of ownership rights and decentralized exchange of many different kinds of assets and tokens. The API can be used for the recording of Supply Chains, Digital Asset Licensing, Financial Assets, Records, Licenses, Certificates, and Securitized Token Offerings (STOs).
The Nexus API is based on a simple verb and noun semantics, and accepts a wide variety of encoding. It is the gateway into the blockchain, that can be used without direct access to the lower levels of the software stack, making development on Nexus as easy as developing a web application.
Developers can build Dapps simply in any language using our API, avoiding unnecessary mistakes being made. To add flexibility, a developer can make non-standard API calls with custom conditions to provide additional functionality to the DApp that is unavailable through the standard API. This can be further augmented with Domain-Specific Languages on the lower API layer. We hope this will reduce the learning curve associated with developing contracts, therefore stimulating the growth of the developer community. An SDK in Python is currently available.
The Nexus Wallet has a modular architecture that provides a platform for developers to build Wallet Modules with the Nexus API. Wallet Modules embed directly into the Wallet as extensions to the standard logical and interface layers of the software stack.
The TAO Name System (TNS) is similar to Domain Name System (DNS), allowing users to create and exchange names with one another that point to different objects, without having to use large hexadecimal addresses. These names can resolve to register addresses such as assets and tokens, or become aliases for user identification.
A Hybrid Network on Nexus is geared towards any individual, company, or large enterprise wishing to manage their own private network, without the added complexity of worrying about system or network security and protection of critical user data.
‘Hybrid’ by definition means a combination of two different elements, to result in something new. Our Hybrid technology combines properties of public and private systems. The public network generates security and decentralization through higher levels of immutability, access control schemes, and custom validation algorithms, while the private network provides autonomy, privacy, and isolation.
The Nexus Hybrid Blockchain has the following properties and features:
Classical computing uses an array of transistors. These transistors form the heart of your computer (the CPU). Each transistor is capable of being either on or off, and these states are used to represent the numerical values 1 and 0. Binary digits’ (bits) number of states depends on the number of transistors available, according to the formula (2^n) + 1, with n being the number of transistors. Classical computers can only be in one of these states at any one time, so the speed of your computer is limited to how fast it can change state.
Quantum computers on the other hand, use what are termed quantum bits or ‘qubits’ which are represented by the quantum spin of electrons or photons. These particles are placed into a state called superposition, allowing the qubit to assume a value of 1 and 0 simultaneously, generally resulting in an exponential increase in computational power over their classical counterparts.
With the rise in the power of classical computers and the emergence of quantum computers, public keys are becoming increasingly vulnerable. Most cryptocurrency addresses are created by hashing or obscuring the public key, however, once a user transfers funds from this address, the public key is then revealed on the blockchain. In the realm of classical computing there is little risk with this method. However, a Quantum Computer running Shor’s algorithm could break most public key cryptography in little to no time at all, resultingin funds being stolen.Though most conjectures range from five to ten years before security could begin to break, Nexus has prepared by integrating a number of cryptographic innovations that support increased levels of quantum resistance.
We have developed anarchitecture called Signature Chains that enhance the security of existing DSA (Digital Signature Algorithm), by hashing the public key until it is used while changing the key pair with every transaction.We have also integrated the following cryptographic functions: FALCON (a second round contender for the NIST Post-Quantum cryptography competition), Argon2 (winner of the password hashing competition, and a superior alternative to S-Crypt or B-Crypt), and Keccak (winner of the SHA3 competition).
Signature Chains use a one-time signature scheme that signs one message per key. Signature Chains enhance the security of existing DSA (Digital Signature Algorithm), by hashing the public key until it is used while changing the key pair with every transaction. Signature Chains reduce the window of quantum vulnerability to the period between making a transaction and the inclusion of the transaction in the ledger.
Nexus has also integrated the following cryptographic functions: FALCON (a second round contender for the NIST Post-Quantum cryptography competition), Argon2 (winner of the password hashing competition, and a superior alternative to S-Crypt or B-Crypt), and Keccak (winner of the SHA3 competition).
The Network is responsible for the end-to-end communication between nodes, handling the relaying and receiving of ledger level data. To advance the functionality of the Network Layer, we are the only blockchain to use the Locator Identifier Separation Protocol (LISP) overlay. LISP was developed by Dino Farinacci who was the first Fellow (the most senior rank or title one can achieve in engineering) of Cisco.
LISP provides many necessary features for ease of use, decentralization, security, scalability, and for secure access schemes for hybrid networks. Some of the below features are fully integrated, and others are being deployed through the TAO Framework.
LISP increases the reliability and security of communication between nodes, and is responsible for network scaling through multicast, identification through a static EID (Endpoint Identifiers), and authentication by using these identifiers.
The LISP Overlay also provides IPv6 functionality to the network, which allows the user to control their IP address through cryptography. Through IPv6 addressing LISP provides ample capacity for the emerging IoT industry. It will be used in a critical capacity with the release of the Amine upgrade, which uses the Network (IP) layer to shard data and assign identifiers to data segments for management of the distributed database, without the loss of security or privacy.
The Lower Level Library (LLL) is a high-performance ‘Template Library’ designed to power emerging-web technologies. The LLL is simple, powerful, and lightweight. It contains three main components: Cryptography (LLC), Database (LLD), and Protocol (LLP).
The Lower Level Database (LLD) is Nexus’ modular storage engine, which according to tests done by Nexus, is capable of outperforming most existing embedded database engines, achieving 100,000 writes and reads to disk in 0.33 seconds – rivaling Google’s LevelDB.
The Lower Level Protocol (LLP) is a core component of the Network Layer, a light and fast protocol that allows developers to customize their packet design and message interpretation. It gains scalability through simplicity and is capable of managing a large number of simultaneous connections.
The Lower Level Cryptography (LLC) is a light library that contains many useful cryptographic functions such as Post-Quantum Cryptography, AES, and Argon2.
A 'Safenet' is being developed as an 'elevated' web within the current internet, to faciliate greater safety, security, and transparency when surfing online. The Nexus Software Stack is an augmentation of the current internet's architecture, which will evenutally verify website content and programs in order to stop viruses, providing a seamless user experience for websites using Nexus as their authentication system.
Today the Internet relies on both large cables that run across the ocean floor, and geosynchronous satellites. The main drawbacks resulting from the state of the current Internet infrastructure are as follows:
Some organizations have deployed cube satellites into LEO (Lower Earth Orbit), however their models are dependent on centralized ownership and management. One of our longer term visions, is to tokenize satellite ownership, whereby token holders will be entitled to the revenue earned and voting rights, in order to facilitate decentralized ownership and management. When you combine this with affordable antennas and local area mesh networks, we envision the beginning of a new Internet.
We welcome all parties whom would like to become a part of this collaborative economy, to connect with us.
Each letter represents one of the three upgrades of the TAO Framework which includes the deployment of the Three-Dimensional Chain (3DC). Each consensus upgrade corresponds to the addition of a transaction level lock which will transform transaction processing into a multi-dimensional process.
Yes, please click here to view our roadmap – the Nexus TAO Framework.
Yes. Staking is an energy efficient form of mining that provides security to the Nexus Blockchain. NXS can only be staked inside the official Nexus Wallet when in ‘staking mode’ and with a continuous internet connection (24 hours a day, 7 days a week). This ownership represents a ‘stake’ in the sense of an interest in something.In return, ‘stakers’ are rewarded for providing security to the network, and can earn a ‘stake rate’ of between 0.5% and 3.0% per year on their NXS holdings.
It is possible to stake with any amount of NXS and earn stake rewards at a rate of 0.5%. However, to grow your stake rate and reach the maximum of 3.0%, your node must find a Proof of Stake block at least every 72 hours. As of the 3rd March 2020 it takes around 10,000 NXS to do this.
Similar to other forms of mining, ‘Proof of Stake’ mining has a level of ‘difficulty’. As more people successfully stake on the network, the difficulty of mining Proof of Stake blocks increases. This increases the amount of NXS required to find at least one block every 72 hours and increase the stake rate. While difficulty reduces the frequency of mining stake blocks, a larger balance of NXS in your wallet will increase the frequency. Thus, if you are not finding blocks within the 72 hour requirement, and wish to increase your stake rate, the easiest way to do so is to increase your balance.
Please see the 'Staking' section of the Wallet guide.
Genesis is the process by which a wallet creates a trust key to use for staking.This is the first step for staking a new wallet.When it creates a new trust key, the Genesis transaction will transfer your wallet balance to that key for staking. This has no impact on your wallet balance.After the trust key is created, the wallet will no longer stake Genesis, and will instead stake Trust transactions.
There is no set time period in which it finds a new block.It is not at all unusual to go a period of time without a Trust transaction.
These items affect the size and frequency of staking rewards after you receive your initial Genesis transaction.
Stake Rate – This value represents your current annual NXS rate of return (%). The rate starts at 0.5%, and can increase to 3.0% after 12 months of consistent staking. The rate increase is non linear, slowing in terms of its increase over time. It takes several weeks of consistent staking to reach 1.0%, and around four months to reach 2.0%. With this rate, you can calculate the average amount of NXS you can expect to receive over time for staking.
Trust Weight – An indication of how much the network trusts your node. It starts at 1.11% and increases in a non-linear manner like stake rate does. Your level of trust increases your stake weight (below), thus increasing your chances of mining stake blocks and receiving staking rewards. It becomes easier to maintain trust as this value increases.
Block Weight – Upon receipt of a Genesis transaction, this value will begin increasing slowly, reaching 100% in 3 days time. Every time you receive a staking transaction, the block weight resets.
What happens when my Block Weight reaches 100%?
Stake Weight – The higher your stake weight, the greater your chance of receiving a transaction. The exact value is derived from your trust weight and block weight
What affects block production in staking?
Yes, two Proof of Work (PoW) channels (Prime and Hashing) and one Proof of Stake (PoS) channel are used to secure the network. Consensus is balanced between all three channels, making the network more resistant to 51% attacks.The prime algorithm is optimized for use by your computer’s central processing unit (CPU), while the hashing algorithm runs optimally on the graphics processing unit (GPU).
Prime Mining Channel
This mining channel looks for a special prime cluster of a set length. This type of calculation is resistant to ASIC mining, allowing for greater decentralization. This is most often performed using the CPU.
This channel utilizes the more traditional method of hashing. This process adds a random nonce, hashes the data, and compares the resultant hash against a predetermined format set by the difficulty. This is most often performed using a GPU.
Please learn more on the following webpage:
As outlined above, there are two types of mining and 1 proof of stake. Each type of mining uses a different component of your computer to find blocks, the CPU or the GPU. Nexus supports CPU and GPU mining on Windows and Linux. There are also third-party macOS builds available.
Please follow the instructions below for the relevant type of miner.
Almost every CPU is capable of mining blocks on this channel. The most effective method of mining is to join a mining pool and receive a share of the rewards based on the contribution you make. To create your own mining facility, you need the CPU mining software, and a NXS address. This address cannot be on an exchange. You create an address when you install your Nexus wallet. You can find the related steps under How Do I Install the Nexus Wallet?
Please download the relevant miner from the Mine page. Note that there are two different miner builds available: the prime solo miner and the prime pool miner. This guide will walk you through installing the pool miner only.
Step 1 – Extract the archive file to a folder.
Step 2 – Open the
miner.conf file. You can use the default host and port, but these may be changed to a pool of your choice. You will need to change the value of nxs_address to the address found in your wallet.
Sieve_threads is the number of CPU threads you want to use to find primes.
Ptest_threads is the number of CPU threads you want to test the primes found by the sieve. As a general rule, the number of threads used for the sieve should be 75% of the threads used for testing.
It is also recommended to add the following line to the options found in the .conf file:
"experimental" : "true"
This option enables the miner to use an improved sieve algorithm which will enable your miner to find primes at a faster rate.
Step 3 – Run the nexus_cpuminer.exe file. For more information on pools and settings, please see the Mine page.
The GPU is a dedicated processing unit housed on-board your graphics card. The GPU is able to perform certain tasks extremely well, unlike your CPU, which is designed for parallel processing. Nexus supports both AMD and Nvidia GPU mining, and works best on the newer models. Officially, Nexus does not support GPU pool mining, but there are 3rd party miners with this capability.
The latest software for the Nvidia miner can be found here. The latest software for the AMD miner can be found here. The AMD miner is a third party miner. This guide will walk you through the Nvidia miner.
Step 1 – Close your wallet. Navigate to
~/Library/Application Support/Nexus on macOS) and open the
nexus.conf file. Depending on your wallet, you may or may not have this file. If not, please create a new txt file and save it as
You will need to add the following lines before restarting your wallet:
Step 2 – Extract the files into a new folder.
Step 3 – Run the
nexus.bat file. This will run the miner and deposit any rewards for mining a block into the account on your wallet.
The Nexus community is the foundation for the strength, diversity and resilience of Nexus. Together, we provide ideas and resources that are crucial to the health of the network. Whether you trade, mine or stake NXS, develop applications to sell or share, or exchange ideas in one of our community channels, you are a part of the community. We are a diverse network of individuals who advocate the following principles:
Responsibility & Independence
Decentralized Systems have the ability to provide choices to become more independent from existing systems, which are often centralized and reliant on outdated processes.
Decentralization & Meritocracy
Decentralization of power and resources is fundamental to building the foundations of a meritocracy, where people are rewarded proportional to their merit.
Information & Exchange
The technology of Nexus is developed for people to have free access to information and exchange, creating the possibility for more novelty.
Honesty & Transparency
Honesty nurtures trust between people, allowing us to be more effective as a group, whilst transparency cultivates integrity.
Community & Collaboration
Respecting ourselves and others encourages greater cooperation, collaboration and growth, to build stronger relationships and therefore a stronger community.
The more people that contribute to a decentralized system, the more secure, resilient and robust it becomes. Each Nexus Wallet is a node, providing security and redundancy to the network, operated by individuals who are a part of the greater Nexus ecosystem.
To learn more about Nexus and to meet our community, please join one of our community channels, which can be found in the footer. Within the channels you will find many helpful and inspirational people.
To learn more about Nexus and to meet our community, please join one of our community channels, which can be found in the footer.
Nexus has adopted the Internet Engineering Task Force’s (IETF) time-tested open process through Working Groups. Our Working Group model connects a decentralized collection of people who work together to set standards or develop new components of our technology. The groups are open to anyone who would like to contribute to the research and development of Nexus.
Here, you can learn about the layers of the Nexus architecture that matter most to you, and design functions and features with our developers. A consistent connection between developers and users ensures the standards of the Nexus architecture are defined through consensus.
The current Nexus Working Groups are:
Please join one of our community channels to get involved in Nexus working groups.