= "a distributed cryptographic ledger shared amongst all nodes participating in the network, over which every successfully performed transaction is recorded". [1]

Description

1. by Jacob Aron:

"The true innovation of Bitcoin's mysterious designer, Satoshi Nakamoto, is its underlying technology, the "block chain". That fundamental concept is being used to transform Bitcoin – and could even replace it altogether.

So what is the block chain? It is a ledger of transactions that keeps Bitcoin secure and allows all users to agree on exactly who owns how many bitcoins. Each new block requires a record of recent transactions along with a string of letters and numbers, known as a hash, which is based on the previous block and produced using a cryptographic algorithm.

Miners, people who run the peer-to-peer Bitcoin software, randomly generate hashes, competing to produce one with a value below a certain target difficulty and thus complete a new block and receive a reward, currently 25 bitcoins. This difficulty means faking a transaction is impossible unless you have more computing power than everyone else on the Bitcoin network combined. Confused? Don't worry, ordinary Bitcoin users needn't know the details of how the block chain works, just as people with a credit card don't bother learning banking network jargon. But those who do understand the power of the block chain are realising how Nakamoto's technology for mass agreement can be adapted. "You can replace that agreement with all sorts of different things and now you have a really powerful building block for any kind of distributed system," says Jeremy Clark of Concordia University in Montreal, Canada." (http://www.newscientist.com/article/mg22129553.700-bitcoin-how-its-core-technology-will-change-the-world.html)

2. Primavera De Filippi

"For many, bitcoin — the distributed, worldwide, decentralized crypto-currency — is all about money … or, as recent events have shown, about who invented it. Yet the actual innovation brought about by bitcoin is not the currency itself but the platform, which is commonly referred to as the “blockchain” — a distributed cryptographic ledger shared amongst all nodes participating in the network, over which every successfully performed transaction is recorded.

And the blockchain is not limited to monetary applications. Borrowing from the same ideas (though not using the actual peer-to-peer network bitcoin runs on), a variety of new applications have adapted the bitcoin protocol to fulfill different purposes: Namecoin for distributed domain name management; Bitmessage and Twister for asynchronous communication; and, more recently, Ethereum (released only a month ago). Like many other peer-to-peer (P2P) applications, these platforms all rely on decentralized architectures to build and maintain network applications that are operated by the community for the community. (I’ve written before here in WIRED Opinion about one example, mesh networks, which can provide an internet-native model for building community and governance).

Thus, while they enable a whole new set of possibilities, blockchain-based applications also present legal, technical, and social challenges similar to those raised by other P2P applications that came before them, such as BitTorrent, Tor, or Freenet."

Discussion

Zacqary Adam Green:

"Bitcoin’s real contribution to the world is its source code. The blockchain, the network protocol, the cryptographic verification — anyone can take this and build a currency with any economic properties their community needs. I’m not convinced that bitcoin’s Austrian School properties can sustain a global (or even local) economy, but you know what? That’s okay. If I ever feel the bitcoin economy has become too unequal, unbalanced, or stagnant, it’s now trivial for me to start my own damn currency.

A single bitcoin belongs is a measurement like a centimeter, but the bitcoin community is a social network. People use bitcoin because other people they trade with use bitcoin. If my town is running low on bitcoin but has a lot of resources to share internally, we can create our own local currency to free up bitcoin for importing and exporting. Or I could join an online network of artists who work on one another’s projects, and we’d create our own internal currency that plays by whatever rules we need it to.

There is no perfect monetary system for every situation. Bitcoin is not going to be the one world currency, and it doesn’t need to be. A lot of people compare Bitcoin to the Internet, but it’s more like CompuServe. It’s the first of many digital, non-state currencies to come, that will all interoperate with each other in ways we can’t even dream of yet." (http://falkvinge.net/2013/11/06/bitcoins-real-revolution-isnt-hard-money-its-economic-panarchy/ )

Examples

BY PRIMAVERA DE FILIPPI:

"the blockchain is not limited to monetary applications. Borrowing from the same ideas (though not using the actual peer-to-peer network bitcoin runs on), a variety of new applications have adapted the bitcoin protocol to fulfill different purposes: Namecoin for distributed domain name management; Bitmessage and Twister for asynchronous communication; and, more recently, Ethereum (released only a month ago). Like many other peer-to-peer (P2P) applications, these platforms all rely on decentralized architectures to build and maintain network applications that are operated by the community for the community." (http://www.wired.com/2014/03/decentralized-applications-built-bitcoin-great-except-whos-responsible-outcomes/)

Ethereum

"One of those tapping into its power is Vitalik Buterin, a 19-year-old developer from Toronto, Canada. Last week he launched Ethereum, a new platform that will not just allow for multiple cryptocurrencies, as they are known, but also promises to host a range of decentralised applications on a single block chain. Making systems decentralised is appealing because the authorities will find them hard to shut down.

Initially, Ethereum users will be able to exchange bitcoins for a new currency – ether. Then, ether will be mined just like Bitcoin. But acquiring another form of digital money is not the point. Ethereum is meant to work like an operating system for cryptocurrencies. Developers can create apps, such as social networks or file storage, that sit on Ethereum's network as part of an app store.

Ethereum allows for the creation of complex, yet decentralised, economic tools like financial derivatives, in which two parties can bet on the rise and fall of an asset, or crop insurance that pays out to a farmer according to a weather data feed. Creating decentralised versions of Dropbox or eBay should be possible too, claims Buterin.

Other developers are attempting to achieve the same results by overlaying new code on the existing Bitcoin block chain. One example is the concept of "coloured" coins: with bitcoins labelled to represent other assets such as gold, cars or even houses, you transfer ownership when you trade the labelled coin.

Buterin says Ethereum is much more flexible. "Bitcoin is great as a form of digital money, but its scripting language is too weak for any kind of serious advanced applications to be built on top." (http://www.newscientist.com/article/mg22129553.700-bitcoin-how-its-core-technology-will-change-the-world.html)

Decentralized Autonomous Corporations

"One of the more advanced concepts being touted for a next-generation Bitcoin is the idea of decentralised autonomous corporations (DAC) – companies with no directors. These would follow a pre-programmed business model and are managed entirely by the block chain. In this case the block chain acts as a way for the DAC to store financial accounts and record shareholder votes.

In a way, Bitcoin is actually the first DAC, says Daniel Larimer, a developer in Blacksburg, Virginia. People who own bitcoins are shareholders in the company, which offers financial services, earns revenue through transaction fees and pays a salary to its employees, the miners. But no one is in charge.

Larimer has started his own DAC, called BitSharesX, which he says can perform the actions of a bank, lending other currencies to customers, who can provide BitShares as collateral. Other potential business models for a DAC include election services and lotteries, all run automatically. "The key to a DAC is that it should not depend on any one person." (http://www.newscientist.com/article/mg22129553.700-bitcoin-how-its-core-technology-will-change-the-world.html)

Discussion

The Bitcoin Protocol Is More ‘Cloud’ Than ‘P2P’

BY PRIMAVERA DE FILIPPI:

"For many, bitcoin — the distributed, worldwide, decentralized crypto-currency — is all about money … or, as recent events have shown, about who invented it. Yet the actual innovation brought about by bitcoin is not the currency itself but the platform, which is commonly referred to as the “blockchain” — a distributed cryptographic ledger shared amongst all nodes participating in the network, over which every successfully performed transaction is recorded.

And the blockchain is not limited to monetary applications. Borrowing from the same ideas (though not using the actual peer-to-peer network bitcoin runs on), a variety of new applications have adapted the bitcoin protocol to fulfill different purposes: Namecoin for distributed domain name management; Bitmessage and Twister for asynchronous communication; and, more recently, Ethereum (released only a month ago). Like many other peer-to-peer (P2P) applications, these platforms all rely on decentralized architectures to build and maintain network applications that are operated by the community for the community. (I’ve written before here in WIRED Opinion about one example, mesh networks, which can provide an internet-native model for building community and governance).

Thus, while they enable a whole new set of possibilities, blockchain-based applications also present legal, technical, and social challenges similar to those raised by other P2P applications that came before them, such as BitTorrent, Tor, or Freenet. But some of these challenges haven’t been seen before in the context of traditional P2P networks.

Although all blockchain-based applications are based on a decentralized network architecture, most of these applications distinguish themselves from standard P2P applications in at least two ways:

Users’ data (including personal data) are not stored locally into users’ devices. They subsist “in the cloud”, in the sense that they are hosted in a distributed database — the blockchain in this case — that is shared amongst all users in the network. This means that data is ubiquitous: It can be accessed at anytime and from anywhere, regardless of the user’s device. But the data is also more transparent: All actions or transactions performed by users are recorded on the blockchain and thus publicly available to everyone (although the identity of users can be kept secret and the content of such transactions can of course be encrypted).

Instead of being run locally, blockchain-based applications operate globally. They are deployed on the blockchain itself and are run — in a distributed manner — by relying on the resources provided by all users connected to the network. Although each client runs locally on the user’s device, these applications are constantly available, even when individual devices are turned off (as long as there are enough resources dedicated to them).

In this sense, blockchain-based applications are — in spite of their inherently decentralized nature — more similar to cloud-based services than traditional P2P applications.

However, these applications do significantly differ from traditional cloud-computing applications in that they are autonomous and independent from any central server or authority in charge of regulating or managing the network. Applications are run through an aggregate of individual, peer-to-peer clients that contribute their own resources to the network. In addition to being autonomous, the network is also more resilient and anonymous: no single point of failure, no single point of control.

We need to make sure we don’t exchange the tyranny of large online operators for the “tyranny of code” instead. As such, the bitcoin platform (or blockchain) allows for the deployment of decentralized applications that combine the benefits of cloud computing — in terms of ubiquity and elasticity — with the benefits of P2P technologies in terms of privacy and anonymity. Even though the blockchain is inherently transparent (as every transaction is recorded on a public ledger), users can have multiple identities that don’t necessarily relate to their real persona.

Blockchain-based applications can therefore address user’s privacy through anonymity." (http://www.wired.com/2014/03/decentralized-applications-built-bitcoin-great-except-whos-responsible-outcomes/)

What Are the Challenges?

BY PRIMAVERA DE FILIPPI:

"In general, most challenges encountered by decentralized network applications are related to the limited availability of resources and the inherent difficulty of managing and coordinating them.

Long-term sustainability can only be achieved by providing an incentive for users to contribute to the network — for altruistic to selfish reasons — so that there are always a sufficient amount of resources available at any given time. In the case of decentralized applications featuring a specifically designed credit system (such as bittorrent) or assuming the function of a cryptocurrency (such as bitcoin, namecoin, and ethereum), this objective is much easier to achieve to the extent that these platforms provide an additional economic and/or utilitarian incentive for users to contribute to the overall operations of the network.

But blockchain-based applications raise important legal challenges, too. The challenges similar to those raised by traditional P2P networks is that the anonymity inherent in these networks supports or even encourages criminal behaviors and other illicit or reprehensible activities.

In previous decentralized networks, these issues were dealt with by establishing shared or distributed liability amongst all users connected to the network. Even though it’s often difficult to determine identity and assess the degree of responsibility each should be held accountable for, there are always specific individuals to blame. (Ultimately, the difficulty lies in assigning more or less responsibilities to one or more users in the network.)

So what happens when the figure of the “user” itself disappears; when the resulting P2P applications live outside a central authority? Who is liable and accountable? While we can borrow lessons learned from the world of previous P2P applications to respond to some of these challenges, it cannot be denied that blockchain-based applications raise new and important legal issues — and of a completely different kind than those found in traditional P2P architectures." (http://www.wired.com/2014/03/decentralized-applications-built-bitcoin-great-except-whos-responsible-outcomes/)

Towards an internet of (block)chains

John Robb:

"The future of the Internet is a confederation of chains.

Chains that'll do almost everything.

Chains that act like companies (without any of that "organic and financial overhead" that costs us so much).

Chains that cut across borders.

Chains for closed social networks. Chains for virtual legal systems. Chains for industries...

Even chains for global insurgencies and alternative economies (the topic of my new book).

Lots of chains.

It's inevitable at this point. Bitcoin was simply the plausible promise of what was possible with this tech.

I'm also getting a very good feel for how this is going to roll out and what I'm seeing is pretty cool.

How so?

The rollout of these blockchains is going to be full on creative destruction.

Chains will generate or control more wealth in the next two decades than the world has produced since inception.

They also enable us to destroy wealth with equal alacrity by allowing us to shift our thinking on what we consider valuable (to the old and currently wealthy --> you are toast). " (http://globalguerrillas.typepad.com/globalguerrillas/2014/10/the-internet-of-chains.html)

More Information

1. Blockchain Companies
2. Internet of Chains