Looking at the gargantuan market caps that the world’s biggest tech companies such as Facebook, Microsoft and Amazon have amassed, one wonders how they’ve managed to dominate within their respective environments, often in such a short period of time. Well it seems the answer lies — at least in part — in their ability to generate network effects.
Also known as ‘network externalities’ and ‘demand-side economies of scale’, network effects are observed when a technology becomes more valuable as more people use it. The telephone is an example of the network effect, whereby more users who purchase telephones make them more valuable to each user, without intending to do so. While two telephones can make only 1 connection, five telephones can make 10 connections, and twelve telephones can make 66 connections:
Of course, network effects don’t always hold, especially for non-tech services. A road, for example, does not get better as more cars use it; in fact, quite the opposite occurs! But the phenomenon is often observed when new technologies emerge. Facebook, for instance, became better as more users joined — the larger the user base, the more friend connections each user could make, and the more updates each user could see from friends and family.
In economic terms, the network effect is a positive externality that boosts the marginal utility to all network users as more users join the network. The has been captured by Metcalfe’s Law, which states that the value of a network is proportional to the square of the number of connected users in the network (n2). The law was found to hold for both Facebook and Tencent in a 2015 study by Zhang, Liu and Xu, which found that the value of both networks (as represented by revenue), was proportional to the square of their respective monthly active user numbers.
As far as blockchain technology is concerned, we should see powerful network effects emerging from this new architecture with greater user adoption.
The number of blockchain wallet users has been accelerating since 2012:
And during this time, many of the biggest cryptocurrency networks have shot up in value. Indeed, a June 2017 study published at the Journal of Electronic Commerce Research and Applications which analyzed Bitcoin, Ethereum and Dash networks according to the number of unique daily addresses that engage in transactions on the network, found that digital blockchain networks “appear to be following Metcalfe’s Law”.
And by the end of last year, Fundstrat’s Tom Lee devised a model based on Metcalfe’s Law to measure user growth by combining the number of unique Bitcoin addresses with the average USD-denomination transaction volume per address. Lee found that this method of tracking user growth was showing 94% correlation with the bitcoin price over the previous four years.
That said, blockchain network effects may also differ from what we’ve seen with other technologies to date. Joel Monegro’s blog post ‘Fat Protocols’, for example, suggested that whereas the internet captured value at the application level (for example, Facebook), blockchain is likely to capture value at the protocol level (Ethereum, Bitcoin). This is mainly attributed to the value of the shared data layer in blockchain protocols which enables a decentralized network to replicate and store user data, and thus creates “a more vibrant and competitive ecosystem of products and services on top.”
We are certainly seeing enormous divergence between the massive valuations of the biggest blockchain protocols (such as Ethereum), and the applications that are built on top of them. Whether this trend holds in the future remains to be seen at this early stage of blockchain’s development. But what we can observe with more confidence is the network effects being realized by Bitcoin.
Back in 2014, Ethereum founder Vitalik Buterin identified 12 separate network effects that may surface in cryptoeconomics, which he divided into four separate categories:
At this stage, Bitcoin and to a lesser extent, Ethereum, have exhibited the greatest visible positive network externalities. Taking Bitcoin as an example, network effects could transpire as follows:
Given the sheer number of cryptocurrencies out there, the competition to be the pre-eminent cryptocurrency is well and truly on. Despite its technical shortcomings, though, Bitcoin has taken the lead so far, as gauged by many of its dominant stats vis-à-vis other cryptos.
There are around 22 million Bitcoin user wallets in existence. The number of Bitcoin ATMs is growing rapidly (and easily outnumber ATMs services for other cryptos). And its market cap is nearly 50% that of the remaining cryptos combined. Futures contracts, advancing trading infrastructure and the potential introduction of an ETF in the near future also suggest that Bitcoin has already attained a resilient economic moat.
That said, comparing Bitcoin with similar ‘non-blockchain’ online payment methods suggests that it is yet to achieve a critical mass of users. Dwarfing Bitcoin’s 22 million user wallets, for example, PayPal has a whopping 237 million active account holders.
Perhaps one of the reasons why Bitcoin and Ethereum have not continued to increase in value this year, despite the increase in user numbers, is due to their well-publicized scaling issues. Negative externalities have resulted with greater network usage, as congestion on Bitcoin and Ethereum networks have surfaced on many occasions. As with our example of the road, network congestion is a negative externality, rather than a positive one, and should be resolved sooner rather than later to realize further network effects.
There are over 1700 cryptos being traded on exchanges. While the majority are likely to end up on the list of dead coins, the rapid growth of a competitor currency to Bitcoin or Ethereum could see a shift in the network value and usage, in which case network effects may not emerge. Of course, there doesn’t necessarily have to simply be one or two dominant cryptocurrencies. In the same way that many of us who have a Facebook account also have Instagram and Twitter accounts that serve different social media purposes, we might use Bitcoin and Ethereum alongside, say, Monero for privacy purposes.
Blockchain provides a shared view of truth among participants who enforce the same set of rules. But unlike other technologies, blockchain protocols can be forked, which means that developers can simply copy that shared view of truth, but then change the rules going forward to create a new protocol with better technology and/or economics. With fork competition, however, “the community of users/readers may be split among too many different ledgers (or cryptocurrencies) and fail to fully exploit positive network externalities.“
And as Equilibrium Labs chairman Teemu Päivinen suggested as a challenge to the concept of fat protocols, “if a protocol is “fat” and capturing a disproportionate amount of value, it’s likely ripe for a fork or a competitive protocol….In this way, I believe “fatness” to actually be an indication of inefficiency and/or some other advantage.”
Not every user that has created a Bitcoin wallet is a long-term user of the cryptocurrency. On the contrary, short-term investors looking to make a quick buck may have masked the true value of many cryptocurrencies, especially recently given the astronomical gains that have been made trading cryptocurrencies. Indeed, the huge sell-off we have experienced this year would support this view.
The fact that Bitcoin is yet to reach critical mass in terms of user adoption means that network effects could very well shift to another, more scalable cryptocurrency in the long run. It may well even be a fork of Bitcoin. At this stage, things remain up in the air, but during the coming months and years it will be undoubtedly fascinating to see how the cryptoeconomics evolve.
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