Where will be able to fuel my vehicle with hydrogen and at what price?

There is a broad scientific consensus that we are witnessing global warming forced by the greenhouse gases emitted into the atmosphere by human activity. Based on this evidence, young people worldwide have mobilised to demand more facts and less rhetoric and posturing from political leaders. They are not without reason, and their protest has gained a great deal of social support. The time for action has come, but are we aware of the nature and true scale of the challenge ahead?

The first step to solving a problem is to formulate it correctly. And to this end we must have present that the CO₂ emitted by human activity is related to four variables, considered on a global scale: 1) the population; 2) GDP per capita; 3) energy used per GDP unit (or energy intensity); and 4) the CO₂ emissions emitted per energy unit consumed (or carbon intensity). From the figure resulting from the multiplication of these four factors, we must subtract the amount of CO₂ that once emitted, we can remove from the air, either by natural means (for example, by avoiding deforestation and encouraging reforestation) or artificial means (using diverse engineering techniques, more or less developed and costly) that would allow CO₂ to be removed from the air and subsequently reused within the framework of a circular economy scheme. 

This leads us to recognise two major components, of a very disparate nature, in the phenomenon of global warming. On the one hand, the first two factors (population and GDP per capita) are related to the current socio-economic model, which postulates unlimited demographic and economic growth, while the last two (energy intensity and carbon intensity), together with the component of removal and use of CO₂ emitted, are related to a certain energy model and level of technological development that make the objectives of demographic and economic growth possible. 

We are, therefore, facing a systematic challenge, whose solution would require not only influencing (as is commonly believed) energy and technological aspects but also the current socio-economic model. A theoretical approximation that clashes with a harsh reality: the global demographic and economic trends point to continued growth in the next few decades. 

In demographics, the world population is expected to reach 9.144 billion people in 2040, compared to 7.421 billion in 2016. Another particularly striking figure of these forecasts is that in 2040 64% of the world population will be concentrated in urban areas, compared to 54% in 2016; a percentage, the former, which may exceed or approach 80% in regions such as North America, Central and South America, and the EU, as well as in countries such as the US, Brazil, Russia, and Japan. We find ourselves before a process that adds to the global urban population a city the size of Singapore every four months.

And in terms of global economic growth, an average compound annual GDP growth rate of around 3.4% is expected for the period 2016-2040, with the highest growth rates concentrated in Africa (4.3%) and above all in the Asia-Pacific region (4.5%), and the lowest in the industrialised OECD countries. Another interesting element linked to the global economic growth is the forecast that the middle class will expand globally, increasing around 80% by 2030 and surpassing 5 billion people, with the majority of said growth coming from countries not part of the OECD. 

Faced with the difficulty of reversing such trends, the international community has decided to focus on a new energy transition capable of decoupling economic and demographic growth from rising energy demand and greenhouse gas emissions. To achieve it, we have three tools: efficiency, decarbonisation, and removal and use of CO₂. However, the global data in 2018 show that the sum of actions in these three areas has not even been able to stabilise emissions compared to 2017. The emissions continue to increase, driven by economic and demographic growth. And if that weren’t enough, in the absence of disruptive scientific and technological breakthroughs, the energy transition is unlikely to be as smooth and fast as would be desirable.

We hear a lot about energy transition. But almost always with excessively specific or very partial approaches. It is therefore worth reflecting on the meaning of the concept in its broadest sense.

There is now a broad scientific consensus that since the industrial revolution, and particularly since the mid-20th century, humans have forced global warming beyond natural climate cycles. This means that the time has come to find ways to "regulate the thermostat" using our ingenuity and cooperative skills. The question is how. To answer this question, it is important to remember that the first step in solving a problem is to formulate it correctly. In this regard, it should not be forgotten that global warming is related to three main groups of factors: 1) socio-economic (demographic and economic growth); 2) energy model (energy intensity and carbon intensity) and 3) amount of CO2 that once emitted can be removed from the atmosphere by natural and/or technological means. 

From this perspective, it is clear that global warming is an unexpected dysfunction of the current socio-economic model, of the energy model that sustains it, and of our level of technological development that prevents us from remedying the problem satisfactorily and urgently.  We are facing a systemic challenge and we have to ask ourselves what we can do about it. On the one hand, we know that focusing our action on socio-economic factors is unrealistic, but on the other hand, future projections tell us that demographic and economic growth trends will contribute to increasing greenhouse gas (GHG) emissions, i.e. worsening global warming. So we have no choice but to try to compensate for this deterioration through a radical improvement in the energy model and significant, disruptive advances in technological innovation.

The energy transition therefore entails: 1) decoupling demographic and economic growth from the increase in CO₂ and other GHG emissions; 2) moving rapidly towards a low energy intensity (efficient) and decarbonised economy (driven by a low carbon mix); and 3) deploying, on a large scale, technologies that enable the removal and reuse of carbon from the atmosphere, fostering a circular CO₂ economy to convert, after economic valorisation, current waste into a resource. 

An epic task that requires a grand pact or coalition, based on science and technology, including governments, financial institutions, investors, companies, and all social sectors and citizens committed to the fight against climate change.