How to pronounce "scarcities"

The question I am most commonly asked about climate change

is should I be optimistic or pessimistic?

I thought about this question a lot.

My career has been at the intersection of climate science, technology,

policy and industry,

mostly working for you,

at one point working for a US president

and now as Chief Scientist and Chief Carbon Wrangler

at Carbon Direct.

At that intersection,

I think about that question in terms of energy flows

and carbon abatement options.

So I ponder a variant of that question,

how much energy should 10 billion people use?

I was first prompted to think about this question

by the late, great Richard Smalley.

Nanotechnologist, Nobel Prize-winning chemist,

co-discovered buckyballs.

Total mensch.

He gave an important and influential talk almost exactly 20 years ago,

in which he laid out the top ten challenges to humanity:

energy, water, food, poverty, the environment, health.

And then he said something kind of obvious.

All of these are energy challenges.

Water is the most straightforward.

Three quarters of the Earth's surface is covered with water.

It's too salty to drink or use.

The primary cost of desalination is energy.

Food. I like food.

Eighty percent of the food consumed around the world

moves through modern agriculture.

That means synthetic fertilizers, combines that harvest,

refrigeration, shipping -- they’re all energy.

Climate. That's my day job.

How do we go from 54 billion tons of greenhouse gases every year

to less than zero very quickly?

And so on.

Abundant clean energy can make progress against this whole list.

So Richard estimated what he thought it would take

for 10 billion humans to live more or less like the United States.

And his answer was: 60 terawatts.

Keep that number in your mind: 60.

For reference, today the world uses about 26 terawatts of energy.

About eight terawatts of that are electricity.

Now the urgency of climate means that we have to --

For all of the energy we use today and all future energy

really has to be abundant, sustainable and cheap.

Abundant, available where you want it, when you want it.

Everybody should have energy,

including the three billion people who use less electricity

than my refrigerator uses.

However, it should also be sustainable.

We can't emit a lot of greenhouse gases. We can't trash nature.

Ideally, it's cheap,

a lot cheaper than today.

Maybe half or a third of what the US pays.

That would be 20 dollars a megawatt-hour or a dollar a gigajoule.

And remember it's energy, not electricity.

We also need heat for heavy industry.

We need clean fuels,

things like clean hydrogen or sustainable aviation fuels.

Well, that seems hard.

And it is.

But if you know that’s what you need or what you want --

abundant, sustainable, cheap energy --

we have a new question to ponder.

How do we get 60 terawatts of that to 10 billion people?

Well, the good news is

every day the Earth receives 163,000 terawatts of energy from the sun.

About half of that bounces back to space,

but about 80,000 terawatts arrive at the Earth in a form we can use.

For example, the air, land and oceans convert some of that

into about 870 terawatts of wind.

These are bigger numbers than 60,

and we've got more than solar and wind.

We have geothermal, we have hydro, we have nuclear.

There's other kinds of clean energies,

and some of the best resources are, in fact, in the global South.

These places are not simply future climate victims.

These places are latent energy superpowers.

And we've made some good starts.

Let's look at Chile,

blessed with abundant hydro, solar and wind.

They can make green electrons on demand.

A lot of those green electrons

are going to get turned into hydrogen and ammonia,

the key ingredient for fertilizer,

itself a good fuel and a great way to move clean energy around the world.

Now Chile has prioritized using these green electrons and hydrogen

to decarbonize its own grid

and for domestic energy use, for things like mining.

They are also building infrastructure.

They're building out the grid and ports for trade and commerce.

This prioritization, this emphasis on infrastructure

is the difference between a neocolonial economy

and a new economy built on abundance.

Let's go to Kenya,

home of the second most productive wind farm on Earth in Lake Turkana,

home of the second largest geothermal program on Earth

and future home of the Great Carbon Valley,

where this abundant, sustainable, cheap energy

will create whole new industries and pull CO2 out of the sky.

Now those are good starts.

But we have far, far to go.

Hashtag “WeNeedMore.”

Specifically, we need new investment vehicles,

and we need development mechanisms

that recognize the opportunity of abundance

as opposed to being built on the scarcities of the past.

My favorite example, Namibia.

A young, rapidly growing nation full of promise.

One of the very driest places on Earth.

Namibia has excellent solar and wind resources,

in particular in the southwest.

Unsurprisingly, a giant 10-billion-dollar project

is bouldering along

that will land 3,000 megawatts of solar on the ground,

3,000 megawatts of wind

that will feed 3,000 megawatts of electrolyzers

that will make clean hydrogen and ammonia for export to Europe,

and European countries and European industries

are providing the long-term offtakes.

In addition, the port of Lüderitz is getting an upgrade

and there's going to be jobs and wealth creation in Namibia.

I love this project. What's not to like?

Namibia gets wealth and jobs.

Europe gets clean, secure energy supplies.

Still something's off.

That's it. This project is ten times bigger

than Namibia's whole grid.

And this project will not substantially build out

the infrastructure or energy access.

No refrigerators, no new course as a nation.

Now again, this is a great project.

But how can we do even better?

Not just here, but everywhere.

How do we harness abundant, sustainable, cheap energy for all?

Well, there's three ingredients to that bouillabaisse.

And if you plan to harvest abundance,

you act differently in each.

First out of the gate -- infrastructure.

We need transmission lines, roads, ports, railroads, fueling stations.

We're not moving bits.

We're moving molecules and electrons.

We need this infrastructure

to get electricity to the people of Namibia

and to get clean fuels out of ports like Mombasa or Cartagena.

These projects take time, money and people.

We need to develop the human capital

as part of these investment projects for decades.

Because remember, children, for the rest of our lives,

every week is infrastructure week.

(Laughter)

Second out of the gate -- innovation.

We need much more energy in many places, much cheaper.

That's an innovation agenda.

Now you all are familiar with the profound and rapid decreases in cost

associated with solar photovoltaics.

That was a combination of sustained investment in innovation,

plus market-aligning policies,

plus mass-manufacturing.

For solar, that was the United States, Germany, China and others acting together.

Well, if that's the recipe, we can do that again.

We're already doing it

with electric vehicles and clean hydrogen production.

We can certainly do it by turning electricity into fuels

and pulling CO2 out of the sky.

In fact, the CO2 and clean hydrogen will be the next generation

of sustainable maritime and aviation fuels.

We can go way farther with solar, with perovskites,

with multi-exciton technologies like supermolecules

we can double or even triple the output.

We just had fusion!

(Laughter)

In California!

Now to harness that abundance, an objective should be cost reduction,

maybe 50 or even 80 percent cost reduction.

And those objectives should be part of the goals

of the institutions that run innovation,

for example, the US Department of Energy's Earthshot programs.

Third,

investment.

Specifically, we need to move away from single-project finance

to more systemic investment mechanisms,

one that reimagine risk across multiple projects,

multiple investment cycles and multiple years,

some of the goals of the audacious and overdue Bridgetown Initiative.

In addition, the full value chain should be part of the investment thesis.

Revenues come from many sources,

including the infrastructure itself,

the equipment sales, the new products

and the improvements for health and welfare.

Global positive investment,

global positive growth that yields solid returns.

Now in the case of Chile,

Japan is a key partner

and Japanese firms will make money on turbines, electrolyzers, ships,

infrastructure, debt.

Now one green hydrogen project is not enough money to do that.

You need, you know --

to rebuild shipyards and supply chains, you need more than one project.

So the Japanese government has in fact backed dozens of projects.

And these are anchored by bilateral agreements

between Chile and Japan

that include long-term offtakes.

Multiple projects and long-term offtakes

change the value propositions for both countries.

You're not feeding a set of shareholders, you're feeding two nations.

And Chile has maintained its commitment to this now

through three successive governments.

So let's go back to Namibia.

Here's the grid today.

Instead of conventional project finance for one project,

what would a 100-billion-dollar set of projects look like?

Well, for starters, you'd sure have to build out the grid a lot.

You'd have to add solar and wind, maybe supersize some projects,

maybe add some hydropower.

Instead of temporary construction jobs in Lüderitz,

you'd have a permanent construction industry there,

and you'd be building electrolyzers all over Namibia.

That would anchor supply chains across Sub-Saharan Africa,

and you'd train a generation of workers.

That would be big enough for desalination,

bringing fresh water to the desert and to the communities

and to the new industries.

Big enough for hospitals, universities, regional logistics hubs.

Big enough to encourage good governance

and, best of all, low-cost clean fertilizer

that could be used to make food in Namibia sold there and to its neighbors.

In effect, Namibia could be a global anchor for food and fuel,

and the investors will get a solid return.

Now that's a future to be optimistic about.

Because let's be honest, whether I'm optimistic or not,

the work looks the same.

So,

let's reimagine that first question.

It doesn't matter whether I'm optimistic or you're optimistic.

It matters if we're optimistic.

Collective action, building together is what makes the difficult possible

and nourishes the soul through a mission and purpose.

And we have a lot to be optimistic about.

Infrastructure, innovation and investment

are commitments to the future anchored in optimism.

We also have the tools and tech we need.

We know what to do

and we can act not out of anger or fear,

but out of generosity and common purpose,

bringing aspiration and humility together.

We're going to build a thriving, vibrant,

exciting world full of generosity and full of potential

that's going to be built on the back

of infrastructure innovation and investment

that will harness the abundant, sustainable, cheap energy

that is our planet's endowment.

Thank you.

(Applause and cheers)