Smashing Atoms: The History of Uranium and Nuclear Power
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Smashing Atoms: The History of Uranium and Nuclear Power



The following content is sponsored by the Sprott Physical Uranium Trust

uranium and nuclear power infographic

The History of Uranium and Nuclear Power

Uranium has been around for millennia, but we only recently began to understand its unique properties.

Today, the radioactive metal fuels hundreds of nuclear reactors, enabling carbon-free energy generation across the globe. But how did uranium and nuclear power come to be?

The above infographic from the Sprott Physical Uranium Trust outlines the history of nuclear energy and highlights the role of uranium in producing clean energy.

From Discovery to Fission: Uncovering Uranium

Just like all matter, the history of uranium and nuclear energy can be traced back to the atom.

Martin Klaproth, a German chemist, first discovered uranium in 1789 by extracting it from a mineral called “pitchblende”. He named uranium after the then newly discovered planet, Uranus. But the history of nuclear power really began in 1895 when German engineer Wilhelm Röntgen discovered X-rays and radiation, kicking off a series of experiments and discoveries—including that of radioactivity.

In 1905, Albert Einstein set the stage for nuclear power with his famous theory relating mass and energy, E = mc2. Roughly 35 years later, Otto Hahn and Fritz Strassman confirmed his theory by firing neutrons into uranium atoms, which yielded elements lighter than uranium. According to Einstein’s theory, the mass lost during the reaction changed into energy. This demonstrated that fission—the splitting of one atom into lighter elements—had occurred.

“Nuclear energy is incomparably greater than the molecular energy which we use today.”

—Winston Churchill, 1955.

Following the discovery of fission, scientists worked to develop a self-sustaining nuclear chain reaction. In 1939, a team of French scientists led by Frédéric Joliot-Curie demonstrated that fission can cause a chain reaction and filed the first patent on nuclear reactors.

Later in 1942, a group of scientists led by Enrico Fermi and Leo Szilard set off the first nuclear chain reaction through the Chicago Pile-1. Interestingly, they built this makeshift reactor using graphite bricks on an abandoned squash court in the University of Chicago.

These experiments proved that uranium could produce energy through fission. However, the first peaceful use of nuclear fission did not come until 1951, when Experimental Breeder Reactor I (EBR-1) in Idaho generated the first electricity sourced from nuclear power.

The Power of the Atom: Nuclear Power and Clean Energy

Nuclear reactors harness uranium’s properties to generate energy without any greenhouse gas emissions. While uranium’s radioactivity makes it unique, it has three other properties that stand out:

  • Material Density: Uranium has a density of 19.1g/cm3, making it one of the densest metals on Earth. For reference, it is nearly as heavy (and dense) as gold.
  • Abundance: At 2.8 parts per million, uranium is approximately 700 times more abundant than gold, and 37 times more abundant than silver.
  • Energy Density: Uranium is extremely energy-dense. A one-inch tall uranium pellet contains the same amount of energy as 120 gallons of oil.

Thanks to its high energy density, the use of uranium fuel makes nuclear power more efficient than other energy sources. This includes renewables like wind and solar, which typically require much more land (and more units) to generate the same amount of electricity as a single nuclear reactor.

But nuclear power offers more than just a smaller land footprint. It’s also one of the cleanest and most reliable energy sources available today, poised to play a major role in the energy transition.

The Future of Uranium and Nuclear Power

Although nuclear power is often left out of the clean energy conversation, the ongoing energy crisis has brought it back into focus.

Several countries are going nuclear in a bid to reduce reliance on fossil fuels while building reliable energy grids. For example, nuclear power is expected to play a prominent role in the UK’s plan to reach net-zero carbon emissions by 2050. Furthermore, Japan recently approved restarts at three of its nuclear reactors after initially phasing out nuclear power following the Fukushima accident.

The resurgence of nuclear power, in addition to reactors that are already under construction, will likely lead to higher demand for uranium—especially as the world embraces clean energy.

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Ranked: Emissions per Capita of the Top 30 U.S. Investor-Owned Utilities

Roughly 25% of all GHG emissions come from electricity production. See how the top 30 IOUs rank by emissions per capita.



Emissions per Capita of the Top 30 U.S. Investor-Owned Utilities

Approximately 25% of all U.S. greenhouse gas emissions (GHG) come from electricity generation.

Subsequently, this means investor-owned utilities (IOUs) will have a crucial role to play around carbon reduction initiatives. This is particularly true for the top 30 IOUs, where almost 75% of utility customers get their electricity from.

This infographic from the National Public Utilities Council ranks the largest IOUs by emissions per capita. By accounting for the varying customer bases they serve, we get a more accurate look at their green energy practices. Here’s how they line up.

Per Capita Rankings

The emissions per capita rankings for the top 30 investor-owned utilities have large disparities from one another.

Totals range from a high of 25.8 tons of CO2 per customer annually to a low of 0.5 tons.

UtilityEmissions Per Capita (CO2 tons per year)Total Emissions (M)
OGE Energy21.518.2
AES Corporation19.849.9
Southern Company18.077.8
Alliant Energy14.414.1
DTE Energy14.229.0
Berkshire Hathaway Energy14.057.2
WEC Energy13.522.2
Duke Energy12.096.6
Xcel Energy11.943.3
Dominion Energy11.037.8
PNM Resources10.55.6
PPL Corporation10.428.7
American Electric Power9.250.9
Consumers Energy8.716.1
NRG Energy8.229.8
Florida Power and Light8.041.0
Portland General Electric7.66.9
Fortis Inc.6.112.6
Consolidated Edison1.66.3
Pacific Gas and Electric0.52.6
Next Era Energy Resources01.1

PNM Resources data is from 2019, all other data is as of 2020

Let’s start by looking at the higher scoring IOUs.


TransAlta emits 25.8 tons of CO2 emissions per customer, the largest of any utility on a per capita basis. Altogether, the company’s 630,000 customers emit 16.3 million metric tons. On a recent earnings call, its management discussed clear intent to phase out coal and grow their renewables mix by doubling their renewables fleet. And so far it appears they’ve been making good on their promise, having shut down the Canadian Highvale coal mine recently.


Vistra had the highest total emissions at 97 million tons of CO2 per year and is almost exclusively a coal and gas generator. However, the company announced plans for 60% reductions in CO2 emissions by 2030 and is striving to be carbon neutral by 2050. As the highest total emitter, this transition would make a noticeable impact on total utility emissions if successful.

Currently, based on their 4.3 million customers, Vistra sees per capita emissions of 22.4 tons a year. The utility is a key electricity provider for Texas, ad here’s how their electricity mix compares to that of the state as a whole:

Energy SourceVistraState of Texas

Despite their ambitious green energy pledges, for now only 1% of Vistra’s electricity comes from renewables compared to 24% for Texas, where wind energy is prospering.

Based on those scores, the average customer from some of the highest emitting utility groups emit about the same as a customer from each of the bottom seven, who clearly have greener energy practices. Let’s take a closer look at emissions for some of the bottom scoring entities.

Utilities With The Greenest Energy Practices

Groups with the lowest carbon emission scores are in many ways leaders on the path towards a greener future.


Exelon emits only 3.8 tons of CO2 emissions per capita annually and is one of the top clean power generators across the Americas. In the last decade they’ve reduced their GHG emissions by 18 million metric tons, and have recently teamed up with the state of Illinois through the Clean Energy Jobs Act. Through this, Exelon will receive $700 million in subsidies as it phases out coal and gas plants to meet 2030 and 2045 targets.

Consolidated Edison

Consolidated Edison serves nearly 4 million customers with a large chunk coming from New York state. Altogether, they emit 1.6 tons of CO2 emissions per capita from their electricity generation.

The utility group is making notable strides towards a sustainable future by expanding its renewable projects and testing higher capacity limits. In addition, they are often praised for their financial management and carry the title of dividend aristocrat, having increased their dividend for 47 years and counting. In fact, this is the longest out of any utility company in the S&P 500.

A Sustainable Tomorrow

Altogether, utilities will have a pivotal role to play in decarbonization efforts. This is particularly true for the top 30 U.S. IOUs, who serve millions of Americans.

Ultimately, this means a unique moment for utilities is emerging. As the transition toward cleaner energy continues and various groups push to achieve their goals, all eyes will be on utilities to deliver.

The National Public Utilities Council is the go-to resource to learn how utilities can lead in the path towards decarbonization.

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The Road to Decarbonization: How Asphalt is Affecting the Planet

The U.S. alone generates ∼12 million tons of asphalt shingles tear-off waste and installation scrap every year and more than 90% of it is dumped into landfills.



Road to Decarbonization - How Asphalt is Affecting the Planet

The Road to Decarbonization: How Asphalt is Affecting the Planet

Asphalt, also known as bitumen, has various applications in the modern economy, with annual demand reaching 110 million tons globally.

Until the 20th century, natural asphalt made from decomposed plants accounted for the majority of asphalt production. Today, most asphalt is refined from crude oil.

This graphic, sponsored by Northstar Clean Technologies, shows how new technologies to reuse and recycle asphalt can help protect the environment.

The Impact of Climate Change

Pollution from vehicles is expected to decline as electric vehicles replace internal combustion engines.

But pollution from asphalt could actually increase in the next decades because of rising temperatures in some parts of the Earth. When subjected to extreme temperatures, asphalt releases harmful greenhouse gases (GHG) into the atmosphere.

Emissions from Road Construction (Source) CO2 equivalent (%)
Asphalt 28%
Excavators and Haulers16%
Crushing Plant 10%
Galvanized Steel 6%
Reinforced Steel6%
Plastic Piping 2%

Asphalt paved surfaces and roofs make up approximately 45% and 20% of surfaces in U.S. cities, respectively. Furthermore, 75% of single-family detached homes in Canada and the U.S. have asphalt shingles on their roofs.

Reducing the Environmental Impact of Asphalt

Similar to roads, asphalt shingles have oil as the primary component, which is especially harmful to the environment.

Shingles do not decompose or biodegrade. The U.S. alone generates ∼12 million tons of asphalt shingles tear-off waste and installation scrap every year and more than 90% of it is dumped into landfills, the equivalent of 20 million barrels of oil.

But most of it can be reused, rather than taking up valuable landfill space.

Using technology, the primary components in shingles can be repurposed into liquid asphalt, aggregate, and fiber, for use in road construction, embankments, and new shingles.

Providing the construction industry with clean, sustainable processing solutions is also a big business opportunity. Canada alone is a $1.3 billion market for recovering and reprocessing shingles.

Northstar Clean Technologies is the only public company that repurposes 99% of asphalt shingles components that otherwise go to landfills.

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