Busting solar myths: Solar energy is too diffuse to be practical

Busting solar myths: Solar energy is too diffuse to be practical

Print Friendly, PDF & Email

There are several reasons why this argument just doesn’t work. No 1: Solar’s average energy output per square meter exceeds that of coal power plants.

Print Friendly, PDF & Email


One thing I find very odd about the world is that even today when solar panels are being installed from Canada to Tasmania and powering everything from laptops to fish tank filters to cars, there are still people who appear to wake up in the morning and decide that their mission for the day is to tell the internet that solar is too diffuse a source of energy to be practical. And while I have to admire the persistence of some of these people, I really can’t say I’m a big fan of their logic, their habit of rejecting evidence they don’t like, or their general lack of comprehension of the reality of how solar power is currently used in the world.

I will take it as read that the world’s most widely used source of electricity, coal power, is not too diffuse to be practical. If it was, we obviously wouldn’t be in the unfortunate position of using so much of it. So I will compare solar with coal and consider different ways of looking at how concentrated they are as sources of electricity.

Currently I am sitting in Adelaide in South Australia. The nearest coal mine to me is over 450 kilometers away as the crow flies or 561 kilometers as the crow drives. If I was to put a giant rubber ring around the state’s population center and then uniformly stretch it out until it included the closest source of coal it would cover over 640,000 square kilometres, giving my state’s coal power an average output of about 0.00033 watts per square meter. Meanwhile, just meters above my head, solar photons are silently banging against the roof right now and not at all annoying me with their non-loudness. The roof right above me is currently being hit with about 1,000 watts of sunshine per square meter. With 15% efficient solar panels that would come to an average output of about 30 watts per square meter at this location. This makes rooftop solar about 90,000 times less diffuse a source of electricity than the state’s coal power.

However, I doubt many people will think this is the right way to go about comparing them. I certainly don’t think that the people who say solar power is too diffuse to be practical will care that coal power often comes from a vast distance away while solar power is right here. So instead I will look at electricity produced per square meter of land dedicated to its production.

solar energy
On a typical display this represents about 6,500 watts per square meter.

Recently I wrote about how the Hazelwood coal power plant and its mine produced an average of about 32 watts per square meter, which is much lower than wind farms. Hazelwood is located in a very cloudy location for Australia, but if I covered its entire 3,554 hectares with commercially available, 20% efficient, Sunpower solar panels, it would produce kilowatt-hours equal to about 85% of Hazelwood’s current average output. If these solar panels were instead installed in a better location in the same state they would exceed Hazelwood’s average output and in a great deal of Australia they would almost double it.

Clearly solar power can’t be considered too diffuse if it is possible for its average output per square meter to exceed that of coal power plants. But this isn’t actually the right way to go about comparing coal and solar. This is because in Australia we almost never put solar panels on the ground. Apart from 10 megawatts in Western Australia and a few installations done by people who are afraid of heights, almost all of Australia’s approximately 2.2 gigawatts of solar capacity is mounted on roofs and doesn’t remove any land from its original use. This means that Australian solar power produces more than 50 times as much electricity per square meter of dedicated land than coal power.

While Australians are very disinclined to put solar panels on the ground, this is less true in places such as Europe and India but this still does not make solar power too diffuse to be practical. In the case of India, almost all of their solar capacity consists of low efficiency, thin-film solar panels mounted on the ground which produce much less electricity per square meter than any coal plant operating at its originally intended capacity. But despite this, India is now building solar farms that will produce electricity at a cost of about 12 cents a kilowatt-hour which is competitive with electricity from new coal plants. So while Indian solar takes up more land than coal per kilowatt-hour produced, it’s obviously not too diffuse to compete with it even when coal power is not paying anything close to the full cost of the harm it causes.

While looking at the area of land required is one way to consider how diffuse a source of electricity is, another is to study the average number of kilowatt-hours produced per kilogram of mass required. A rooftop solar system with 15% efficient panels that receives a not-particularly impressive average of 4.5 hours of sunlight a day will produce about 400 kilowatt-hours per kilogram of its total system weight over its lifetime. Whereas coal power, due to the massive amount of coal it burns, will only produce about 2 kilowatt-hours per kilogram of mass required. This makes electricity from rooftop solar approximately 200 times more concentrated a source of electricity than coal power. If the mass of the oxygen required to combust the coal is included then rooftop solar is about 400 times more concentrated.

So despite what you may occasionally see scrawled on the internet, in Australia and many other regions, solar power is a much more concentrated source of electricity than coal in terms of the amount of land it requires. And in India where solar power is more diffuse than coal in terms of land used, it is still competitive with new coal even when coal doesn’t pay anywhere near the full cost of its externalities. And in terms of kilowatt-hours produced per kilogram of mass required, solar power is a far more concentrated source of electricity than coal anywhere in the world and the only thing that can change that is if you make me include the mass of the sun in my calculations.

This article was originally published on CleanTechnica. Reproduced with permission
Print Friendly, PDF & Email

  1. Sopa 8 years ago

    Hi Ronald

    I am from a Developing country and its located around the equatorial belt. Al I can say is these people know that solar will eventually put them out of business or reduce their profits. Almost everything that is used today to help reduce carbon emissions, alleviate poverty and protect and sustainably use our limited natural resources tend to attract a lot of critique, many of which tend to be ‘antagonistic’ rather than ‘edify’. The only thing that I can point to is profit-maximisation. Such people do not deserve to be inhabitants of this community called Earth.

  2. Pete 8 years ago

    Storage is vital however, as no power is produced at night with Solar. The one advantage fossil fuels have. It will be an exciting day when solar thermal and storage costs start to seriously compete with fossil fuels however. Australia is perfect for solar thermal.

    • Ronald Brak 8 years ago

      Lower cost storage would be appreciated, but as the price of daytime electricity decreases more demand will shift to the day and Australia’s existing pumped storage capacity can be saved for the evening instead of being used in the afternoon as it often is now. So we can still eliminate a great deal of fossil fuel use without any new storage. I do think Australia will have more energy storage in the future, but with our current low wholesale electricity prices and high retail prices, it seems likely to me that it will be mostly home and business storage rather than utility scale storage.

  3. dallascaley 7 years ago

    There is one factor that has been left out of this comparison and that is the factor of how much power it takes to actually build the solar cells. I would like to see what this would do to the equation. For instance is it even feasible to replace fossil fuels with something like solar? will we run out of silicon to build the cells? I honestly don’t know the answer to this.

Comments are closed.

Get up to 3 quotes from pre-vetted solar (and battery) installers.