Tag Archives: Renewable Energy

ENERGY: Coal use in the United States drops, clean energy use rises

Posted on by
1

Image via the russians are here on Flickr

It seems that the United States is shifting away from coal energy and moving towards sustainable, more rational energy sources.

Utilizing more clean energy into our energy mix while moving away from fossil fuels is a commonsensical energy policy, because fossil fuels are nonrenewable, exhaustible, and unsustainable; contribute to climate change; contribute to rising public health costs; pollute the environment; and are subject to volatility. As a result, an energy policy based largely on fossil fuels is imprudent and a national security nightmare. Furthermore, solar energy is the only energy source that can keep up with human consumption. More via The Huffington Post:

In the first quarter of 2012, coal made up just 36 percent of U.S. electricity generation – down from nearly 45 percent from the same period in 2011. That’s a 9 percent drop in U.S. coal use in just one year.

The report, released this week by the U.S. Energy Information Administration (EIA), had even more bad news for big polluters. Electricity generation from coal may drop another 14 percent this year. The EIA also believes coal production will decline 10 percent in 2012.

Meanwhile, wind energy is thriving. In the first quarter of 2012, the U.S. installed 1,695 megawatts of wind, one of the industry’s best quarters ever, up 53 percent from the same time last year, according to the American Wind Energy Association (AWEA). Wind projects are creating jobs and economic opportunity across the country, with 32 new projects installed in 17 states in the first quarter alone.

Hat tip to Jerry Greer

ENERGY: Michigan Public Service Commission: Renewables cheaper than coal

Posted on by
2

Image: Wind turbine, Pigeon, Michigan. Image via ~Jetta Girl~ on Flickr

The Michigan Public Service Commission, which is a public utilities commission that regulates entities such as natural gas companies and electric utilities, “has released its annual checkup [PDF] on the implementation of the state’s Renewable Energy Standard and its cost effectiveness.”

According to the Commission, renewables are cheaper than coal per megawatt hour, and Michigan “is on track to meet its RES of 10 percent by 2015.” However, the Commission warns that, although Michigan will meet its renewable energy standard targets by 2015, the state will lag behind other states that have set higher renewable targets. More via Midwest Energy News:

The PSC has released its annual checkup [PDF] on the implementation of the state’s Renewable Energy Standard and its cost effectiveness. The highlights include:

  • More than $100 million in investments on advanced energy projects from 2008-2011, with job creation as an additional benefit;
  • An average cost for renewables of $91.19 per megawatt hour, compared to $133 per megawatt hour for a new coal plant.

That’s almost 42 bucks less per megawatt hour for cleaner energy sources like wind and solar, without nasty downsides like respiratory illness and mercury pollution.

Continue reading this article at Midwest Energy News.

ENERGY: Is the nuclearization of energy sources a prudent investment?

Posted on by
Reply

Image via Clay Bennett

Personally, I’m not against using nuclear energy sources to meet energy demand and to reduce carbon emissions. However, since there are significant drawbacks to nuclear power, I do not believe that the nuclearization of energy sources, or substantially increasing the number of nuclear power stations to meet energy demand and to reduce carbon emissions, represents prudent energy policy. I’ve outlined the significant drawbacks to nuclear power before:

[T]he Republican Party believes that “the best way for utility companies to reduce carbon emissions is to increase their supply of nuclear energy.” However, nuclear power isn’t cheap, and the costs associated with constructing new nuclear power plants have skyrocketed. There are also substantial costs associated with decommissioning nuclear power plants (“it may cost $300 million or more to shut down and decommission a plant“). Other negatives associated with nuclear power production include the fact that the nuclear power industry depends solely on a nonrenewable energy source, and there’s the well-known problem of storing nuclear waste. Also, “the process of thermoelectric generation from fossil fuels such as coal, oil, and natural gas, as well as nuclear power, is water intensive. In fact, each kWh generated requires on average approximately 25 gallons of water to produce.” Therefore, drought could force nuclear power plants to shut down. What’s more, there are past and present safety concerns with nuclear power production. Recently, the nuclear power industry has been plagued by safety problems at the Vermont Yankee Nuclear Power Plant. Certainly, if the costs associated with decommissioning nuclear power plants, with the management of nuclear power plants, and with the disposal of nuclear waste are considered, then both solar and wind power are substantially cheaper than nuclear power.

Shouldn’t the massive costs associated with nuclear power construction, production, and decommissioning be invested into renewable energy research and production and into research and technologies related to energy storage, grid modernization, and energy conservation. According to Nathan Lewis, “To get the 10 terawatts we need to stay on the ‘business-as-usual’ curve, we’d need 10,000 of our current one-gigawatt reactors, and that means we’d have to build one every other day somewhere in the world for the next 50 straight years.” Lewis also points out that “one hundred twenty thousand terawatts of solar power hits the earth . . . It is the only natural energy resource that can keep up with human consumption.” More via an earlier post on the Conservation Report:

Nathan Lewis provides a gloomy but sobering assessment of the challenges humanity will face in meeting its future energy needs (emphasis added):

Energy is the single most important technological challenge facing humanity today. Nothing else in science or technology comes close in comparison. If we don’t invent the next nano-widget, if we don’t cure cancer in 20 years, like it or not the world will stay the same. But with energy, we are in the middle of doing the biggest experiment that humans will have ever done, and we get to do that experiment exactly once. And there is no tomorrow, because in 20 years that experiment will be cast in stone. If we don’t get this right, we can say as students of physics and chemistry that we know that the world will, on a timescale comparable to modern human history, never be the same.

The currency of the world is not the dollar, it’s the joule.

.       .       .

Humanity’s current energy consumption rate is 13 trillion thermal watts, or 13 terawatts.

.       .       .

The United States consumes a quarter of the world’s energy, at a rate of about 3.3 terawatts[.]

.       .       .

With population and GDP growth conspiring together, we would then obtain a tripling of energy demand by 2050. This is partly mitigated, however, by the fact that we’re using energy more efficiently per unit of GDP. The ratio of energy consumption to GDP has been declining at about 1 percent, globally averaged, per year. The United States actually saves energy at a faster rate, about 2 percent per year. Because we have such a high per-capita energy baseline consumption, it is easier for us to save off that base, whereas the developing countries save less. The “business as usual” scenario assumes that this will continue, and if we project that down, we will achieve an average energy consumption of two kilowatts per person within our lifetimes. (The United States now uses 10 kilowatts per person.) But factor in population growth and conservative economic growth, and we’ll still need twice as much energy as we need now.

In terms of average thermal load, a person on a 2,000-calorie-per-day diet is basically a hundred-watt lightbulb. And in our highly mechanized western agricultural system, the energy embedded in food—to run the farm and grow the food and transport it to the supermarket and put it in the refrigerator—is 10 to 20 times the energy content of the food itself. And the farther you live from the food source, the more embedded energy you consume. If we are 100-watt lightbulbs, this means that just keeping us fed requires one to two kilowatts.

.       .       .

Ice cores taken near Vostok Station, Antarctica, show that the CO2 level has been in a narrow band between 200 and 300 parts per million by volume (ppmv) for the last 425,000 years; data from other cores have extended this back to 670,000 years. Current CO2 levels are about 380 ppmv. “Business as usual” will require 10 trillion watts, 10 terawatts, of carbon-free power, and it never stabilizes CO2 levels—they just keep going up. So even on that track, we are betting against data that goes back for almost a million straight years, and hoping that this time, we get lucky.

.       .       .

[U]nfortunately, there is no natural destruction mechanism for carbon dioxide in our atmosphere. Unlike ozone depletion, it will not heal by itself through chemical processes. In our highly oxidizing atmosphere, CO2 is an end product. The lifetimes of CO2 in the atmosphere are well known, and the time for 500 to 600 ppmv of CO2 to decay back to 300 ppmv is between 500 and 5,000 years. Which means that the CO2 we produce over the next 40 years, and its associated effects, will last for a timescale comparable to modern human history. This is why, within the next 20 years, we either solve this problem or the world will never be the same. How different that world will be, we won’t know until we get there.

If we want to hold CO2 even to 550 ppmv, even with aggressive energy efficiency we will need as much clean, carbon-free energy within the next 40 years, online, as the entire oil, natural gas, coal, and nuclear industries today combined—10 to 15 terawatts. This is not changing a few lightbulbs in Fresno, this is building an industry comparable to 50 Exxon Mobils. Furthermore, if we wait 30 years, the amount of carbon-free energy we’ll need will be even greater, and needed even faster, because in the meantime we will have put out 30 years of accumulated CO2 emissions that will not go away for centuries to millennia. So stabilizing at 550 ppmv will then require about 15 to 20 terawatts of carbon-free power in 2050.

.       .       .

So let’s look at carbon-neutral energy sources. We could go nuclear, which is the only proven technology that we have that could scale to these numbers. We have about 400 nuclear power plants in the world today. To get the 10 terawatts we need to stay on the “business-as-usual” curve, we’d need 10,000 of our current one-gigawatt reactors, and that means we’d have to build one every other day somewhere in the world for the next 50 straight years. I’ve been giving this talk in one version or another for five years—we should have already built on the order of 1,000 new reactors, or double what’s ever been built, just to stay on track. So we’re really behind.

There isn’t enough terrestrial uranium on the planet to build them as once-through reactors. We could get enough uranium from seawater, if we processed the equivalent of 3,000 Niagara Falls 24/7 to do the extraction. Which means that the only credible nuclear-energy source today involves plutonium. That’s never talked about by the politicians, but it’s a fact. Forgive my facetiousness, but on some level we should be thanking North Korea and Iran for doing their part to mitigate global warming. We’d need about 10,000 fast-breeder reactors and, by the way, their commissioned lifetime is only 50 years. That means that after we choose this route, we’re building one of them every other day, or more rapidly, forever.

We don’t have time for the physicists to figure out how to make nuclear fusion reactors—they’ve been saying it will be demonstrated (although not economical) in 35 years, and they’ve been saying that for the last 50. If we assume they’re right this time, then ITER, a multinational demonstration fusion reactor being built in the south of France, will demonstrate break even—that is, it will put out as much energy as it takes to run it—in 35 years, and it will run for all of one week before the entire machine will, by design, disintegrate in the presence of that high-neutron radiation and temperature flux. And in the meantime we would have to build a commercial fission reactor every day for the next 30 years. It’s not going to happen.

.       .       .

One hundred twenty thousand terawatts of solar power hits the earth . . . It is the only natural energy resource that can keep up with human consumption. Everything else will run up against the stops, soon. In fact, more solar energy hits the earth in one hour than all the energy the world consumes in a year.

ENERGY: As the world’s population grows, meeting future energy needs will be difficult

Posted on by
2

Image: Each red square illustrates an area that could capture three terawatts of solar energy. Together, the red squares could supply the world’s energy needs

There is no such thing as unlimited growth, so the U.S. government and other governments must understand the connection between energy availability and population growth by integrating sustainability into energy policy and into energy law. The current business-as-usual scenario will not meet the future energy needs of a rapidly growing world.

Also, exponential population growth and increasing energy demands will impact efforts to mitigate climate change. As a result, large amounts of renewable, clean energy will be required to sustain the energy needs of a growing world. However, not even nuclear power can keep up with escalating population growth and the future energy needs of a business-as-usual world in 2050. Solar energy, however, is the only natural energy resource that can keep up with human consumption.

Nathan Lewis provides a gloomy but sobering assessment of the challenges humanity will face in meeting its future energy needs (emphasis added):

Energy is the single most important technological challenge facing humanity today. Nothing else in science or technology comes close in comparison. If we don’t invent the next nano-widget, if we don’t cure cancer in 20 years, like it or not the world will stay the same. But with energy, we are in the middle of doing the biggest experiment that humans will have ever done, and we get to do that experiment exactly once. And there is no tomorrow, because in 20 years that experiment will be cast in stone. If we don’t get this right, we can say as students of physics and chemistry that we know that the world will, on a timescale comparable to modern human history, never be the same.

The currency of the world is not the dollar, it’s the joule.

.       .       .

Humanity’s current energy consumption rate is 13 trillion thermal watts, or 13 terawatts.

.       .       .

The United States consumes a quarter of the world’s energy, at a rate of about 3.3 terawatts[.]

.       .       .

With population and GDP growth conspiring together, we would then obtain a tripling of energy demand by 2050. This is partly mitigated, however, by the fact that we’re using energy more efficiently per unit of GDP. The ratio of energy consumption to GDP has been declining at about 1 percent, globally averaged, per year. The United States actually saves energy at a faster rate, about 2 percent per year. Because we have such a high per-capita energy baseline consumption, it is easier for us to save off that base, whereas the developing countries save less. The “business as usual” scenario assumes that this will continue, and if we project that down, we will achieve an average energy consumption of two kilowatts per person within our lifetimes. (The United States now uses 10 kilowatts per person.) But factor in population growth and conservative economic growth, and we’ll still need twice as much energy as we need now.

In terms of average thermal load, a person on a 2,000-calorie-per-day diet is basically a hundred-watt lightbulb. And in our highly mechanized western agricultural system, the energy embedded in food—to run the farm and grow the food and transport it to the supermarket and put it in the refrigerator—is 10 to 20 times the energy content of the food itself. And the farther you live from the food source, the more embedded energy you consume. If we are 100-watt lightbulbs, this means that just keeping us fed requires one to two kilowatts.

.       .       .

Ice cores taken near Vostok Station, Antarctica, show that the CO2 level has been in a narrow band between 200 and 300 parts per million by volume (ppmv) for the last 425,000 years; data from other cores have extended this back to 670,000 years. Current CO2 levels are about 380 ppmv. “Business as usual” will require 10 trillion watts, 10 terawatts, of carbon-free power, and it never stabilizes CO2 levels—they just keep going up. So even on that track, we are betting against data that goes back for almost a million straight years, and hoping that this time, we get lucky.

.       .       .

[U]nfortunately, there is no natural destruction mechanism for carbon dioxide in our atmosphere. Unlike ozone depletion, it will not heal by itself through chemical processes. In our highly oxidizing atmosphere, CO2 is an end product. The lifetimes of CO2 in the atmosphere are well known, and the time for 500 to 600 ppmv of CO2 to decay back to 300 ppmv is between 500 and 5,000 years. Which means that the CO2 we produce over the next 40 years, and its associated effects, will last for a timescale comparable to modern human history. This is why, within the next 20 years, we either solve this problem or the world will never be the same. How different that world will be, we won’t know until we get there.

If we want to hold CO2 even to 550 ppmv, even with aggressive energy efficiency we will need as much clean, carbon-free energy within the next 40 years, online, as the entire oil, natural gas, coal, and nuclear industries today combined—10 to 15 terawatts. This is not changing a few lightbulbs in Fresno, this is building an industry comparable to 50 Exxon Mobils. Furthermore, if we wait 30 years, the amount of carbon-free energy we’ll need will be even greater, and needed even faster, because in the meantime we will have put out 30 years of accumulated CO2 emissions that will not go away for centuries to millennia. So stabilizing at 550 ppmv will then require about 15 to 20 terawatts of carbon-free power in 2050.

.       .       .

So let’s look at carbon-neutral energy sources. We could go nuclear, which is the only proven technology that we have that could scale to these numbers. We have about 400 nuclear power plants in the world today. To get the 10 terawatts we need to stay on the “business-as-usual” curve, we’d need 10,000 of our current one-gigawatt reactors, and that means we’d have to build one every other day somewhere in the world for the next 50 straight years. I’ve been giving this talk in one version or another for five years—we should have already built on the order of 1,000 new reactors, or double what’s ever been built, just to stay on track. So we’re really behind.

There isn’t enough terrestrial uranium on the planet to build them as once-through reactors. We could get enough uranium from seawater, if we processed the equivalent of 3,000 Niagara Falls 24/7 to do the extraction. Which means that the only credible nuclear-energy source today involves plutonium. That’s never talked about by the politicians, but it’s a fact. Forgive my facetiousness, but on some level we should be thanking North Korea and Iran for doing their part to mitigate global warming. We’d need about 10,000 fast-breeder reactors and, by the way, their commissioned lifetime is only 50 years. That means that after we choose this route, we’re building one of them every other day, or more rapidly, forever.

We don’t have time for the physicists to figure out how to make nuclear fusion reactors—they’ve been saying it will be demonstrated (although not economical) in 35 years, and they’ve been saying that for the last 50. If we assume they’re right this time, then ITER, a multinational demonstration fusion reactor being built in the south of France, will demonstrate break even—that is, it will put out as much energy as it takes to run it—in 35 years, and it will run for all of one week before the entire machine will, by design, disintegrate in the presence of that high-neutron radiation and temperature flux. And in the meantime we would have to build a commercial fission reactor every day for the next 30 years. It’s not going to happen.

.       .       .

One hundred twenty thousand terawatts of solar power hits the earth . . . It is the only natural energy resource that can keep up with human consumption. Everything else will run up against the stops, soon. In fact, more solar energy hits the earth in one hour than all the energy the world consumes in a year.

NONRENEWABLE RESOURCES: Energy analyst predicts that oil could reach $300 in ten years. Can the GOP’s energy policy meet our future energy needs?

Posted on by
2

Images via Grant Neufeld and pshab on Flickr.

How will the future economy of the United States respond to rising oil prices or to $300-a-barrel oil? Under the Obama Administration and a Democratic majority, we’ve seen the federal government attempt to stimulate renewable energy by investing into it, by contributing to energy-storage technology, and by recognizing the utility of alternative-fuel vehicles.

Despite fossil fuels contributing to climate change, national security concerns, and the pollution of the human environment, the GOP embraces an economy dependent on dirty, nonrenewable fossil fuels. Fossil fuels may seem cheap, but they’re not. The cheap cost of fossil fuels, paid at the pump for example, doesn’t reflect the true cost of fossil fuels, because the price at the pump doesn’t include costs that are a consequence of the negative externalities associated with burning fossil fuels. For example, it has been estimated by numerous studies that the negative externalities associated with burning fossil fuels cost governments and the public billions of dollars each year. This means that while fossil-fuel companies receive record profits, they’re not responsible for the consequences of doing dirty business or for the billions of dollars that governments and the public are forced to pick up. Additionally, the fossil-fuel industry receives government subsidies to pollute the human environment. These fossil-fuel subsidies must be eliminated to “enhance energy security, reduce emissions of greenhouse gases and air pollution, and bring economic benefits.”

Given the facts and consequences associated with a fossil fuel-based economy, it would seem that a prudent and progressive energy policy shouldn’t be a partisan issue, but the Republican Party isn’t exactly known for pushing clean, sustainable, or rational energy policy reforms. For example, the Republican Party’s energy policy focuses on “lifting restrictions on ANWR, the Outer Continental Shelf, and oil shale in the Mountain West.” Also, the Republican Party claims that “revenue generated by the sale of leases will be invested in renewable and alternative sources of energy.” However, what will the United States utilize after these nonrenewable resources are exhausted? Why drill here, drill now when these minerals are sold on an international market, so why is it necessary to invade protected wilderness areas to extract minerals, which aren’t necessarily consumed domestically. Also, considering greenhouse gases, global warming, and climate change, why is it necessary to add even more trapped carbon dioxide — a greenhouse gas — into the atmosphere? Basically, the short-term benefits of extracting and using these minerals are outweighed by the long-term damage caused by climate change and a failure to implement a prudent or sustainable energy policy.

Furthermore, the Republican Party believes that “the best way for utility companies to reduce carbon emissions is to increase their supply of nuclear energy.” However, nuclear power isn’t cheap, and the costs associated with constructing new nuclear power plants have skyrocketed. There are also substantial costs associated with decommissioning nuclear power plants (“it may cost $300 million or more to shut down and decommission a plant“). Other negatives associated with nuclear power production include the fact that the nuclear power industry depends solely on a nonrenewable energy source, and there’s the well-known problem of storing nuclear waste. Also, “the process of thermoelectric generation from fossil fuels such as coal, oil, and natural gas, as well as nuclear power, is water intensive. In fact, each kWh generated requires on average approximately 25 gallons of water to produce.” Therefore, drought could force nuclear power plants to shut down. What’s more, there are past and present safety concerns with nuclear power production. Recently, the nuclear power industry has been plagued by safety problems at the Vermont Yankee Nuclear Power Plant. Certainly, if the costs associated with decommissioning nuclear power plants, with the management of nuclear power plants, and with the disposal of nuclear waste are considered, then both solar and wind power are substantially cheaper than nuclear power.

The GOP’s talking points on energy also claim that Democrats tax energy, but the GOP makes no mention of the tax incentives and tax credits spurred under the Democratic majority and under the Obama Administration. Consequently, the Republican Party merely politicizes and trivializes the issue of energy. Why can’t the Republican Party aggressively pursue the development of renewables? Portugal is doing it. Denmark is doing it. Iceland is doing it. Even China understands the utility of developing its renewable energy sources.

Additionally, being a conservative political party, there are energy conservation strategies that the Republican Party should show open and strong support for but don’t. For example, there are the ideas of retrofitting buildings to conserve energy, adopting greener building standards to conserve energy, or even promoting the smart grid revolution to conserve energy. Also, instead of attacking it, the Republican Party should show strong support for science in order to spur innovation and technological development to meet our energy needs.

Given the Party’s energy policy positions, the new Republican majority in the House of Representatives threatens to stifle the progress made by the Democratic majority by resurrecting an energy policy focused too much on fossil fuels. For example, Representative Joe Barton, a Republican from Texas and BP apologist, is supposedly a contender for the chairmanship of the Energy and Commerce Committee. Another contender for the chairmanship of the Energy and Commerce Committee is John Shimkus, a Republican from Illinois. Shimkus is a climate-change denier, and once declared that “global warming isn’t something to worry about because God said he wouldn’t destroy the Earth after Noah’s flood.”

To summarize, the Republican energy policy lacks innovation and forward-thinking, and their energy policy merely utilizes old ideas, which don’t promote energy security. To put it another way, the Republican Party’s answer to our current energy crisis is to stick their heads in the sand. Also, the failure of the Republican Party to embrace prudent energy policies is the failure to recognize the connection between population growth, rising energy demand, natural resource unavailability, and rising energy and mineral prices. More on the future price of oil via Peak Oil News and Message Boards:

Ludwig: What is your oil price outlook as this whole new world order begins to take shape?

Maxwell: The supply and demand of oil in the world today are pretty close to each other, and there shouldn’t be too much deviation in 2010 and 2011. We think prices will stay within a band roughly between $67-$87 a barrel. When it gets up toward $87, it seems to retreat, and when it gets down toward $67, it seems to take off again. That’s because supply and demand are in rough balance.

But as the economic recovery continues, as more people use oil because there are more people in the world, and China and India continue to progress with rapid expansion of cars and the roads they are offering their people, demand for oil will continue to climb between 1 and 1.5 percent per year. That, combined with the depletion of these mature oil fields we’ve talked about, will bring us to a plateau by 2015-2017, where the rising production of newer oil fields will equal the falling production of old fields.

At that stage, prices will break through this $87 boundary—in about 2013, I’m thinking. And by 2015 we’ll be up to around $130-$150 a barrel. And then by 2020, when we have 1.5 percent increases in demand each year and 0.5 percent declines on the downside, then we’ll really be in a fix. At that time, I’m looking at $300 a barrel in money of the day. But remember, by then we will have the full effects of inflation over the prior 10 years, so it would probably be something like $200 a barrel in today’s terms, but it will have a nominal price of about $300 a barrel.