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“State of Charge” Frequently Asked Questions

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Our new report on electric vehicles, State of Charge: Electric Vehicles’ Global Warming Emissions and Fuel-Cost Savings Across the United States, has been out for a couple of weeks now and we’ve gotten a lot of great comments from folks and some pretty exciting media coverage, as well as some interesting analysis of the media coverage. We’ve responded to a number of questions from interested readers on our blog and wanted to share some of the common questions and answers all in one place. So here are the Frequently Asked Questions on State of Charge:

If you are charging a electric vehicle overnight, are you using electricity that would be wasted anyway?

There is typically excess electricity generating capacity overnight because electricity demand is lower than peak times which typically occur during the day. However, electricity production continually changes to match demand. Power plants that are not needed at night are shutdown or their output is reduced to match demand during these periods. In other words, electricity is not being wasted. In some rare cases, wind power has been curtailed, or shut off, because of too much electricity on the grid. This happened recently in the northwest when large river flows and windy conditions created excess electricity production, but is not a common occurrence.

Has the electricity grid been getting cleaner since 2007, and does that impact the results of the report?

In recent years, generation of coal-powered electricity has declined while natural gas and renewables has increased.  As a result newer power plant data is expected to show that EVs powered by the electricity grid have even lower emissions. This trend is expected to continue into the future in part due to state renewable energy standards, 30 of which exist across the country, and the retirement of older, less efficient coal-fired plants (see the map below to see which states have renewable energy standards).  As a result, an EV bought today will get cleaner the longer you own it.

As new data becomes available, we will update our analysis to reflect the changing grid mix.

Renewable electricity standards by state as of December 2011

Are the mpg values used in the study real-world or are they based on compliance data for federal fuel economy and greenhouse gas emissions?

Our mpg ratings are based on the combined city/highway fuel economy window sticker values, like those found on the www.fueleconomy.gov website.  These values much more closely reflect real world driving than the mpg values used to determine compliance with federal fuel economy standards.  For more information on how mpg ratings differ for compliance testing and window labels, see our fact sheet about translating standards into on-road fuel efficiency.

Did the report consider other air pollution, besides global warming emissions,  from electric vehicles?

Our analysis focused on global warming emissions from operating an electric vehicle and the costs of charging. Other analyses have looked at the air quality implications of electric vehicles. A 2007 report by the Natural Resources Defense Council and the Electric Power Research Institute is one of the most comprehensive analyses done to date. The study looks at projections of plug-in electric vehicles overtime and the change in ozone concentrations and other pollutants that might be expected and finds that the vast majority of areas will see improved air quality.

Air quality analyses require sophisticated modeling to perform because the location and timing of the emissions are important factors in determining changes in air pollutions concentrations and the resulting population exposures to these pollutants.

A move towards more renewables and away from coal will reduce other air pollutants in addition to global warming emissions, and ensure electric vehicles deliver the greatest benefits.

New electricity users vs old users: Does “State of Charge” treat them equally?

Our approach to estimating emissions treats all users of a region’s electricity equally, meaning no matter what device is using the electricity, be it a ten-year old hot tub or a brand new Nissan LEAF, each kWh of electricity they consume is presumed to have the same emissions.

An alternative approach is to use marginal emissions, which represent the additional emissions that are expected by adding a new electricity load to the grid. For example, plugging in your new EV means a power plant somewhere has to increase its output just a little bit.  If that power plant happens to be coal fired, the emissions from charging your EV would be equivalent to about a 30 mpg gasoline vehicle. If it just so happens that excess wind generation is on the grid (the rare occurrence noted above) then you could claim your EV would have zero emissions.

Marginal emission analysis is important for understanding the impact of thousands of vehicles plugging in the electricity grid, or any new demand on the electricity grid for that matter. But for an individual consumer, treating all the electrons coming into your house the same, whether they are powering up your old hot tub, charging your new EV, or powering that new flat screen TV, makes the most sense.

Think about how a marginal type of analysis might play out if applied to gasoline.  Oil from tar sands for example, a growing source of oil, has higher emissions because of the greater energy required for extraction.

So you pull up to the gas station in your new Chevy Volt, the first car you have ever owned, and someone next to you is filling up a 1986 Dodge Ram pickup. You want to know the global warming emissions that will result from consuming the gallon of gasoline each of you is putting in the tank.  Does the gallon of gasoline going into the new Volt  contain more, less, or the same amount of carbon as the gallon of gasoline going in to the old pick-up? Using average emissions – they are equal. Using marginal emissions – they are different.

Kind of reminds me of that trick question, what weighs more, a pound of feathers or a pound of gold?

Our collective decisions to use gasoline and electricity contribute to the resulting emissions from these sources of energy. Marginal emissions analysis is key to understanding the emissions impact of these decisions on a large scale and into the future.  But using the average emissions of gasoline and electricity to understand the carbon footprint of individual vehicle choices, as we do in our analysis, provides a reasonable estimate for an individual.

What data was used to estimate electric vehicle emissions?

The data used to estimate the emissions from power plants is based on data compiled by EPA in their eGrid database. The most recent available version was used, which includes emissions data from plants operating in 2007. We also included the emissions from extraction and transportation emissions of energy sources used in electricity production. For example, the emissions from coal mining and transporting the coal to the power plant are included, as well as the inefficiencies of getting electricity from the power plant to your house. We treated gasoline in a similar manner, accounting for the extraction, refining and transportation of gasoline.

We used Argonne National Labs GREET model to determine the emissions from producing and burning a gallon of gasoline as well as for the upstream electricity generation feedstock emissions described above.

Posted in: Uncategorized, Vehicles Tags: , , ,

About the author: Don Anair is a senior engineer with expertise on diesel, hybrid and battery electric vehicle, and goods movement technologies and the policies needed to turn them into real solutions for U.S. oil dependence, air pollution and global warming. He holds a master’s degree in electrical engineering. See Don's full bio.

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2 Responses

  1. Tony Milillo says:

    I have some questions about the EV efficiency used in the report. At page 46 it states, “The “i” uses less electricity per mile than the LEAF (0.30 kWh/mile versus 0.34 kWh/mile, respectively), giving the “i” a smaller global warming footprint.” But the “i” has a 16 kwh battery and an EPA rated range of 62 miles. Doesn’t that work out to an efficiency of .26 kWh/mile? So my first question is why the difference?

    Also, the report assumed an EV efficiency of .34 kWh. The “i” has been reported to get 70 to 80 miles in real-world use with still some charge left. Even assuming only 70 miles from a full charge, that would get the efficiency up to .23 kWh/mile. Thus, using the EPA rating, the “i” is 24% more efficient than the assumed efficiency of .34, and using a 70 mile range gives a 38% improvement.

    So my next question is, would it be correct to increase the mpg’s in the chart showing the gas equivalent of an ev by those percentages to see how the “i” compares to gasoline vehicles? If this is correct, the 31-40 mpg equivalence in a “Good” region would go up to either 38-50 mpg or 43-55 mpg for the “i”. And, people like me who live in the “best” region would see an mpg equivalence of over 63 mpg or 70 mpg. Is this computation correct?

    I’m seriously considering buying an “i” even though I live in upstate NY and will have to run the car’s heater during the cold months, greatly reducing the car’s range and efficiency. Any input you can provide would be very helpful. Thanks for the great work in putting together the report.

    • Don Anair says:

      Thanks for the question Tony. Regarding your first question, the 16 kWh rating of the battery pack refers to how much electricity can be stored in the batteries, similar to how many gallons a gas tank can hold in a gasoline vehicle. The amount of energy stored in the batteries doesn’t determine the efficiency of the vehicle, rather its the vehicles characteristics (aerodynamics, tire rolling resistance, weight, motor efficiency, etc) that determine how much electricity (kWh) it takes to travel 1 mile. We used EPA efficiency ratings for both gasoline and electric vehicles to be consistent in our comparison. However, as you probably have experienced, the ratings don’t always reflect exactly what you get in real-world driving. Recent updates to EPA’s efficiency estimates have vastly improved the estimates, but driving behavior will still have an impact on how many miles you can go on a gallon of gasoline or a kWh of electricity. Consistently avoiding hard acceleration, for example, will improve your efficiency.

      To see how the “i” compares to the LEAF in NYUP, upstate New York’s grid region, check out Table 4.2. The LEAF earns a rating of 86 mpg equivalent, but the “i”‘s greater efficiency earns it an mpg equivalent of 97.