MIT analysis suggests generating electricity from large-scale wind farms could influence climate...

Wind resistance

MIT analysis suggests generating electricity from large-scale wind farms could influence climate — and not necessarily in the desired way.

Morgan Bettex, MIT News Office

March 12, 2010

Wind power has emerged as a viable renewable energy source in recent years — one that proponents say could lessen the threat of global warming. Although the American Wind Energy Association estimates that only about 2 percent of U.S. electricity is currently generated from wind turbines, the U.S. Department of Energy has said that wind power could account for a fifth of the nation’s electricity supply by 2030.

But a new MIT analysis may serve to temper enthusiasm about wind power, at least at very large scales. Ron Prinn, TEPCO Professor of Atmospheric Science, and principal research scientist Chien Wang of the Department of Earth, Atmospheric and Planetary Sciences, used a climate model to analyze the effects of millions of wind turbines that would need to be installed across vast stretches of land and ocean to generate wind power on a global scale. Such a massive deployment could indeed impact the climate, they found, though not necessarily with the desired outcome.

In a http://www.atmos-chem-phys.net/10/2053/2010/acp-10-2053-2010.html">paper published online Feb. 22 in Atmospheric Chemistry and Physics, Wang and Prinn suggest that using wind turbines to meet 10 percent of global energy demand in 2100 could cause temperatures to rise by one degree Celsius in the regions on land where the wind farms are installed, including a smaller increase in areas beyond those regions. Their analysis indicates the opposite result for wind turbines installed in water: a drop in temperatures by one degree Celsius over those regions. The researchers also suggest that the intermittency of wind power could require significant and costly backup options, such as natural gas-fired power plants.

Prinn cautioned against interpreting the study as an argument against wind power, urging that it be used to guide future research that explores the downsides of large-scale wind power before significant resources are invested to build vast wind farms. “We’re not pessimistic about wind,” he said. “We haven’t absolutely proven this effect, and we’d rather see that people do further research.”

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For the land analysis, they simulated the effects of wind farms by using data about how objects similar to turbines, such as undulating hills and clumps of trees, affect surface “roughness,” or friction that can disturb wind flow. After adding this data to the model, the researchers observed that the surface air temperature over the wind farm regions increased by about one degree Celsius, which averages out to an increase of .15 degrees Celsius over the entire global surface.

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Abstract. Meeting future world energy needs while addressing climate change requires large-scale deployment of low or zero greenhouse gas (GHG) emission technologies such as wind energy. The widespread availability of wind power has fueled substantial interest in this renewable energy source as one of the needed technologies. For very large-scale utilization of this resource, there are however potential environmental impacts, and also problems arising from its inherent intermittency, in addition to the present need to lower unit costs. To explore some of these issues, we use a three-dimensional climate model to simulate the potential climate effects associated with installation of wind-powered generators over vast areas of land or coastal ocean. Using wind turbines to meet 10% or more of global energy demand in 2100, could cause surface warming exceeding 1 ◦ C over land installations. In contrast, surface cooling exceeding 1 ◦ C is computed over ocean installations, but the validity of simulating the impacts of wind turbines by simply increasing the ocean surface drag needs further study. Significant warming or cooling remote from both the land and ocean installations, and alterations of the global distributions of rainfall and clouds also occur. These results are influenced by the competing effects of increases in roughness and decreases in wind speed on near-surface turbulent heat fluxes, the differing nature of land and ocean surface friction, and the dimensions of the installations parallel and perpendicular to the prevailing winds. These results are also dependent on the accuracy of the model used, and the realism of the methods applied to simulate wind turbines. Additional theory and new field observations will be required for their ultimate validation. Intermittency of wind power on daily, monthly and longer time scales as computed in these simulations and inferred from meteorological observations, poses a demand for one or more options to ensure reliability, including backup generation capacity, very long distance power transmission lines, and onsite energy storage, each with specific economic and/or technological challenges.

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The computed air temperature over the installation regions in Run L is elevated by more than 1 ◦ C in the lowest model layer (∼30 m thick at sea level) in many regions (Fig. 2), but the increase, averaged over the entire global land surface, is only about 0.15 ◦ C. Although the surface air temperature change is dominated by the increase over the wind turbine-installed areas (Fig. 1), the changes go well beyond these areas (Fig. 2). The frequency distributions for temperature also shown in Fig. 2. The global land-average temperature changes are 0.05, 0.16, and 0.73 ◦ C, respectively, for these three other land-based runs (VL, H and VH). In all these runs, except for Run VL, the global patterns of these changes are consistent with Run L (Fig. 2). These patterns also have some similarities to the previous study by Keith et al. (2004) over land, but not over the oceans, since that study assumed fixed ocean temperatures.

The warming caused by the wind turbines is limited to the lowermost atmospheric layers (Fig. 3). Above the planetary boundary layer, a compensating cooling effect is expected and observed in many regions, because the turbulent transfer of heat from the surface to these higher layers is reduced. This should be contrasted to the relatively uniformly distributed warming throughout the troposphere induced by rising greenhouse gases (IPCC, 2007).

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1 Introduction

World energy demand is predicted to increase from
430 EJ/year (14 TW) in 2002 to 1400 EJ/year (44 TW)
in 2100 (Reilly and Paltsev, 2007). Any effective energy
contributor needs to be implemented on a very large scale
(e.g. provide 10% of the year 2100 demand). Among the
current energy technologies with low or zero greenhouse
gas (GHG) emissions, electrical generation using wind turbines
is percentage-wise the fastest growing energy resource
worldwide. In the US, it has grown from 1.8GW of capacity
in 1996 to more than 11.6 GW (0.37 EJ/year) in 2006, but
this is still negligible compared to future energy demand.

The solar energy absorbed by the Earth is converted into
latent heat (by evaporation), gravitational potential energy
(by atmospheric expansion), internal energy (by atmospheric
and oceanic warming, condensation), or kinetic energy (e.g
by convective and baroclinic instabilities) (Lorenz, 1967).
Averaged globally, internal energy, gravitational potential energy,
latent heat, and kinetic energy comprise about 70.4,
27.05, 2.5, and 0.05% respectively of the total atmospheric
energy (Peixoto and Oort, 1992). However, only a small fraction
of the already scarce kinetic energy is contained in the
near surface winds that then produce small-scale turbulent
motions due to surface friction. Eventually the turbulent motions
downscale to molecular motions, thus converting bulk
air kinetic energy to internal energy.

However, it is not the size of these energy reservoirs, but
the rate of conversion from one to another, that is more relevant
here. The global average rate of conversion of largescale
wind kinetic energy to internal energy near the surface
is about 1.68W/m2 (860TW globally) in our model calculations.
This is only about 0.7% of the average net incoming
solar energy of 238 W/m2 (122PW globally) (Lorenz, 1967;
Peixoto and Oort, 1992). The magnitude of this rate when
wind turbines are present is expected to differ from this, but
not by large factors. The widespread availability of wind
power has fueled substantial interest in harnessing it for energy
production (e.g. Carter, 1926; Hewson, 1975; Archer
and Jacobson, 2003). Wind turbines convert wind power into
electrical power. However, the turbulence near the surface,
which also feeds on wind power, is critical for driving the
heat and moisture exchanges between the surface and the
atmosphere that play an important role in determining surface
temperature, atmospheric circulation and the hydrological
cycle.

Because of the low output (MW) of individual wind turbines,
one needs to install a large number of the devices to
generate a substantial amount of energy. For example, presuming
these turbines are effectively generating at full capacity
only 1/3 of the time, about 13 million of them are needed
to meet an energy output of 140 EJ/year (4.4 TW), and they
would occupy a continental-scale area. While the amount
of energy gained from global deployment of surface wind
power may be small relative to the 860TW available globally,
the accompanying climate effects may not be negligible.
A previous study using atmospheric general circulation
models with fixed sea surface temperatures suggests that the
climatic perturbation caused by a large-scale land installation
of wind turbines can spread well beyond the installation
regions (Keith et al., 2004).

Using wind turbines to meet 10% or more of global energy demand in 2100 could cause surface warming exceeding 1C over land installations. Significant warming and cooling remote from the installations, and alterations of the global distributions of rainfall and clouds also occur.

These findings mean that we can now say: if you emit that tonne of carbon dioxide, it will lead to 0.0000000000015 degrees of global temperature change. If we want to restrict global warming to no more than 2 degrees, we must restrict total carbon emissions – from now until forever – to little more than half a trillion tonnes of carbon, or about as much again as we have emitted since the beginning of the industrial revolution.

... To explore some of these issues, we use a three-dimensional climate model to simulate the potential climate effects associated with installation of wind-powered generators over vast areas of land or coastal ocean. ...