Alternative Energy Resources in Michigan
Below is a short summary of alternative energy resources for Michigan. For more information on each technology, visit the State Energy Alternatives Technology Options page.
For more information, including links to resource maps, energy statistics, and contacts for Michigan, visit EERE's State Activities and Partnerships Web site's Michigan page.
Biomass
Studies indicate that Michigan has good biomass resource potential. For more state-specific resource information, see Biomass Feedstock Availability in the United States: 1999 State Level Analysis.
Geothermal
Michigan has vast low-temperature resources suitable for geothermal heat pumps. However, Michigan does not have sufficient resources to use the other geothermal technologies.
Hydropower
Michigan has a relatively low hydropower resource as a percentage of the state's electricity generation. For additional resource information, check out the Idaho National Laboratory's Virtual Hydropower Prospector (VHP). VHP is a convenient geographic information system (GIS) tool designed to assist you in locating and assessing natural stream water energy resources in the United States.
Solar
To accurately portray your state's solar resource, we need two maps. That is because different collector types use the sun in different ways. Collectors that focus the sun (like a magnifying glass) can reach high temperatures and efficiencies. These are called concentrating collectors. Typically, these collectors are on a tracker, so they always face the sun directly. Because these collectors focus the sun's rays, they only use the direct rays coming straight from the sun.
Other solar collectors are simply flat panels that can be mounted on a roof or on the ground. Called flat-plate collectors, these are typically fixed in a tilted position correlated to the latitude of the location. This allows the collector to best capture the sun. These collectors can use both the direct rays from the sun and reflected light that comes through a cloud or off the ground. Because they use all available sunlight, flat-plate collectors are the best choice for many northern states. Therefore, this site gives you two maps: one is the resource for a concentrating collector and one is the resource for a flat-plate collector.
What do the maps mean? For flat-plate collectors, Michigan has a useful resource throughout the state. Because of their simplicity, flat-plate collectors are often used for residential and commercial building applications. They can also be used in large arrays for utility applications. For concentrating collectors, Michigan has a relatively poor resource. Concentrators are probably not the best renewable energy technology for the state.
Wind
Wind Powering America indicates that Michigan has wind resources consistent with utility-scale production. The map shows that the onshore utility-scale wind resources in Michigan are concentrated along the immediate shores of the Great Lakes (especially Lakes Michigan and Superior) and on offshore islands. The Great Lakes have good to outstanding wind resource. In addition, small wind turbines may have applications in some areas. For more information on wind resources in Michigan, visit Wind Powering America's U.S. Wind Resource Map.
Energy Efficiency
Energy efficiency means doing the same work, or more, and enjoying the same comfort level with less energy. Consequently, energy efficiency can be considered part of your state's energy resource base — a demand side resource. Unlike energy conservation, which is rooted in behavior, energy efficiency is technology-based. This means the savings may be predicted by engineering calculations, and they are sustained over time. Examples of energy efficiency measures and equipment include compact fluorescent light bulbs (CFLs), and high efficiency air conditioners, refrigerators, boilers, and chillers.
Saving energy through efficiency is less expensive than building new power plants. Utilities can plan for, invest in, and add up technology-based energy efficiency measures and, as a consequence, defer or avoid the need to build a new power plant. In this way, Austin, Texas, aggregated enough energy savings to offset the need for a planned 450-megawatt coal-fired power plant. Austin achieved these savings during a decade when the local economy grew by 46% and the population doubled. In addition, the savings from energy efficiency are significantly greater than one might expect, because no energy is needed to generate, transmit, distribute, and store energy before it reaches the end user.
Reduced fuel use, and the resulting decreased pollution, provide short- and long-term economic and health benefits.
For more information on current state policies related to energy efficiency, visit the Alliance to Save Energy's State Energy Efficiency Index.
The American Council for an Energy-Efficient Economy published a report in January 2005 titled, Examining the Potential for Energy Efficiency to Help Address the Natural Gas Crisis in the Midwest. This report estimates that energy efficiency programs in Michigan will create 11,380 jobs by 2020.
Technical Potential for Renewable Energy
A 2004 study by the Union of Concerned Scientists titled, Renewing America's Economy estimated that a national renewable electricity standard of 20% by 2020 would produce a net gain of 4,900 jobs in Michigan. Renewable energy would create 2.3 times more jobs than electricity generated from new natural gas and coal power plants.