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National Energy and Petrochemical Map

FracTracker Alliance has released a new national map, filled with energy and petrochemical data. Explore the map, continue reading to learn more, and see how your state measures up!

The items on the map (followed by facility count in parenthesis) include:

         For oil and gas wells, view FracTracker’s state maps. 

This map is by no means exhaustive, but is exhausting. It takes a lot of infrastructure to meet the energy demands from industries, transportation, residents, and businesses – and the vast majority of these facilities are powered by fossil fuels. What can we learn about the state of our national energy ecosystem from visualizing this infrastructure? And with increasing urgency to decarbonize within the next one to three decades, how close are we to completely reengineering the way we make energy?

Key Takeaways

  • Natural gas accounts for 44% of electricity generation in the United States – more than any other source. Despite that, the cost per megawatt hour of electricity for renewable energy power plants is now cheaper than that of natural gas power plants.
  • The state generating the largest amount of solar energy is California, while wind energy is Texas. The state with the greatest relative solar energy is not technically a state – it’s D.C., where 18% of electricity generation is from solar, closely followed by Nevada at 17%. Iowa leads the country in relative wind energy production, at 45%.
  • The state generating the most amount of energy from both natural gas and coal is Texas. Relatively, West Virginia has the greatest reliance on coal for electricity (85%), and Rhode Island has the greatest percentage of natural gas (92%).
  • With 28% of total U.S. energy consumption for transportation, many of the refineries, crude oil and petroleum product pipelines, and terminals on this map are dedicated towards gasoline, diesel, and other fuel production.
  • Petrochemical production, which is expected to account for over a third of global oil demand growth by 2030, takes the form of chemical plants, ethylene crackers, and natural gas liquid pipelines on this map, largely concentrated in the Gulf Coast.

Electricity generation

The “power plant” legend item on this map contains facilities with an electric generating capacity of at least one megawatt, and includes independent power producers, electric utilities, commercial plants, and industrial plants. What does this data reveal?

National Map of Power plants

Power plants by energy source. Data from EIA.

In terms of the raw number of power plants – solar plants tops the list, with 2,916 facilities, followed by natural gas at 1,747.

In terms of megawatts of electricity generated, the picture is much different – with natural gas supplying the highest percentage of electricity (44%), much more than the second place source, which is coal at 21%, and far more than solar, which generates only 3% (Figure 1).

National Energy Sources Pie Chart

Figure 1. Electricity generation by source in the United States, 2019. Data from EIA.

This difference speaks to the decentralized nature of the solar industry, with more facilities producing less energy. At a glance, this may seem less efficient and more costly than the natural gas alternative, which has fewer plants producing more energy. But in reality, each of these natural gas plants depend on thousands of fracked wells – and they’re anything but efficient.Fracking's astronomical decline rates - after one year, a well may be producing less than one-fifth of the oil and gas it produced its first year. To keep up with production, operators must pump exponentially more water, chemicals, and sand, or just drill a new well.

The cost per megawatt hour of electricity for a renewable energy power plants is now cheaper than that of fracked gas power plants. A report by the Rocky Mountain Institute, found “even as clean energy costs continue to fall, utilities and other investors have announced plans for over $70 billion in new gas-fired power plant construction through 2025. RMI research finds that 90% of this proposed capacity is more costly than equivalent [clean energy portfolios, which consist of wind, solar, and energy storage technologies] and, if those plants are built anyway, they would be uneconomic to continue operating in 2035.”

The economics side with renewables – but with solar, wind, geothermal comprising only 12% of the energy pie, and hydropower at 7%, do renewables have the capacity to meet the nation’s energy needs? Yes! Even the Energy Information Administration, a notorious skeptic of renewable energy’s potential, forecasted renewables would beat out natural gas in terms of electricity generation by 2050 in their 2020 Annual Energy Outlook.

This prediction doesn’t take into account any future legislation limiting fossil fuel infrastructure. A ban on fracking or policies under a Green New Deal could push renewables into the lead much sooner than 2050.

In a void of national leadership on the transition to cleaner energy, a few states have bolstered their renewable portfolio.

How does your state generate electricity?
Legend

Figure 2. Electricity generation state-wide by source, 2019. Data from EIA.

One final factor to consider – the pie pieces on these state charts aren’t weighted equally, with some states’ capacity to generate electricity far greater than others.  The top five electricity producers are Texas, California, Florida, Pennsylvania, and Illinois.

Transportation

In 2018, approximately 28% of total U.S. energy consumption was for transportation. To understand the scale of infrastructure that serves this sector, it’s helpful to click on the petroleum refineries, crude oil rail terminals, and crude oil pipelines on the map.

Map of transportation infrastructure

Transportation Fuel Infrastructure. Data from EIA.

The majority of gasoline we use in our cars in the US is produced domestically. Crude oil from wells goes to refineries to be processed into products like diesel fuel and gasoline. Gasoline is taken by pipelines, tanker, rail, or barge to storage terminals (add the “petroleum product terminal” and “petroleum product pipelines” legend items), and then by truck to be further processed and delivered to gas stations.

The International Energy Agency predicts that demand for crude oil will reach a peak in 2030 due to a rise in electric vehicles, including busses.  Over 75% of the gasoline and diesel displacement by electric vehicles globally has come from electric buses.

China leads the world in this movement. In 2018, just over half of the world’s electric vehicles sales occurred in China. Analysts predict that the country’s oil demand will peak in the next five years thanks to battery-powered vehicles and high-speed rail.

In the United States, the percentage of electric vehicles on the road is small but growing quickly. Tax credits and incentives will be important for encouraging this transition. Almost half of the country’s electric vehicle sales are in California, where incentives are added to the federal tax credit. California also has a  “Zero Emission Vehicle” program, requiring electric vehicles to comprise a certain percentage of sales.

We can’t ignore where electric vehicles are sourcing their power – and for that we must go back up to the electricity generation section. If you’re charging your car in a state powered mainly by fossil fuels (as many are), then the electricity is still tied to fossil fuels.

Petrochemicals

Many of the oil and gas infrastructure on the map doesn’t go towards energy at all, but rather aids in manufacturing petrochemicals – the basis of products like plastic, fertilizer, solvents, detergents, and resins.

This industry is largely concentrated in Texas and Louisiana but rapidly expanding in Pennsylvania, Ohio, and West Virginia.

On this map, key petrochemical facilities include natural gas plants, chemical plants, ethane crackers, and natural gas liquid pipelines.

Map of Petrochemical Infrastructure

Petrochemical infrastructure. Data from EIA.

Natural gas processing plants separate components of the natural gas stream to extract natural gas liquids like ethane and propane – which are transported through the natural gas liquid pipelines. These natural gas liquids are key building blocks of the petrochemical industry.

Ethane crackers process natural gas liquids into polyethylene – the most common type of plastic.

The chemical plants on this map include petrochemical production plants and ammonia manufacturing. Ammonia, which is used in fertilizer production, is one of the top synthetic chemicals produced in the world, and most of it comes from steam reforming natural gas.

As we discuss ways to decarbonize the country, petrochemicals must be a major focus of our efforts. That’s because petrochemicals are expected to account for over a third of global oil demand growth by 2030 and nearly half of demand growth by 2050 – thanks largely to an increase in plastic production. The International Energy Agency calls petrochemicals a “blind spot” in the global energy debate.

Petrochemical infrastructure

Petrochemical development off the coast of Texas, November 2019. Photo by Ted Auch, aerial support provided by LightHawk.

Investing in plastic manufacturing is the fossil fuel industry’s strategy to remain relevant in a renewable energy world. As such, we can’t break up with fossil fuels without also giving up our reliance on plastic. Legislation like the Break Free From Plastic Pollution Act get to the heart of this issue, by pausing construction of new ethane crackers, ensuring the power of local governments to enact plastic bans, and phasing out certain single-use products.

“The greatest industrial challenge the world has ever faced”

Mapped out, this web of fossil fuel infrastructure seems like a permanent grid locking us into a carbon-intensive future. But even more overwhelming than the ubiquity of fossil fuels in the US is how quickly this infrastructure has all been built. Everything on this map was constructed since Industrial Revolution, and the vast majority in the last century (Figure 3) – an inch on the mile-long timeline of human civilization.

Figure 3. Global Fossil Fuel Consumption. Data from Vaclav Smil (2017)

In fact, over half of the carbon from burning fossil fuels has been released in the last 30 years. As David Wallace Wells writes in The Uninhabitable Earth, “we have done as much damage to the fate of the planet and its ability to sustain human life and civilization since Al Gore published his first book on climate than in all the centuries—all the millennia—that came before.”

What will this map look like in the next 30 years?

A recent report on the global economics of the oil industry states, “To phase out petroleum products (and fossil fuels in general), the entire global industrial ecosystem will need to be reengineered, retooled and fundamentally rebuilt…This will be perhaps the greatest industrial challenge the world has ever faced historically.”

Is it possible to build a decentralized energy grid, generated by a diverse array of renewable, local, natural resources and backed up by battery power? Could all communities have the opportunity to control their energy through member-owned cooperatives instead of profit-thirsty corporations? Could microgrids improve the resiliency of our system in the face of increasingly intense natural disasters and ensure power in remote regions? Could hydrogen provide power for energy-intensive industries like steel and iron production? Could high speed rail, electric vehicles, a robust public transportation network and bike-able cities negate the need for gasoline and diesel? Could traditional methods of farming reduce our dependency on oil and gas-based fertilizers? Could  zero waste cities stop our reliance on single-use plastic?

Of course! Technology evolves at lightning speed. Thirty years ago we didn’t know what fracking was and we didn’t have smart phones. The greater challenge lies in breaking the fossil fuel industry’s hold on our political system and convincing our leaders that human health and the environment shouldn’t be externalized costs of economic growth.

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Bird’s eye view of a sand mine in Wisconsin. Photo by Ted Auch 2013.

7 Sand Mining Communities, 3 States, 5 Months – Part 1

An Exploration of Sand Mining Impacts: Lasalle County, IL by way of Chicago’s South Side
By Ted Auch, Great Lakes Program Coordinator

When it comes to high-volume hydraulic fracturing (HVHF), frac sand mining may be the most neglected aspect of the industry’s footprint. (HVHF demand on a per-well basis is increasing by 8% per year.)

To capture how this industry is changing several sand mining communities, I recently took a road trip to visit, photograph, and listen to the residents of this country’s primary frac sand areas. In total, I visited 7 sand mining communities in Illinois, Indiana, and Michigan.

This multimedia perspective is part of our ongoing effort to map and quantify the effects of silica sand mining on people, agriculture, wildlife, ecosystem services, and watersheds more broadly. Below is my attempt to give the FracTracker community a sense of what residents are hearing, seeing, and saying about the silica sand mining industry writ large.

Chicago’s South Side

Before heading to Illinois’ frac sand epicenter of Lasalle County, I couldn’t help but catch the South Shore Line out of Millennium Station. This station can be seen as you head south to the Hegewisch neighborhood on Chicago’s impoverished South Side, an area of greater Chicago-Gary, Indiana that has largely been forgotten by politicians in both states. Chicago_KCBX_BP

ChicagoLand_Income_Hardship

Figure 1. Average income per capita and Hardship Index (0-100 with 100 being the worst) for Chicago’s neighborhoods with Hegewisch highlighted in the city’s southeast corner.

This situation is a shame because collectively Hegewisch and the city of Whiting, IN are home to one of the largest – and getting larger – collections of oil refineries and oil sands infrastructure in the United States.

For an estimation of how difficult it is to live in various Chicago neighborhoods, see Figure 1, left.

This proliferation has not been without its dangers, including a compressor station explosion at BP PLC’s massive1 Whiting Refinery in August 2014. Unfortunately, that incident was just the latest in a long line of mishaps at this facility. The “operational incident,” as BP called it, rocked already stressed neighborhoods like MarkTown, IN – the aborted company town planned for steel maker Clayton Mark. MarkTown is on the National Register of Historic Places and is an example of a community that is being erased from the face of the earth in the name of Hydrocarbon Industrial Complex expansion. For those interested in architecture preservation, MarkTown’s rapid erasure is being conducted by BP itself and in the process we are losing an example of Conservatively Radical architect Howard Van Doren Shaw’s distinct English-style Tudor homes and urban planning. Residents speculate BP “may be buying up the properties because of concerns about liability.” The company counters they are just trying to create additional green space for residents.

KCBX_BP_POV

NAmerican_Ports_Refineries

Figure 2. Average daily oil refinery production per day across North America’s 152 Oil Refineries along with North American ports.

Luckily for everyone, operations following the aforementioned recent explosion were only “minimally impacted as a result of the incident and the refinery continue[d] to produce products for customers.” However, the more chronic concern is the tight supply-demand relationship between BP’s refinery and their Koch KCBX neighbor. Koch has made repeated headlines – and many neighbors turned enemies including the Southeast Environmental Task Force and its fearless leader Peggy Salazar – with its handling of the refinery’s annual production of 600,000 tons of petcoke a development Chicago Magazine called Mountains of Trouble. Petcoke is a byproduct of the refinery’s increased acceptance and processing of tar sands from Alberta Canada. Levels of production are likely to increase given BP’s completion in November 2014 of a “$4-billion revamp…to boost its intake of Canadian crude oil from 85,000 bpd to 350,000 bpd.”

Given how interconnected the hydrocarbon industry is, I thought it would be worth collecting some photos of the aforementioned infrastructure. When I saw that Koch KCBX’s terminal was also storing large amounts of silica sand, however, the connection between my next target(s) in LaSalle County was made even more obvious.

LaSalle vs. Chicagoland: A Tale of Two Worlds

Lasalle County, Illinois is situated approximately 50-60 miles south-southwest of Chicago. When you try to compare demographics and commerce, however, it is worlds away.

Chicagoland encompasses nearly 10,900 square miles – 9.5 times the area of Lasalle County. While Chicago’s population is expanding by 95,681 people per year, LaSalle’s is shrinking by 2,734 per year (Table 1). Chicagoans, though not South Siders, are making more than two times that of LaSalle County residents (with the latter actually falling nearly $4,700 below the state average). Predictably the demographics of Chicago reflect more and more those of the US, while LaSalle is typical of rural America with a population that is 93% white and only 3.3% foreign born. Thirty-five percent of Chicagoans are likely to achieve a bachelor’s degree, while only 16% of LaSalle County residents are likely to do so. Rates of poverty and more specifically child poverty, on the other hand, are significantly higher in Chicago. Finally, LaSalle is one of the country’s preeminent farming counties; it ranks #4 in the state and #126 nationally thanks to the value of agricultural commodities produced amounting to $448.5 million net of farm subsidies. See Table 1.

La Salle County, IL Silica Sand Mines & St. Peter Sandstone Geology

Figure 3. La Salle County, IL Silica Sand Mines & St. Peter Sandstone Geology

Chicago_Vs_LaSalleCounty_Comparison

Table 1. Chicagoland and LaSalle County, Illinois summary demographics, economic prosperity, and agricultural productivity.

Photos from the Tour

The above contrast was made crystal clear as I traveled down Interstate 80 westbound towards exit 90 and LaSalle’s County seat Ottawa (pop. 18,562). Upon arriving in Ottawa I drove west on Madison Street to the first target of our expedition: U.S. Silica Company’s mine and processing facility at the corner of Madison Boyce Memorial Drive. Upon arriving, however, it became clear that I would not find a suitable location to photograph the company’s mine; the perimeter had been fenced off and mounded up to the tune of 10-15 feet. So I got back in our rental car and drove to the mine’s southern perimeter adjacent to the Bear Den Bar and Grill and the Vine St.-Fern St.-15th Ave. neighborhood where there was clear line of site. It was here that I got some of the best photos of the mine’s scale and scope with respect to land-use, reclamation, and hydrology.

US_Silica_OttawaCo

Below is a sample of some of those images as well as several I took further down Route 34 between U.S. Silica’s active mine and a “reclaimed” Ottawa Silica Co. mine on the banks of the Illinois River.

After snapping several hundred shots of these two mines I headed to the I & M Canal State Trail between Utica and Ottawa emanating out of Buffalo Rock State Park and hiked east towards the Northern edge of U.S. Silica’s mine alongside a CSX railroad and recently constructed spur feeding into the mine’s loading terminal. The hope was that I would get a closer look at the mine but it turned out the angle was different but not better.

From the back of U.S. Silica’s Ottawa mine I traveled approximately 7 miles west to Unimin’s North Utica mine and a short dirt road off of 2803rd Road on the northern edge of the mine.

Unimin_NorthUtica

It was here that I photographed the mine’s reclamation plots, active mine pits, and developing water transport mechanisms. However, more importantly it was from here that I noticed off in the distance a bright red silica sand grain-size separator.

Curiously I did not – but do now – have this nascent and relatively small mine posted on our Frac Sands Mines and Related Facilities map at the time. Upon arriving at this site I found that the mine was owned and operated by a company called Northern White Sand a small mom & pop operation out of Utica, IL.

Unimin_NorthUtica_NorthernWhiteSand

The photos I took of this mine were primarily from atop a vegetated berm to the southwest of the mine’s primary footprint. This vantage point allowed us to get some great shots of the types of infrastructure/equipment typical of this sized mine including the aforementioned modular grain-size separator, conveyor belts, retention ponds, and the pyramid-like piles of powdery white silica sand so desired by the HVHF industry.

Our final stop on the LaSalle County silica sand mine tour landed us in Troy Grove 13 miles north of North Utica by way of Interstate 39. It was here that I visited several vantage points around Technisand’s MBI Manley Bros. silica mine. The expanse included the site’s mixture of old and new processing infrastructure, what appeared to be an alluvial fan derived from sand waste and associated wetland, and the mine’s far reaches alongside a Chicago and North Western Transportation Company (CNW) railroad.

Resident Testimonials

So now that I have outlined my tour of La Salle County I thought it would be helpful to share some of the stories residents told me during my travels and later by way of email.

Anna Mattes – La Salle County, IL

I live in LaSalle County, Illinois where I have prime farmland and Starved Rock State Park… the crown jewel of Illinois. I already have a fine farming industry and plenty of tourism as Starved Rock is visited by two million people annually. LaSalle County already has forty two quarries, gravel pits and sand mines. If I allow anymore the county will look as though it has been bombed. Empty sand pits will never produce food ever again. No amount of reclamation will restore this land to be productive…Each mine uses one million gallons of water daily. The LaSalle County Board has enlisted the USGS to do a hydrology study to determine how much water I have in our aquifer for municipalities and farming. Presently I have a moratorium in place on sand mines thru July 2016 and I hope forever. As a woman, wife and mother I am charged with the continuity of life. It is my job, profession, to raise healthy children, make a healthy breakfast and pack a nutritious lunch for my husband so he can do his job, and it generally falls to women to care for the elderly in families. With out clean air, pure water, healthy food what is the quality of life? Fracking is a dangerous business and I need to take better care of Planet Earth. Please do your part, I’m a Master Gardener and I’m doing my part.

Thomas Skomski – Wedron, IL

I am a resident of Wedron who has been severely impacted by Wedron Silica; and I want to report that there are many more problems associated with the influx of sand mines in LaSalle Co. than named in your recent article. In order to be fair to other residents who will be negatively affected by proximity to any sand mine I believe it is important to inform them and all concerned on the unmentioned problems associated with living near a sand mine. For example: the mountains of sand that are produced migrate everywhere the wind takes the particles. As I all know the winds are frequently fierce in this part of the country. One neighbor describes how in the morning when he sets his coffee cup down on his front porch and goes into his house to get the newspaper that he returns to find a layer of white sand covering his coffee. Another neighbor vacuums the sand off her living room rugs weekly while her husband regularly has to clean out sand-filled gutters. I do know that enabling pollutants on private property is technically criminal trespass. At the last EPA hearing in Wedron a retired mine employee admitted that Wedron Silica uses 100 million gallons of water per hour in sand processing. Some of this water is recycled. Since I have not confirmed those statistics, I prefer sticking to the fact that the mine has reversed the flow of the ground water. Who knows what the unseen consequences of that reversal might be? The toxic plume that Wedron Silica is in part responsible for creating migrates wherever the ground water moves. As a result of the threat of my well being poisoned my land, 23 acres has been devalued by the county to $1.00. All my five buildings are worth 40% of what they were before nine wells were poisoned in Wedron. Those wells were so toxic with benzene that water came out of the faucet orange and you could not breath it let alone use it to wash anything. Wedron Silica has begun buying homes in Wedron which will allow them to pursue their wealth with no concerns- BUT what about the water which I all know is in limited supply and susceptible to being polluted? So in summary, please include the human costs involved in a mine opening near you. My wife and I moved to the country to enjoy the solitude and quiet of living on a farm in our retirement years. The quality of our lives has been diminished, in addition the noise is disturbing; trains come in at all hours incessantly blowing their horns and the semi traffic is constant. Finally, I have heard a lot of what I consider negative criticism about the EPA. Having experienced this monumental problem directly it is perfectly clear to me that without the resources of a pro-environment organization I would be hard pressed to stand up to a corporation with multi billions in assets.

Ashley Williams – LaSalle County, IL

The nickname the “Silica Sand Capital of the World” has quickly transformed into a curse rather than a blessing for the citizens of LaSalle County, IL. Here, the frac sand industry continues to proliferate, endangering the health and safety of the people and local environment. Our precious life vessels: our air, water, and soil are under siege by a nexus of power that seeks to intimidate us into quiet submission, but I’ll be damned if I’m going to sit by and let that happen.

Footnote

  1. This facility alone processes nearly 2% of all oil in North America on a daily basis. This facility is the seventh-largest refinery in the United States and the largest outside of the Gulf Coast.

Over 1.1 Million Active Oil and Gas Wells in the US

Many people ask us how many wells have been hydraulically fractured in the United States.  It is an excellent question, but not one that is easily answered; most states don’t release data on well stimulation activities.  Also, since the data are released by state regulatory agencies, it is necessary to obtain data from each state that has oil and gas data to even begin the conversation.  We’ve finally had a chance to complete that task, and have been able to aggregate the following totals:

Oil and gas summary data of drilled wells in the United States.

Oil and gas summary data of drilled wells in the United States.

 

While data on hydraulically fractured wells is rarely made available, the slant of the wells are often made accessible.  The well types are as follows:

  • Directional:  Directional wells are those where the top and the bottom of the holes do not line up vertically.  In some cases, the deviation is fairly slight.  These are also known as deviated or slant wells.
  • Horizontal:  Horizontal wells are directional wells, where the well bore makes something of an “L” shape.  States may have their own definition for horizontal wells.  In Alaska, these wells are defined as those deviating at least 80° from vertical.  Currently, operators are able to drill horizontally for several miles.
  • Directional or Horizontal:  These wells are known to be directional, but whether they are classified as horizontal or not could not be determined from the available data.  In many cases, the directionality was determined by the presence of directional sidetrack codes in the well’s API number.
  • Vertical:  Wells in which the top hole and bottom hole locations are in alignment.  States may have differing tolerances for what constitutes a vertical well, as opposed to directional.
  • Hydraulically Fractured:  As each state releases data differently, it wasn’t always possible to get consistent data.  These wells are known to be hydraulically fractured, but the slant of the well is unknown.
  • Not Fractured:  These wells have not been hydraulically fractured, and the slant of the well is unknown.
  • Unknown:  Nothing is known about the slant, stimulation, or target formation of the well in question.
  • Unknown (Shale Formation):  Nothing is known about the slant or stimulation of the wells in question; however, it is known that the target formation is a major shale play.  Therefore, it is probable that the well has been hydraulically fractured, with a strong possibility of being drilled horizontally.

Wells that have been hydraulically fractured might appear in any of the eight categories, with the obvious exception of “Not Fractured.”  Categories that are very likely to be fractured include, “Horizontal”, “Hydraulically Fractured”, and “Unknown (Shale Formation),” the total of which is about 32,000 wells.  However, that number doesn’t include any wells from Texas or Colorado, where we know thousands wells have been drilled into major shale formations, but the data had to be placed into categories that were more vague.

Oil and gas wells in the United States, as of February 2014. Location data were not available for Maryland (n=104), North Carolina (n=2), and Texas (n=303,909).  To access the legend and other map tools, click the expanding arrows icon in the top-right corner.

The standard that we attempted to reach for all of the well totals was for wells that have been drilled but have not yet been plugged, which is a broad spectrum of the well’s life-cycle.  In some cases, decisions had to be made in terms of which wells to include, due to imperfect metadata.

No location data were available for Maryland, North Carolina, or Texas.  The first two have very few wells, and officials in Maryland said that they expect to have the data available within about a month.  Texas location data is available for purchase, however such data cannot be redistributed, so it was not included on the map.

It should not be assumed that all of the wells that are shown in  the map above the shale plays and shale basin layers are actually drilled into shale.  In many cases, however, shale is considered a source rock, where hydrocarbons are developed, before the oil and gas products migrate upward into shallower, more conventional formations.

The raw data oil and gas data is available for download on our site in shapefile format.

 

Pages

Indiana Shale Viewer

Indiana

Oil & Gas Activity in Indiana

Click on the image below to explore our IN map of oil and gas extraction-related activities.



32,733

Total Wells (As of Mar 2017)

Additional Maps & Data

Earthworks IN Oil & Gas Threat Map

Active oil & gas wells, & the counts of people, schools, & hospitals that live within ½ mile of these facilities. Project Launch: 2016

Frac Sand Mining Map

Map of silica sands/frac sand mines, drying facilities, & value added facilities in North America.

Indiana Photos & Videos


This album contains IN imagery contributed to our site from FracTracker staff and volunteers. Reuse is permitted so long as you cite the photographer if one is listed in the photo’s info section, as well as FracTracker Alliance.


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National Energy and Petrochemical Map

FracTracker Alliance has released a new national map, filled with energy and petrochemical data. Explore the map, continue reading to learn more, and see how your state measures up!

The items on the map (followed by facility count in parenthesis) include:

         For oil and gas wells, view FracTracker’s state maps. 

This map is by no means exhaustive, but is exhausting. It takes a lot of infrastructure to meet the energy demands from industries, transportation, residents, and businesses – and the vast majority of these facilities are powered by fossil fuels. What can we learn about the state of our national energy ecosystem from visualizing this infrastructure? And with increasing urgency to decarbonize within the next one to three decades, how close are we to completely reengineering the way we make energy?

Key Takeaways

  • Natural gas accounts for 44% of electricity generation in the United States – more than any other source. Despite that, the cost per megawatt hour of electricity for renewable energy power plants is now cheaper than that of natural gas power plants.
  • The state generating the largest amount of solar energy is California, while wind energy is Texas. The state with the greatest relative solar energy is not technically a state – it’s D.C., where 18% of electricity generation is from solar, closely followed by Nevada at 17%. Iowa leads the country in relative wind energy production, at 45%.
  • The state generating the most amount of energy from both natural gas and coal is Texas. Relatively, West Virginia has the greatest reliance on coal for electricity (85%), and Rhode Island has the greatest percentage of natural gas (92%).
  • With 28% of total U.S. energy consumption for transportation, many of the refineries, crude oil and petroleum product pipelines, and terminals on this map are dedicated towards gasoline, diesel, and other fuel production.
  • Petrochemical production, which is expected to account for over a third of global oil demand growth by 2030, takes the form of chemical plants, ethylene crackers, and natural gas liquid pipelines on this map, largely concentrated in the Gulf Coast.

Electricity generation

The “power plant” legend item on this map contains facilities with an electric generating capacity of at least one megawatt, and includes independent power producers, electric utilities, commercial plants, and industrial plants. What does this data reveal?

National Map of Power plants

Power plants by energy source. Data from EIA.

In terms of the raw number of power plants – solar plants tops the list, with 2,916 facilities, followed by natural gas at 1,747.

In terms of megawatts of electricity generated, the picture is much different – with natural gas supplying the highest percentage of electricity (44%), much more than the second place source, which is coal at 21%, and far more than solar, which generates only 3% (Figure 1).

National Energy Sources Pie Chart

Figure 1. Electricity generation by source in the United States, 2019. Data from EIA.

This difference speaks to the decentralized nature of the solar industry, with more facilities producing less energy. At a glance, this may seem less efficient and more costly than the natural gas alternative, which has fewer plants producing more energy. But in reality, each of these natural gas plants depend on thousands of fracked wells – and they’re anything but efficient.Fracking's astronomical decline rates - after one year, a well may be producing less than one-fifth of the oil and gas it produced its first year. To keep up with production, operators must pump exponentially more water, chemicals, and sand, or just drill a new well.

The cost per megawatt hour of electricity for a renewable energy power plants is now cheaper than that of fracked gas power plants. A report by the Rocky Mountain Institute, found “even as clean energy costs continue to fall, utilities and other investors have announced plans for over $70 billion in new gas-fired power plant construction through 2025. RMI research finds that 90% of this proposed capacity is more costly than equivalent [clean energy portfolios, which consist of wind, solar, and energy storage technologies] and, if those plants are built anyway, they would be uneconomic to continue operating in 2035.”

The economics side with renewables – but with solar, wind, geothermal comprising only 12% of the energy pie, and hydropower at 7%, do renewables have the capacity to meet the nation’s energy needs? Yes! Even the Energy Information Administration, a notorious skeptic of renewable energy’s potential, forecasted renewables would beat out natural gas in terms of electricity generation by 2050 in their 2020 Annual Energy Outlook.

This prediction doesn’t take into account any future legislation limiting fossil fuel infrastructure. A ban on fracking or policies under a Green New Deal could push renewables into the lead much sooner than 2050.

In a void of national leadership on the transition to cleaner energy, a few states have bolstered their renewable portfolio.

How does your state generate electricity?
Legend

Figure 2. Electricity generation state-wide by source, 2019. Data from EIA.

One final factor to consider – the pie pieces on these state charts aren’t weighted equally, with some states’ capacity to generate electricity far greater than others.  The top five electricity producers are Texas, California, Florida, Pennsylvania, and Illinois.

Transportation

In 2018, approximately 28% of total U.S. energy consumption was for transportation. To understand the scale of infrastructure that serves this sector, it’s helpful to click on the petroleum refineries, crude oil rail terminals, and crude oil pipelines on the map.

Map of transportation infrastructure

Transportation Fuel Infrastructure. Data from EIA.

The majority of gasoline we use in our cars in the US is produced domestically. Crude oil from wells goes to refineries to be processed into products like diesel fuel and gasoline. Gasoline is taken by pipelines, tanker, rail, or barge to storage terminals (add the “petroleum product terminal” and “petroleum product pipelines” legend items), and then by truck to be further processed and delivered to gas stations.

The International Energy Agency predicts that demand for crude oil will reach a peak in 2030 due to a rise in electric vehicles, including busses.  Over 75% of the gasoline and diesel displacement by electric vehicles globally has come from electric buses.

China leads the world in this movement. In 2018, just over half of the world’s electric vehicles sales occurred in China. Analysts predict that the country’s oil demand will peak in the next five years thanks to battery-powered vehicles and high-speed rail.

In the United States, the percentage of electric vehicles on the road is small but growing quickly. Tax credits and incentives will be important for encouraging this transition. Almost half of the country’s electric vehicle sales are in California, where incentives are added to the federal tax credit. California also has a  “Zero Emission Vehicle” program, requiring electric vehicles to comprise a certain percentage of sales.

We can’t ignore where electric vehicles are sourcing their power – and for that we must go back up to the electricity generation section. If you’re charging your car in a state powered mainly by fossil fuels (as many are), then the electricity is still tied to fossil fuels.

Petrochemicals

Many of the oil and gas infrastructure on the map doesn’t go towards energy at all, but rather aids in manufacturing petrochemicals – the basis of products like plastic, fertilizer, solvents, detergents, and resins.

This industry is largely concentrated in Texas and Louisiana but rapidly expanding in Pennsylvania, Ohio, and West Virginia.

On this map, key petrochemical facilities include natural gas plants, chemical plants, ethane crackers, and natural gas liquid pipelines.

Map of Petrochemical Infrastructure

Petrochemical infrastructure. Data from EIA.

Natural gas processing plants separate components of the natural gas stream to extract natural gas liquids like ethane and propane – which are transported through the natural gas liquid pipelines. These natural gas liquids are key building blocks of the petrochemical industry.

Ethane crackers process natural gas liquids into polyethylene – the most common type of plastic.

The chemical plants on this map include petrochemical production plants and ammonia manufacturing. Ammonia, which is used in fertilizer production, is one of the top synthetic chemicals produced in the world, and most of it comes from steam reforming natural gas.

As we discuss ways to decarbonize the country, petrochemicals must be a major focus of our efforts. That’s because petrochemicals are expected to account for over a third of global oil demand growth by 2030 and nearly half of demand growth by 2050 – thanks largely to an increase in plastic production. The International Energy Agency calls petrochemicals a “blind spot” in the global energy debate.

Petrochemical infrastructure

Petrochemical development off the coast of Texas, November 2019. Photo by Ted Auch, aerial support provided by LightHawk.

Investing in plastic manufacturing is the fossil fuel industry’s strategy to remain relevant in a renewable energy world. As such, we can’t break up with fossil fuels without also giving up our reliance on plastic. Legislation like the Break Free From Plastic Pollution Act get to the heart of this issue, by pausing construction of new ethane crackers, ensuring the power of local governments to enact plastic bans, and phasing out certain single-use products.

“The greatest industrial challenge the world has ever faced”

Mapped out, this web of fossil fuel infrastructure seems like a permanent grid locking us into a carbon-intensive future. But even more overwhelming than the ubiquity of fossil fuels in the US is how quickly this infrastructure has all been built. Everything on this map was constructed since Industrial Revolution, and the vast majority in the last century (Figure 3) – an inch on the mile-long timeline of human civilization.

Figure 3. Global Fossil Fuel Consumption. Data from Vaclav Smil (2017)

In fact, over half of the carbon from burning fossil fuels has been released in the last 30 years. As David Wallace Wells writes in The Uninhabitable Earth, “we have done as much damage to the fate of the planet and its ability to sustain human life and civilization since Al Gore published his first book on climate than in all the centuries—all the millennia—that came before.”

What will this map look like in the next 30 years?

A recent report on the global economics of the oil industry states, “To phase out petroleum products (and fossil fuels in general), the entire global industrial ecosystem will need to be reengineered, retooled and fundamentally rebuilt…This will be perhaps the greatest industrial challenge the world has ever faced historically.”

Is it possible to build a decentralized energy grid, generated by a diverse array of renewable, local, natural resources and backed up by battery power? Could all communities have the opportunity to control their energy through member-owned cooperatives instead of profit-thirsty corporations? Could microgrids improve the resiliency of our system in the face of increasingly intense natural disasters and ensure power in remote regions? Could hydrogen provide power for energy-intensive industries like steel and iron production? Could high speed rail, electric vehicles, a robust public transportation network and bike-able cities negate the need for gasoline and diesel? Could traditional methods of farming reduce our dependency on oil and gas-based fertilizers? Could  zero waste cities stop our reliance on single-use plastic?

Of course! Technology evolves at lightning speed. Thirty years ago we didn’t know what fracking was and we didn’t have smart phones. The greater challenge lies in breaking the fossil fuel industry’s hold on our political system and convincing our leaders that human health and the environment shouldn’t be externalized costs of economic growth.

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Bird’s eye view of a sand mine in Wisconsin. Photo by Ted Auch 2013.

7 Sand Mining Communities, 3 States, 5 Months – Part 1

An Exploration of Sand Mining Impacts: Lasalle County, IL by way of Chicago’s South Side
By Ted Auch, Great Lakes Program Coordinator

When it comes to high-volume hydraulic fracturing (HVHF), frac sand mining may be the most neglected aspect of the industry’s footprint. (HVHF demand on a per-well basis is increasing by 8% per year.)

To capture how this industry is changing several sand mining communities, I recently took a road trip to visit, photograph, and listen to the residents of this country’s primary frac sand areas. In total, I visited 7 sand mining communities in Illinois, Indiana, and Michigan.

This multimedia perspective is part of our ongoing effort to map and quantify the effects of silica sand mining on people, agriculture, wildlife, ecosystem services, and watersheds more broadly. Below is my attempt to give the FracTracker community a sense of what residents are hearing, seeing, and saying about the silica sand mining industry writ large.

Chicago’s South Side

Before heading to Illinois’ frac sand epicenter of Lasalle County, I couldn’t help but catch the South Shore Line out of Millennium Station. This station can be seen as you head south to the Hegewisch neighborhood on Chicago’s impoverished South Side, an area of greater Chicago-Gary, Indiana that has largely been forgotten by politicians in both states. Chicago_KCBX_BP

ChicagoLand_Income_Hardship

Figure 1. Average income per capita and Hardship Index (0-100 with 100 being the worst) for Chicago’s neighborhoods with Hegewisch highlighted in the city’s southeast corner.

This situation is a shame because collectively Hegewisch and the city of Whiting, IN are home to one of the largest – and getting larger – collections of oil refineries and oil sands infrastructure in the United States.

For an estimation of how difficult it is to live in various Chicago neighborhoods, see Figure 1, left.

This proliferation has not been without its dangers, including a compressor station explosion at BP PLC’s massive1 Whiting Refinery in August 2014. Unfortunately, that incident was just the latest in a long line of mishaps at this facility. The “operational incident,” as BP called it, rocked already stressed neighborhoods like MarkTown, IN – the aborted company town planned for steel maker Clayton Mark. MarkTown is on the National Register of Historic Places and is an example of a community that is being erased from the face of the earth in the name of Hydrocarbon Industrial Complex expansion. For those interested in architecture preservation, MarkTown’s rapid erasure is being conducted by BP itself and in the process we are losing an example of Conservatively Radical architect Howard Van Doren Shaw’s distinct English-style Tudor homes and urban planning. Residents speculate BP “may be buying up the properties because of concerns about liability.” The company counters they are just trying to create additional green space for residents.

KCBX_BP_POV

NAmerican_Ports_Refineries

Figure 2. Average daily oil refinery production per day across North America’s 152 Oil Refineries along with North American ports.

Luckily for everyone, operations following the aforementioned recent explosion were only “minimally impacted as a result of the incident and the refinery continue[d] to produce products for customers.” However, the more chronic concern is the tight supply-demand relationship between BP’s refinery and their Koch KCBX neighbor. Koch has made repeated headlines – and many neighbors turned enemies including the Southeast Environmental Task Force and its fearless leader Peggy Salazar – with its handling of the refinery’s annual production of 600,000 tons of petcoke a development Chicago Magazine called Mountains of Trouble. Petcoke is a byproduct of the refinery’s increased acceptance and processing of tar sands from Alberta Canada. Levels of production are likely to increase given BP’s completion in November 2014 of a “$4-billion revamp…to boost its intake of Canadian crude oil from 85,000 bpd to 350,000 bpd.”

Given how interconnected the hydrocarbon industry is, I thought it would be worth collecting some photos of the aforementioned infrastructure. When I saw that Koch KCBX’s terminal was also storing large amounts of silica sand, however, the connection between my next target(s) in LaSalle County was made even more obvious.

LaSalle vs. Chicagoland: A Tale of Two Worlds

Lasalle County, Illinois is situated approximately 50-60 miles south-southwest of Chicago. When you try to compare demographics and commerce, however, it is worlds away.

Chicagoland encompasses nearly 10,900 square miles – 9.5 times the area of Lasalle County. While Chicago’s population is expanding by 95,681 people per year, LaSalle’s is shrinking by 2,734 per year (Table 1). Chicagoans, though not South Siders, are making more than two times that of LaSalle County residents (with the latter actually falling nearly $4,700 below the state average). Predictably the demographics of Chicago reflect more and more those of the US, while LaSalle is typical of rural America with a population that is 93% white and only 3.3% foreign born. Thirty-five percent of Chicagoans are likely to achieve a bachelor’s degree, while only 16% of LaSalle County residents are likely to do so. Rates of poverty and more specifically child poverty, on the other hand, are significantly higher in Chicago. Finally, LaSalle is one of the country’s preeminent farming counties; it ranks #4 in the state and #126 nationally thanks to the value of agricultural commodities produced amounting to $448.5 million net of farm subsidies. See Table 1.

La Salle County, IL Silica Sand Mines & St. Peter Sandstone Geology

Figure 3. La Salle County, IL Silica Sand Mines & St. Peter Sandstone Geology

Chicago_Vs_LaSalleCounty_Comparison

Table 1. Chicagoland and LaSalle County, Illinois summary demographics, economic prosperity, and agricultural productivity.

Photos from the Tour

The above contrast was made crystal clear as I traveled down Interstate 80 westbound towards exit 90 and LaSalle’s County seat Ottawa (pop. 18,562). Upon arriving in Ottawa I drove west on Madison Street to the first target of our expedition: U.S. Silica Company’s mine and processing facility at the corner of Madison Boyce Memorial Drive. Upon arriving, however, it became clear that I would not find a suitable location to photograph the company’s mine; the perimeter had been fenced off and mounded up to the tune of 10-15 feet. So I got back in our rental car and drove to the mine’s southern perimeter adjacent to the Bear Den Bar and Grill and the Vine St.-Fern St.-15th Ave. neighborhood where there was clear line of site. It was here that I got some of the best photos of the mine’s scale and scope with respect to land-use, reclamation, and hydrology.

US_Silica_OttawaCo

Below is a sample of some of those images as well as several I took further down Route 34 between U.S. Silica’s active mine and a “reclaimed” Ottawa Silica Co. mine on the banks of the Illinois River.

After snapping several hundred shots of these two mines I headed to the I & M Canal State Trail between Utica and Ottawa emanating out of Buffalo Rock State Park and hiked east towards the Northern edge of U.S. Silica’s mine alongside a CSX railroad and recently constructed spur feeding into the mine’s loading terminal. The hope was that I would get a closer look at the mine but it turned out the angle was different but not better.

From the back of U.S. Silica’s Ottawa mine I traveled approximately 7 miles west to Unimin’s North Utica mine and a short dirt road off of 2803rd Road on the northern edge of the mine.

Unimin_NorthUtica

It was here that I photographed the mine’s reclamation plots, active mine pits, and developing water transport mechanisms. However, more importantly it was from here that I noticed off in the distance a bright red silica sand grain-size separator.

Curiously I did not – but do now – have this nascent and relatively small mine posted on our Frac Sands Mines and Related Facilities map at the time. Upon arriving at this site I found that the mine was owned and operated by a company called Northern White Sand a small mom & pop operation out of Utica, IL.

Unimin_NorthUtica_NorthernWhiteSand

The photos I took of this mine were primarily from atop a vegetated berm to the southwest of the mine’s primary footprint. This vantage point allowed us to get some great shots of the types of infrastructure/equipment typical of this sized mine including the aforementioned modular grain-size separator, conveyor belts, retention ponds, and the pyramid-like piles of powdery white silica sand so desired by the HVHF industry.

Our final stop on the LaSalle County silica sand mine tour landed us in Troy Grove 13 miles north of North Utica by way of Interstate 39. It was here that I visited several vantage points around Technisand’s MBI Manley Bros. silica mine. The expanse included the site’s mixture of old and new processing infrastructure, what appeared to be an alluvial fan derived from sand waste and associated wetland, and the mine’s far reaches alongside a Chicago and North Western Transportation Company (CNW) railroad.

Resident Testimonials

So now that I have outlined my tour of La Salle County I thought it would be helpful to share some of the stories residents told me during my travels and later by way of email.

Anna Mattes – La Salle County, IL

I live in LaSalle County, Illinois where I have prime farmland and Starved Rock State Park… the crown jewel of Illinois. I already have a fine farming industry and plenty of tourism as Starved Rock is visited by two million people annually. LaSalle County already has forty two quarries, gravel pits and sand mines. If I allow anymore the county will look as though it has been bombed. Empty sand pits will never produce food ever again. No amount of reclamation will restore this land to be productive…Each mine uses one million gallons of water daily. The LaSalle County Board has enlisted the USGS to do a hydrology study to determine how much water I have in our aquifer for municipalities and farming. Presently I have a moratorium in place on sand mines thru July 2016 and I hope forever. As a woman, wife and mother I am charged with the continuity of life. It is my job, profession, to raise healthy children, make a healthy breakfast and pack a nutritious lunch for my husband so he can do his job, and it generally falls to women to care for the elderly in families. With out clean air, pure water, healthy food what is the quality of life? Fracking is a dangerous business and I need to take better care of Planet Earth. Please do your part, I’m a Master Gardener and I’m doing my part.

Thomas Skomski – Wedron, IL

I am a resident of Wedron who has been severely impacted by Wedron Silica; and I want to report that there are many more problems associated with the influx of sand mines in LaSalle Co. than named in your recent article. In order to be fair to other residents who will be negatively affected by proximity to any sand mine I believe it is important to inform them and all concerned on the unmentioned problems associated with living near a sand mine. For example: the mountains of sand that are produced migrate everywhere the wind takes the particles. As I all know the winds are frequently fierce in this part of the country. One neighbor describes how in the morning when he sets his coffee cup down on his front porch and goes into his house to get the newspaper that he returns to find a layer of white sand covering his coffee. Another neighbor vacuums the sand off her living room rugs weekly while her husband regularly has to clean out sand-filled gutters. I do know that enabling pollutants on private property is technically criminal trespass. At the last EPA hearing in Wedron a retired mine employee admitted that Wedron Silica uses 100 million gallons of water per hour in sand processing. Some of this water is recycled. Since I have not confirmed those statistics, I prefer sticking to the fact that the mine has reversed the flow of the ground water. Who knows what the unseen consequences of that reversal might be? The toxic plume that Wedron Silica is in part responsible for creating migrates wherever the ground water moves. As a result of the threat of my well being poisoned my land, 23 acres has been devalued by the county to $1.00. All my five buildings are worth 40% of what they were before nine wells were poisoned in Wedron. Those wells were so toxic with benzene that water came out of the faucet orange and you could not breath it let alone use it to wash anything. Wedron Silica has begun buying homes in Wedron which will allow them to pursue their wealth with no concerns- BUT what about the water which I all know is in limited supply and susceptible to being polluted? So in summary, please include the human costs involved in a mine opening near you. My wife and I moved to the country to enjoy the solitude and quiet of living on a farm in our retirement years. The quality of our lives has been diminished, in addition the noise is disturbing; trains come in at all hours incessantly blowing their horns and the semi traffic is constant. Finally, I have heard a lot of what I consider negative criticism about the EPA. Having experienced this monumental problem directly it is perfectly clear to me that without the resources of a pro-environment organization I would be hard pressed to stand up to a corporation with multi billions in assets.

Ashley Williams – LaSalle County, IL

The nickname the “Silica Sand Capital of the World” has quickly transformed into a curse rather than a blessing for the citizens of LaSalle County, IL. Here, the frac sand industry continues to proliferate, endangering the health and safety of the people and local environment. Our precious life vessels: our air, water, and soil are under siege by a nexus of power that seeks to intimidate us into quiet submission, but I’ll be damned if I’m going to sit by and let that happen.

Footnote

  1. This facility alone processes nearly 2% of all oil in North America on a daily basis. This facility is the seventh-largest refinery in the United States and the largest outside of the Gulf Coast.
Indiana Shale Viewer

Indiana

Oil & Gas Activity in Indiana

Click on the image below to explore our IN map of oil and gas extraction-related activities.



32,733

Total Wells (As of Mar 2017)

Additional Maps & Data

Earthworks IN Oil & Gas Threat Map

Active oil & gas wells, & the counts of people, schools, & hospitals that live within ½ mile of these facilities. Project Launch: 2016

Frac Sand Mining Map

Map of silica sands/frac sand mines, drying facilities, & value added facilities in North America.

Indiana Photos & Videos


This album contains IN imagery contributed to our site from FracTracker staff and volunteers. Reuse is permitted so long as you cite the photographer if one is listed in the photo’s info section, as well as FracTracker Alliance.


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Over 1.1 Million Active Oil and Gas Wells in the US

Many people ask us how many wells have been hydraulically fractured in the United States.  It is an excellent question, but not one that is easily answered; most states don’t release data on well stimulation activities.  Also, since the data are released by state regulatory agencies, it is necessary to obtain data from each state that has oil and gas data to even begin the conversation.  We’ve finally had a chance to complete that task, and have been able to aggregate the following totals:

Oil and gas summary data of drilled wells in the United States.

Oil and gas summary data of drilled wells in the United States.

 

While data on hydraulically fractured wells is rarely made available, the slant of the wells are often made accessible.  The well types are as follows:

  • Directional:  Directional wells are those where the top and the bottom of the holes do not line up vertically.  In some cases, the deviation is fairly slight.  These are also known as deviated or slant wells.
  • Horizontal:  Horizontal wells are directional wells, where the well bore makes something of an “L” shape.  States may have their own definition for horizontal wells.  In Alaska, these wells are defined as those deviating at least 80° from vertical.  Currently, operators are able to drill horizontally for several miles.
  • Directional or Horizontal:  These wells are known to be directional, but whether they are classified as horizontal or not could not be determined from the available data.  In many cases, the directionality was determined by the presence of directional sidetrack codes in the well’s API number.
  • Vertical:  Wells in which the top hole and bottom hole locations are in alignment.  States may have differing tolerances for what constitutes a vertical well, as opposed to directional.
  • Hydraulically Fractured:  As each state releases data differently, it wasn’t always possible to get consistent data.  These wells are known to be hydraulically fractured, but the slant of the well is unknown.
  • Not Fractured:  These wells have not been hydraulically fractured, and the slant of the well is unknown.
  • Unknown:  Nothing is known about the slant, stimulation, or target formation of the well in question.
  • Unknown (Shale Formation):  Nothing is known about the slant or stimulation of the wells in question; however, it is known that the target formation is a major shale play.  Therefore, it is probable that the well has been hydraulically fractured, with a strong possibility of being drilled horizontally.

Wells that have been hydraulically fractured might appear in any of the eight categories, with the obvious exception of “Not Fractured.”  Categories that are very likely to be fractured include, “Horizontal”, “Hydraulically Fractured”, and “Unknown (Shale Formation),” the total of which is about 32,000 wells.  However, that number doesn’t include any wells from Texas or Colorado, where we know thousands wells have been drilled into major shale formations, but the data had to be placed into categories that were more vague.

Oil and gas wells in the United States, as of February 2014. Location data were not available for Maryland (n=104), North Carolina (n=2), and Texas (n=303,909).  To access the legend and other map tools, click the expanding arrows icon in the top-right corner.

The standard that we attempted to reach for all of the well totals was for wells that have been drilled but have not yet been plugged, which is a broad spectrum of the well’s life-cycle.  In some cases, decisions had to be made in terms of which wells to include, due to imperfect metadata.

No location data were available for Maryland, North Carolina, or Texas.  The first two have very few wells, and officials in Maryland said that they expect to have the data available within about a month.  Texas location data is available for purchase, however such data cannot be redistributed, so it was not included on the map.

It should not be assumed that all of the wells that are shown in  the map above the shale plays and shale basin layers are actually drilled into shale.  In many cases, however, shale is considered a source rock, where hydrocarbons are developed, before the oil and gas products migrate upward into shallower, more conventional formations.

The raw data oil and gas data is available for download on our site in shapefile format.