Helium is a chemical element with atomic number 2 which means there are 2 protons and 2 electrons in the atomic structure. Helium (He), chemical element, inert gas of Group 18 (noble gases) of the periodic table. The second lightest element (only hydrogen is lighter), helium is a colourless, odourless, and tasteless gas that becomes liquid at −268.9 °C (−452 °F). The boiling and freezing points of helium are lower than those of any other known substance.
The Element Helium
[Click for Isotope Data]
Atomic Number: 2
Atomic Weight: 4.002602
Melting Point: 0.95 K (-272.2°C or -458.0°F)
Boiling Point: 4.22 K (-268.93°C or -452.07°F)
Density: 0.0001785 grams per cubic centimeter
Phase at Room Temperature: Gas
Element Classification: Non-metal
Period Number: 1
Group Number: 18
Group Name: Noble Gas
What's in a name? For the Greek god of the sun, Helios.
Say what? Helium is pronounced as HEE-lee-em.
History and Uses:
Helium, the second most abundant element in the universe, was discovered on the sun before it was found on the earth. Pierre-Jules-César Janssen, a French astronomer, noticed a yellow line in the sun's spectrum while studying a total solar eclipse in 1868. Sir Norman Lockyer, an English astronomer, realized that this line, with a wavelength of 587.49 nanometers, could not be produced by any element known at the time. It was hypothesized that a new element on the sun was responsible for this mysterious yellow emission. This unknown element was named helium by Lockyer.
The hunt to find helium on earth ended in 1895. Sir William Ramsay, a Scottish chemist, conducted an experiment with a mineral containing uranium called clevite. He exposed the clevite to mineral acids and collected the gases that were produced. He then sent a sample of these gases to two scientists, Lockyer and Sir William Crookes, who were able to identify the helium within it. Two Swedish chemists, Nils Langlet and Per Theodor Cleve, independently found helium in clevite at about the same time as Ramsay.
Helium makes up about 0.0005% of the earth's atmosphere. This trace amount of helium is not gravitationally bound to the earth and is constantly lost to space. The earth's atmospheric helium is replaced by the decay of radioactive elements in the earth's crust. Alpha decay, one type of radioactive decay, produces particles called alpha particles. An alpha particle can become a helium atom once it captures two electrons from its surroundings. This newly formed helium can eventually work its way to the atmosphere through cracks in the crust.
Helium is commercially recovered from natural gas deposits, mostly from Texas, Oklahoma and Kansas. Helium gas is used to inflate blimps, scientific balloons and party balloons. It is used as an inert shield for arc welding, to pressurize the fuel tanks of liquid fueled rockets and in supersonic windtunnels. Helium is combined with oxygen to create a nitrogen free atmosphere for deep sea divers so that they will not suffer from a condition known as nitrogen narcosis. Liquid helium is an important cryogenic material and is used to study superconductivity and to create superconductive magnets. The Department of Energy's Jefferson Lab uses large amounts of liquid helium to operate its superconductive electron accelerator.
Helium is an inert gas and does not easily combine with other elements. There are no known compounds that contain helium, although attempts are being made to produce helium diflouride (HeF2).
Estimated Crustal Abundance: 8×10-3 milligrams per kilogram
Estimated Oceanic Abundance: 7×10-6 milligrams per liter
Number of Stable Isotopes: 2 (View all isotope data)
Ionization Energy: 24.587 eV
Oxidation States: 0
Electron Shell Configuration:
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Home » Oil & Gas » Helium
Helium's unique properties make it the perfect gas for many important applications
Article by: Hobart M. King, PhD, RPG
Helium blimp: Most people have heard of helium being used as a lifting gas for weather balloons, blimps, and party balloons. These are very minor uses of helium. The use that consumes more helium than any other is cooling the magnets in MRI (magnetic resonance imaging) machines in medical facilities. Goodyear blimp photo by Derek Jensen.
What is Helium?
Helium is a chemical element and a colorless, odorless, tasteless, inert gas. It has the smallest atomic radius of any element and the second-lowest atomic weight. It is lighter than air.
Most people know that helium is used as a lifting gas in blimps and party balloons, but they can't name another way in which it is used. The number one use of helium is as a cooling gas for magnetic resonance imaging (MRI) machines used in medical facilities. Other important uses of helium include: a protective gas for welding, an inert gas for controlled atmosphere manufacturing, a fugitive gas used for leak detection, and a low-viscosity gas for pressurized breathing mixtures.
Where Does Helium Come From?
Very little helium is present in Earth's atmosphere. It is such a light element that Earth's gravity cannot hold it. When present at Earth's surface, unconfined helium immediately begins rising until it escapes the planet. That's why party balloons rise!
The helium that is produced commercially is obtained from the ground. Some natural gas fields have enough helium mingled with the gas that it can be extracted at an economical cost. A few fields in the United States contain over 7% helium by volume. Companies that drill for natural gas in these areas produce the natural gas, process it and remove the helium as a byproduct.
Helium-bearing natural gas deposits: Deposit model for helium-bearing natural gas fields in the United States. Helium is produced by the decay of uranium and thorium in granitoid basement rocks. The liberated helium is buoyant and moves toward the surface in porosity associated with basement faults. The helium then moves upward through porous sedimentary cover until it is trapped with natural gas under beds of anhydrite or salt. These are the only laterally-persistent rock types that are able to trap and contain the tiny, buoyant helium atoms. This geological situation only occurs at a few locations in the world and is why rich helium accumulations are rare.
Related:A New Use of Helium - Hard Drives
Why is Helium in Some Natural Gas?
Most of the helium that is removed from natural gas is thought to form from radioactive decay of uranium and thorium in granitoid rocks of Earth's continental crust. As a very light gas, it is buoyant and seeks to move upward as soon as it forms.
The richest helium accumulations are found where three conditions exist: 1) granitoid basement rocks are rich in uranium and thorium; 2) the basement rocks are fractured and faulted to provide escape paths for the helium; and, 3) porous sedimentary rocks above the basement faults are capped an impermeable seal of halite or anhydrite.  When all three of these conditions are met, helium might accumulate in the porous sedimentary rock layer.
Helium has the smallest atomic radius of any element, about 0.2 nanometers. So, when it forms and starts moving upward, it can fit through very small pore spaces within the rocks. Halite and anhydrite are the only sedimentary rocks that can block the upward migration of helium atoms. Shales that have their pore spaces plugged with abundant organic materials (kerogen) sometimes serve as a less effective barrier.
Helium-bearing natural gas deposits: Map showing the natural gas fields that serve as important sources of helium in the United States. The natural gas produced from these fields contains between 0.3% to over 7% helium. The helium is removed from the gas for commercial sale. Image by Geology.com using location data from the United States Geological Survey. 
Where is Natural Gas Rich in Helium?
Most unprocessed natural gas contains at least trace amounts of helium. Very few natural gas fields contain enough to justify a helium recovery process. A natural gas source must contain at least 0.3% helium to be considered as a potential helium source.
In 2010, all of the natural gas processed for helium in the United States came from fields in Colorado, Kansas, Oklahoma, Texas, Utah, and Wyoming as shown on the accompanying map. The Hugoton Field in Oklahoma, Kansas and Texas; the Panoma Field in Kansas; the Keyes Field in Oklahoma; the Panhandle West and Cliffside Fields in Texas, and the Riley Ridge Field in Wyoming account for most of the helium production in the United States. 
During 2010, the United States produced 128 million cubic meters of helium. Of that amount, 53 million cubic meters of helium were extracted from natural gas, and 75 million cubic meters were withdrawn from the National Helium Reserve. Other countries with known production amounts were: Algeria (18 mcm), Qatar (13 mcm), Russia (6 mcm), and Poland (3 mcm). Canada and China produced small but unreported amounts of helium. 
Helium in MRI machines: The number one use of helium is cooling the magnets in the MRI (magnetic resonance imaging) machines used to diagnose disease and injury in medical facilities.
A New Use for Helium: The first helium-sealed hard drive was produced in 2013. Helium enables the drive to use less energy, produce less heat, make less noise, take up less space, hold more data and produce fewer vibrations than a standard hard drive. Learn more. Photo copyright iStockphoto / deepblue4you.
Uses of Helium
Helium has a number of properties that make it exceptionally well-suited for certain uses. In some of these uses, helium is the best possible gas to use, and in a few there is no adequate substitute for helium. Several uses of helium along with the properties that make it suitable for the use are described below.
Magnetic Resonance Imaging
The number one use of helium is in the magnetic resonance imaging machines used in medical facilities to assess injuries and diagnose illness. These machines utilize a magnetic field that is produced by a superconducting magnet. These magnets generate an enormous amount of heat. Liquid helium is the cooling substance of choice for regulating the temperature of these magnets. Because helium has the second-lowest specific heat of any gas and the lowest boiling/melting point of any element, there is no foreseen substitute for helium in this very important use.
Helium has the second-lowest atomic weight of any element. Only hydrogen has a lower atomic weight. As a lighter-than-air gas, helium has been used as a 'lifting gas' for airships and balloons. Blimps, dirigibles, zeppelins, anti-aircraft balloons, weather balloons and other lighter-than-air craft have all used helium as a lifting gas. It is much safer than hydrogen because it is not flammable. This was the most important category of helium use until the end of World War II. Much lower amounts of helium are now used as a lifting gas.
Purging gas: Helium is used by NASA and the Department of Defense to purge liquid oxygen and liquid hydrogen from fuel tanks and fuel delivery systems of rocket engines. Helium is inert and has a freezing temperature that is so low that it remains a gas through the purging process. A flow of helium into these systems has even been used during emergencies to extinguish fires. Image by NASA.
Helium has the lowest melting and boiling point of any gas. It melts and boils at temperatures close to absolute zero. Because it remains a gas at very low temperatures, it can be used as a purging gas for fuel tanks and fuel delivery systems that are filled with very cold liquids such as liquid hydrogen and liquid oxygen. Because it is inert and has a low freezing temperature, it can displace these fuels safely without freezing. Large amounts of helium are used by NASA and the Department of Defense for purging rocket propulsion systems.
Controlled Atmosphere Manufacturing
Helium is an inert gas. The only gas with a lower reactivity is neon. This low reactivity makes helium a valuable gas to use in manufacturing and repair processes when an inert atmosphere is required. Helium also has the second-lowest density of any gas along with a very high thermal conductivity. These properties of helium gas make it the atmosphere of choice for many metallurgical processes, growing perfect crystals in chemical vapors, manufacturing optical fibers and other uses.
Helium has a very low viscosity, a high diffusion coefficient, and the smallest atom of any element. These characteristics make helium very hard to contain. If a system has a leak, helium will escape. Helium gas is therefore used to test high vacuum systems, fuel systems and other containments for leaks.
Helium breathing mixtures: Helium is used to prepare breathing gas mixtures for deep-water diving. Helium is inert and has a low viscosity under pressure which allows easier breathing. Image by NOAA.
Helium and other inert gases are used to prepare breathing mixtures for deep-water diving and medical treatments. Helium is used here because it is inert, has a very low viscosity and is easier to breathe under pressure than any other gas.
Helium is used as a protective atmosphere when welding. An inert gas atmosphere protects hot metals from oxidation and other reactions that might occur rapidly at high temperatures.
Uses of helium: Relative amounts of helium consumed by various uses in the United States during 2011. Graph by Geology.com using data from USGS.
Helium: A Nonrenewable Resource
Helium is a gas that is only found where a coincidence of unlikely situations occur. Although it is continually being produced by radioactive mineral decay in Earth's crust, its rate of natural production and accumulation is so slow that it must be considered a nonrenewable resource.
|  Helium in New Mexico: Ronald F. Broadhead, New Mexico Geology, New Mexico Bureau of Geology and Mineral Resources, New Mexico Institute of Mining and Technology, November 2005. |
 Helium 2010: Joseph B. Peterson and Peter J. Madrid, Minerals Yearbook, United States Geological Survey, January 2012.
 Helium 2012: Peter J. Madrid, Mineral Commodity Summaries, United States Geological Survey, January 2012.
 Selling the Nation's Helium Reserve: Committee on Understanding the Impact of Selling the Helium Reserve, National Research Council, The National Academies Press, 2010.
 Testimony on the Helium Stewardship Act of 2013: Testimony before the House of Representatives Subcommittee on Energy and Mineral Resources, United States Government Accountability Office, GAO-15-734T, July 8, 2015.
 Fast-Rising Helium Prices May Pop Balloon Sales: Rachel Rodgers and Sharon Barricklow, an article in the Decatur Herald-Review, February 2015.
Helium Gluts and Helium Shortages
In 1925 the United States established the National Helium Reserve to serve as a strategic supply of helium for use in airships and for other defense purposes. At that time the country was producing much more helium than was being consumed. After World War II the amount of helium used as a lifting gas declined, but demand for helium as a purging gas when refueling rocket engines and as a coolant in nuclear weapons facilities surged. Still, more helium was being produced than consumed.
In 1995, Congress decided that the National Helium Reserve was not essential and initiated a program to sell the helium as part of the Helium Privatization Act of 1996.  For almost two decades Congress allowed the helium to be sold at an enormous discount to free-market prices. Up to 1/2 of the world's helium demand was being met through sales from the National Helium Reserve. In some years more helium was exported out of the United States to other countries than was consumed domestically.  Those who purchased helium from the government got a fantastic deal, and those who purchased helium in the free market paid a much higher price.
Dumping of National Helium Reserve stock into the market depressed the price of helium so much that it was being used as a cheap substitute for argon and other gases that have a much less limited supply.
Because commercial helium production was not rewarded or heavily utilized, the market was undersupplied when National Helium Reserve sales were replaced by an auction system in 2014. In the first auction, two bidders purchased the entire yearly allocation of 93 million cubic feet of helium at more than double the previous year's market price. After the auction another 1 billion cubic feet was sold to the same two bidders. 
Since the first auction, the price of helium continued to rise because production of new helium falls short of consumption. The price increase has triggered investment in new helium processing plants. However, helium can only be produced from natural gas fields with salt or anhydrate as a trap rock. These only occur in a few parts of the world.
Under current law, the National Helium Reserve will be sold-out by 2021. Hopefully the rising investment in helium recovery plants will be adequate to meet the needs of helium consumers when that important source of helium is gone.
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