{"id":198,"date":"2017-12-14T21:29:02","date_gmt":"2017-12-14T21:29:02","guid":{"rendered":"https:\/\/courses.lumenlearning.com\/suny-mcc-introductorychemistry\/chapter\/introduction-to-gases\/"},"modified":"2017-12-14T21:29:02","modified_gmt":"2017-12-14T21:29:02","slug":"introduction-to-gases","status":"publish","type":"chapter","link":"https:\/\/courses.lumenlearning.com\/suny-introductory-chemistry\/chapter\/introduction-to-gases\/","title":{"raw":"Introduction to Gases","rendered":"Introduction to Gases"},"content":{"raw":"
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Opening Essay<\/h3>\n

Perhaps one of the most spectacular chemical reactions involving a gas occurred on May 6, 1937, when the German airship Hindenburg<\/em> exploded on approach to the Naval Air Station in Lakehurst, New Jersey. The actual cause of the explosion is still unknown, but the entire volume of hydrogen gas used to float the airship, about 200,000 m3<\/sup>, burned in less than a minute. Thirty-six people, including one on the ground, were killed.<\/p>\n\n

\n\n[caption id=\"attachment_3217\" align=\"alignnone\" width=\"400\"]\"The<\/a> The German airship Hindenburg (left) was one of the largest airships ever built. However, it was filled with hydrogen gas and exploded in Lakehurst, New Jersey, at the end of a transatlantic voyage in May 1937 (right). Source: \u201cHindenburg\u201d by James Vaughan is licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 2.0 Generic. \u201cHindenburg burning\u201d by Gus Pasquerella is in the public domain.[\/caption]\n

Hydrogen is the lightest known gas. Any balloon filled with hydrogen gas will float in air if its mass is not too great. This makes hydrogen an obvious choice for flying machines based on balloons\u2014airships, dirigibles, and blimps. However, hydrogen also has one obvious drawback: it burns in air according to the well-known chemical equation<\/p>\n\n<\/div>\n2 H2<\/sub>(g) +\u00a0O2<\/sub>(g) \u2192\u00a02 H2<\/sub>O(\u2113)<\/span><\/span>\n

So although hydrogen is an obvious choice, it is also a dangerous choice.<\/p>\n

Helium gas is also lighter than air and has 92% of the lifting power of hydrogen. Why, then, was helium not used in the Hindenburg<\/em>? In the 1930s, helium was much more expensive. In addition, the best source of helium at the time was the United States, which banned helium exports to pre\u2013World War II Germany. Today all airships use helium, a legacy of the Hindenburg<\/em> disaster.<\/p>\n\n<\/div>\n

Of the three basic phases of matter\u2014solids, liquids, and gases\u2014only one of them has predictable physical properties: gases. In fact, the study of the properties of gases was the beginning of the development of modern chemistry from its alchemical roots. The interesting thing about some of these properties is that they are independent of the identity of the gas. That is, it doesn\u2019t matter if the gas is helium gas, oxygen gas, or sulfur vapours; some of their behaviour is predictable and, as we will find, very similar. In this chapter, we will review some of the common behaviours of gases.<\/p>\n

Let us start by reviewing some properties of gases. Gases have no definite shape or volume; they tend to fill whatever container they are in. They can compress and expand, sometimes to a great extent. Gases have extremely low densities, one-thousandth or less the density of a liquid or solid. Combinations of gases tend to mix together spontaneously; that is, they form solutions. Air, for example, is a solution of mostly nitrogen and oxygen. Any understanding of the properties of gases must be able to explain these characteristics.<\/p>\n\n<\/div>\n<\/div>","rendered":"

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Opening Essay<\/h3>\n

Perhaps one of the most spectacular chemical reactions involving a gas occurred on May 6, 1937, when the German airship Hindenburg<\/em> exploded on approach to the Naval Air Station in Lakehurst, New Jersey. The actual cause of the explosion is still unknown, but the entire volume of hydrogen gas used to float the airship, about 200,000 m3<\/sup>, burned in less than a minute. Thirty-six people, including one on the ground, were killed.<\/p>\n

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\"The<\/a><\/p>\n

The German airship Hindenburg (left) was one of the largest airships ever built. However, it was filled with hydrogen gas and exploded in Lakehurst, New Jersey, at the end of a transatlantic voyage in May 1937 (right).
Source: \u201cHindenburg\u201d by James Vaughan is licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 2.0 Generic. \u201cHindenburg burning\u201d by Gus Pasquerella is in the public domain.<\/p>\n<\/div>\n

Hydrogen is the lightest known gas. Any balloon filled with hydrogen gas will float in air if its mass is not too great. This makes hydrogen an obvious choice for flying machines based on balloons\u2014airships, dirigibles, and blimps. However, hydrogen also has one obvious drawback: it burns in air according to the well-known chemical equation<\/p>\n<\/div>\n

2 H2<\/sub>(g) +\u00a0O2<\/sub>(g) \u2192\u00a02 H2<\/sub>O(\u2113)<\/span><\/span><\/p>\n

So although hydrogen is an obvious choice, it is also a dangerous choice.<\/p>\n

Helium gas is also lighter than air and has 92% of the lifting power of hydrogen. Why, then, was helium not used in the Hindenburg<\/em>? In the 1930s, helium was much more expensive. In addition, the best source of helium at the time was the United States, which banned helium exports to pre\u2013World War II Germany. Today all airships use helium, a legacy of the Hindenburg<\/em> disaster.<\/p>\n<\/div>\n

Of the three basic phases of matter\u2014solids, liquids, and gases\u2014only one of them has predictable physical properties: gases. In fact, the study of the properties of gases was the beginning of the development of modern chemistry from its alchemical roots. The interesting thing about some of these properties is that they are independent of the identity of the gas. That is, it doesn\u2019t matter if the gas is helium gas, oxygen gas, or sulfur vapours; some of their behaviour is predictable and, as we will find, very similar. In this chapter, we will review some of the common behaviours of gases.<\/p>\n

Let us start by reviewing some properties of gases. Gases have no definite shape or volume; they tend to fill whatever container they are in. They can compress and expand, sometimes to a great extent. Gases have extremely low densities, one-thousandth or less the density of a liquid or solid. Combinations of gases tend to mix together spontaneously; that is, they form solutions. Air, for example, is a solution of mostly nitrogen and oxygen. Any understanding of the properties of gases must be able to explain these characteristics.<\/p>\n<\/div>\n<\/div>\n\n\t\t\t

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Candela Citations<\/h3>\n\t\t\t\t\t
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CC licensed content, Shared previously<\/div>