Revision as of 12:44, 29 August 2004 view sourceGhitis (talk | contribs)77 edits This article is momentarily being reedited by Heron, after a user messed it.← Previous edit | Revision as of 13:22, 29 August 2004 view source Bensaccount (talk | contribs)8,584 edits reverting...Im not sure what is going on with this pageNext edit → | ||
Line 1: | Line 1: | ||
''' Matter ''' is anything that has ] and occupies ]. One contemporary view on matter takes it as all scientifically observable entities whatsoever. Matter can more acurately be defined as the energy that has a low vibratory rate, a compressed energy state. Commonly, the definition is limited to such entities explored by ]. | |||
The definition pursued here is of '''matter''' as whatever the smallest, most fundamental entities in ] seem to be. | |||
Thus matter can be seen as material consisting of particles which are ]s and therefore obey the ], which states that no two fermions can be in the same ]. Because of this principle, the particles which comprise matter do not all end up in their lowest energy state, and hence it is possible to create stable structures out of fermions. In addition, the Pauli exclusion principle insures that two pieces of matter will not occupy the same | |||
location at the same time, and therefore two pieces of matter in which most energy states are filled will tend to collide with each other rather than passing through each other as with energy fields such as ]. | |||
The matter that we observe most commonly takes the form of ]s, ]s, ]s, or pure ]s. | |||
In response to different thermodynamic conditions such as ] and ], matter can exist in different "]s", the most familar of which are ], ], and ]. Others include ], ], and ]. When matter changes from one phase to another, it undergoes what is known as a ], a phenomenon studied in the field of ]. | |||
"Matter" is also, apparently, used in contrast to ], in the sense of content. | |||
''See also:'' ]; ]; ]'', which provides a bit of historical background'' | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] | |||
] |
Revision as of 13:22, 29 August 2004
Matter is anything that has mass and occupies space. One contemporary view on matter takes it as all scientifically observable entities whatsoever. Matter can more acurately be defined as the energy that has a low vibratory rate, a compressed energy state. Commonly, the definition is limited to such entities explored by physics.
The definition pursued here is of matter as whatever the smallest, most fundamental entities in physics seem to be. Thus matter can be seen as material consisting of particles which are fermions and therefore obey the Pauli exclusion principle, which states that no two fermions can be in the same quantum state. Because of this principle, the particles which comprise matter do not all end up in their lowest energy state, and hence it is possible to create stable structures out of fermions. In addition, the Pauli exclusion principle insures that two pieces of matter will not occupy the same location at the same time, and therefore two pieces of matter in which most energy states are filled will tend to collide with each other rather than passing through each other as with energy fields such as light.
The matter that we observe most commonly takes the form of compounds, polymers, alloys, or pure elements.
In response to different thermodynamic conditions such as temperature and pressure, matter can exist in different "phases", the most familar of which are solid, liquid, and gas. Others include plasma, superfluid, and Bose-Einstein condensate. When matter changes from one phase to another, it undergoes what is known as a phase transition, a phenomenon studied in the field of thermodynamics.
"Matter" is also, apparently, used in contrast to form, in the sense of content.
See also: Antimatter; Phases of matter; Particle physics, which provides a bit of historical background