# Difference between revisions of "Size measures for items related to cells"

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| diameter of [[eukaryotic cell]] (varies based on organism and cell type) || <math>10^{-5}</math><br>to<br><math>10^{-4}</math> || <math>10^{10}</math><br>to<br><math> 10^{11}</math> || <math>10^7</math><br>to<br><math>10^8</math> || <math>10^5</math><br>to<br><math>10^6</math> || <math>10^4</math><br>to<br><math>10^5</math> || 10<br>to<br>100 || 0.01<br>to<br>0.1 | | diameter of [[eukaryotic cell]] (varies based on organism and cell type) || <math>10^{-5}</math><br>to<br><math>10^{-4}</math> || <math>10^{10}</math><br>to<br><math> 10^{11}</math> || <math>10^7</math><br>to<br><math>10^8</math> || <math>10^5</math><br>to<br><math>10^6</math> || <math>10^4</math><br>to<br><math>10^5</math> || 10<br>to<br>100 || 0.01<br>to<br>0.1 | ||

|} | |} | ||

+ | |||

+ | ==Comparison of areas and volumes== | ||

+ | |||

+ | The [[relation between ratios of lengths, areas, and volumes]] states that for two items with the same shape, the ratio of corresponding areas is the square of the ratio of corresponding lengths, and the ratio of corresponding volumes is the cube of the ratio of corresponding lengths. Even for objects of somewhat different shapes, the above holds to a reasonable approximation if the shapes are reasonably similar. We can use this to do quick and approximate computations of the ratio of volumes of the atom and the atomic nucleus, or the ratio of volumes of eukaryotic and prokaryotic cells. |

## Latest revision as of 16:14, 27 May 2012

This page lists order of magnitude estimates for the sizes of various microscopic items that are related to cells. The goal is to give a rough sense of what individual sizes mean, since these are too small for us to compare with our day-to-day intuitions.

## Contents

## Units for length

### Units

Unit for length (full word) | Unit for length (shorthand) | In terms of meters (m) | What's it used to measure? |
---|---|---|---|

femtometer | fm | nucleus of an atom (not nucleus of a cell). Rarely used in biology
| |

picometer | pm | radius and diameter of an atom or size of a molecule. Used in biology when talking about biological membranes and passage of ions through membranes | |

angstrom | A | sizes of molecules, wavelengths of light | |

nanometer | nm | sizes of very large molecules, substructures and organelles of cells, wavelengths of light | |

micron or micrometer | m | sizes of cells and cellular organelles | |

millimeter | mm | Rarely used in cell biology. May be used for tissues and cell clusters |

### Conversion between units

Unit for length (full word) | Unit for length (shorthand) | Number of fm | Number of pm | Number of angstroms | Number of nm | Number of m | Number of mm |
---|---|---|---|---|---|---|---|

femtometer | fm | 1 | |||||

picometer | pm | 1 | |||||

angstrom | A | 1 | |||||

nanometer | nm | 10 | 1 | ||||

micron or micrometer | m | 1 | |||||

millimeter | mm | 1 |

Item | Number of meters | Number of fm | Number of pm | Number of angstroms | Number of nm | Number of m | Number of mm |
---|---|---|---|---|---|---|---|

diameter of atomic nucleus (varies with element) = twice the nuclear radius | to |
1.5 to 15 |
to |
to |
to |
to |
to |

diameter of atom (varies with element) = twice the atomic radius | to |
5000 to 60000 |
50 to 600 |
0.5 to 6 |
0.05 to 0.6 |
to |
to |

thickness of lipid bilayer | to |
to |
1000 to 10000 |
10 to 100 |
1 to 10 |
to |
to |

wavelength of visible light in vacuum (wavelength depends on color) | to |
to |
to |
4000 to 7000 |
400 to 700 |
0.4 to 0.7 |
to |

diameter of prokaryotic cell (varies based on organism) | to |
to |
to |
to |
1000 to 10000 |
1 to 10 |
to |

diameter of eukaryotic cell (varies based on organism and cell type) | to |
to |
to |
to |
to |
10 to 100 |
0.01 to 0.1 |

## Comparison of areas and volumes

The relation between ratios of lengths, areas, and volumes states that for two items with the same shape, the ratio of corresponding areas is the square of the ratio of corresponding lengths, and the ratio of corresponding volumes is the cube of the ratio of corresponding lengths. Even for objects of somewhat different shapes, the above holds to a reasonable approximation if the shapes are reasonably similar. We can use this to do quick and approximate computations of the ratio of volumes of the atom and the atomic nucleus, or the ratio of volumes of eukaryotic and prokaryotic cells.