*< sup > 278 </ sup > Mt in the decay chain of < sup > 294 </ sup > Uus ;

*< sup > 276 </ sup > Mt in the decay chain of < sup > 288 </ sup > Uup ;

*< sup > 275 </ sup > Mt in the decay chain of < sup > 287 </ sup > Uup ;

*< sup > 274 </ sup > Mt in the decay chain of < sup > 282 </ sup > Uut ;

*< sup > 270 </ sup > Mt in the decay chain of < sup > 278 </ sup > Uut ;

*< sup > 268 </ sup > Mt in the decay chain of < sup > 272 </ sup > Rg.

*< sup > 237 </ sup > U is also produced via an ( n, 2n ) reaction with < sup > 238 </ sup > U. This only happens with very energetic neutrons.

*< cite > Science and Sanity: An Introduction to Non-Aristotelian Systems and General Semantics </ cite >, Alfred Korzybski, Preface by Robert P. Pula, Institute of General Semantics, 1994, hardcover, 5th edition, ISBN 0-937298-01-8, ( full text online )

*< span class =" plainlinks "> Charles Lyell </ span > Notable Names Database.

*< tt > File Checksum Integrity Verifier ( FCIV )</ tt >, a command-prompt utility from Microsoft that computes and verifies MD5 or SHA-1 cryptographic hash values of files.

*< cite id = junkbox ></ cite >

*< cite id = Electronic Design ></ cite >

*< cite id = refClem1948 > G M Clemence, " On the System of Astronomical Constants ", Astronomical Journal, vol. 53 ( 6 ) ( 1948 ), issue # 1170, pp 169 – 179 .</ cite >

*< cite id = refClem1971 > G M Clemence ( 1971 ), " The Concept of Ephemeris Time ", Journal for the History of Astronomy, vol. 2 ( 1971 ), pp. 73 – 79 .</ cite >

*< cite id = refGuin1988 > B Guinot and P K Seidelmann ( 1988 ), " Time scales – Their history, definition and interpretation ", Astronomy and Astrophysics, vol.

*< cite id = refESAE >' ESAE 1961 ': " Explanatory Supplement to the Astronomical Ephemeris and the American Ephemeris and Nautical Almanac " (' prepared jointly by the Nautical Almanac Offices of the United Kingdom and the United States of America ', HMSO, London, 1961 ).</ cite >

*< cite id = refIAU1976 > IAU resolutions ( 1976 ): Resolutions adopted by the IAU in 1976 at Grenoble .</ cite >

*< cite id = refILE >" Improved Lunar Ephemeris ", US Government Printing Office, 1954 .</ cite >

*< cite id = refMark1955 > W Markowitz, R G Hall, S Edelson ( 1955 ), " Ephemeris time from photographic positions of the moon ", Astronomical Journal, vol.

*< cite id = refMark1958 > W Markowitz, R G Hall, L Essen, J V L Parry ( 1958 ), " Frequency of cesium in terms of ephemeris time ", Physical Review Letters, vol. 1 ( 1958 ), 105 – 107 .</ cite >

*< cite id = refMark1959 > W Markowitz ( 1959 ), " Variations in the Rotation of the Earth, Results Obtained with the Dual-Rate Moon Camera and Photograhic Zenith Tubes ", Astronomical Journal, vol. 64 ( 1959 ), pp. 106 – 113 .</ cite >

*< cite id = refMark1988 > Wm Markowitz ( 1988 ), " Comparisons of ET ( Solar ), ET ( Lunar ), UT and TDT ", in A K Babcock & G A Wilkins ( eds.

*< cite id = tr32-1306 > W G Melbourne, J D Mulholland, W L Sjogren, F M Sturms ( 1968 ), " Constants and Related Information for Astrodynamic Calculations ", NASA Technical Report 32-1306, Jet Propulsion Laboratory, July 15, 1968 .</ cite >

*< cite id = morrste2004 > L V Morrison, F R Stephenson ( 2004 ), " Historical values of the Earth's clock error ΔT and the calculation of eclipses ", Journal for the History of Astronomy ( ISSN 0021-8286 ), vol.

*< cite id = refNewcSun > Simon Newcomb ( 1895 ), Tables of the Sun (" Tables of the Motion of the Earth on its Axis and Around the Sun ", in " Tables of the Four Inner Planets ", vol.

*< cite id = refSitter1927 > W de Sitter ( 1927 ), " On the secular accelerations and the fluctuations of the longitudes of the moon, the sun, Mercury and Venus ", Bull.

*< sup > 1 </ sup >

*< sup >( 1 )</ sup > -

*< cite id = cro2000 > Crowell, Benjamin, ( 2011 ), Light and Matter, ( 2011, Light and Matter ), especially at Section 4. 2, Newton's First Law, Section 4. 3, Newton's Second Law, and Section 5. 1, Newton's Third Law .</ cite >

*< cite id = new1729v1 > Newton, Isaac, " Mathematical Principles of Natural Philosophy ", 1729 English translation based on 3rd Latin edition ( 1726 ), volume 1, containing Book 1, especially at the section Axioms or Laws of Motion starting page 19 .</ cite >

*< cite id = tho1867 > Thomson, W ( Lord Kelvin ), and Tait, P G, ( 1867 ), Treatise on natural philosophy, volume 1, especially at Section 242, Newton's laws of motion .</ cite >

*< sup > 1 </ sup >/< sub > 4 </ sub > turn.

*< div id =" 1 E + 25 m³ "> 1 E + 25 m³ or 10 < sup > 25 </ sup > m³ equals :</ div >

*< div id =" 1 E + 26 m³ "> 1 E + 26 m³ or 10 < sup > 26 </ sup > m³ equals :</ div >

*< div id =" 1 E + 22 m³ "> 1 E + 22 m³ or 10 < sup > 22 </ sup > m³ equals :</ div >

*< div id =" 1 E + 23 m³ "> 1 E + 23 m³ or 10 < sup > 23 </ sup > m³ equals :</ div >

When we say that any two models of the above axioms are isomorphic, we mean that for any two models ( R, 0 < sub > R </ sub >, 1 < sub > R </ sub >, +< sub > R </ sub >, *< sub > R </ sub >, ≤< sub > R </ sub >) and ( S, 0 < sub > S </ sub >, 1 < sub > S </ sub >, +< sub > S </ sub >, *< sub > S </ sub >, ≤< sub > S </ sub >), there is a bijection f: R → S preserving both the field operations and the order.

*< sup > 1 </ sup >

*< sup > 1 </ sup >

*< sup > 1 </ sup >

*< font color =" green "></ font > 1888: Alifair McCoy, January 1 at Randolph's house by nine attackers led by Jim Vance.

*< font color =" green "></ font > 1888: Calvin McCoy, January 1 at Randolph's house by nine attackers led by Jim Vance.