LEADER 00800nam0-22002771i-450-
001 990001667920403321
005 20050516100553.0
035   $a000166792
035   $aFED01000166792
035   $a(Aleph)000166792FED01
035   $a000166792
100   $a20030910d1858----km-y0itay50------ba
101 0 $afre
200 1 $aGuide de la fabrication economique des engrais$fF. Rohart
210   $aParis$cLibrarie De Lacroix et Baudry$d1858
215   $a728 p.$d22 cm
610 0 $aFertilizzanti$aIndustria
676   $a668.62
700  1$aRohart,$bF.$072040
801  0$aIT$bUNINA$gRICA$2UNIMARC
901   $aBK
912   $a990001667920403321
952   $a60 DONO IERNA 147$b36284$fFAGBC
959   $aFAGBC
996   $aGuide de la fabrication economique des engrais$9370344
997   $aUNINA

LEADER 01670nam0-2200529---450-
001 990000047000203316
005 20090907120817.0
010   $a88-217-1236-2
035   $a0004700
035   $aUSA010004700
035   $a(ALEPH)000004700USA01
035   $a0004700
100   $a20000914d1999----|||y0itay0103----ba
101 0 $ait
102   $aIT
105   $a||||n---001yy
200 1 $aCodice del condominio$eNormativa, Giurisprudenza, Formule$fa cura di Giuseppe De Marzo
210   $a[Milanofiori, Assago]$cIPSOA$dcopyr. 1999
215   $aXIV, 914 p.$d19 cm
225 2 $aCollana Codici Annotati
410  0$a12001$aCollana Codici A---nnotati
610   $aCondominio Legislazione
676   $a346. 45043302638
700  1$aITALIA$0491077
702  1$aDE MARZO,$bGiuseppe$f<1964- >
801   $aIT$bSALBC$gISBD
912   $a990000047000203316
951   $aXXV.1.A 162 (CODEX 725)$b23843 G.$cXXV.1.A 162 (CODEX 725)$d00245137
959   $aBK
979   $c20000914$lUSA01$h1721
979   $c20000919$lUSA01$h1047
979   $c20000919$lUSA01$h1520
979   $c20001019$lUSA01$h1054
979   $c20001019$lUSA01$h1452
979   $c20001019$lUSA01$h1459
979   $c20001019$lUSA01$h1537
979   $c20001024$lUSA01$h1513
979   $c20001027$lUSA01$h1517
979   $c20001027$lUSA01$h1522
979   $c20001110$lUSA01$h1709
979   $c20001124$lUSA01$h1206
979   $c20020403$lUSA01$h1612
979   $aPATRY$b90$c20040406$lUSA01$h1605
979   $aPATRY$b90$c20061017$lUSA01$h1724
979   $aRSIAV4$b90$c20090907$lUSA01$h1208
996   $aCodice del condominio$91487071
997   $aUNISA

LEADER 06300nam  2200469   450 
001 9910555017103321
005 20220819010048.0
010   $a1-119-88167-6
010   $a1-119-88169-2
035   $a(MiAaPQ)EBC6817973
035   $a(Au-PeEL)EBL6817973
035   $a(CKB)19935015000041
035   $a(OCoLC)1287133927
035   $a(EXLCZ)9919935015000041
100   $a20220819d2021      uy             0
101 0 $aeng
135   $aurcnu||||||||
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 04$aThe solar system 2 $eexternal satellites, small bodies, cosmochemistry, dynamics, exobiology /$fThe?re?se Encrenaz, James Lequeux
205   $a2nd ed.
210  1$aLondon, England ;$aHoboken, New Jersey :$cISTE Limited :$cJohn Wiley & Sons, Incorporated,$d[2021]
210  4$d©2021
215   $a1 online resource (368 pages)
300   $aIncludes index.
311 08$aPrint version: Encrenaz, Thérèse The Solar System 2 Newark : John Wiley & Sons, Incorporated,c2022 9781789450347 
327   $aCover -- Half-Title Page -- Title Page -- Copyright Page -- Contents -- Preface -- 1. Satellites and Rings of the Giant Planets -- 1.1. Introduction -- 1.2. Jupiter's satellites -- 1.2.1. The Galilean satellites -- 1.2.2. The minor Jovian satellites -- 1.3. Saturn's satellites -- 1.3.1. Titan -- 1.3.2. Enceladus -- 1.3.3. The other icy satellites -- 1.3.4. Challenges for future missions in the Saturn system and Dragonfly -- 1.4. The satellites of Uranus and Neptune -- 1.4.1. The satellites of Uranus -- 1.4.2. The satellites of Neptune -- 1.4.3. Future exploration of the icy giant planets' systems -- 1.5. The rings -- 1.5.1. Tidal forces and the Roche limit -- 1.5.2. Flattening and ring dispersion -- 1.5.3. Jupiter's rings -- 1.5.4. Saturn's rings -- 1.5.5. Uranus's rings -- 1.5.6. Neptune's rings -- 1.5.7. The rings of small bodies -- 1.5.8. Ring dynamics -- 1.5.9. The origin of the rings -- 1.5.10. An exo-ring -- 1.6. References -- 2. Comets, Asteroids, and Dwarf Planets -- 2.1. Comets -- 2.1.1. Definition and nomenclature -- 2.1.2. The orbits and families of the comets -- 2.1.3. Cometary magnitude -- 2.1.4. Space exploration of the comets -- 2.1.5. The nucleus -- 2.1.6. The atmosphere -- 2.1.7. Dust and the tail -- 2.1.8. The chemical diversity of the comets: a relationship to their origins? -- 2.1.9. The interaction of comets with solar wind -- 2.2. The "historical" asteroids -- 2.2.1. The asteroids in the main belt -- 2.2.2. The asteroids that cross the orbit of the terrestrial planets -- 2.2.3. The Trojan asteroids -- 2.2.4. The properties of asteroids -- 2.3. The "new" asteroids -- 2.3.1. The Centaurs -- 2.3.2. Trans-Neptunian objects -- 2.3.3. Interstellar objects -- 2.3.4. The origin and evolution of the asteroids -- 2.4. The dwarf planets -- 2.4.1. Ceres -- 2.4.2. Pluto and its satellites -- 2.4.3. Eris, Haumea, and Makemake.
327   $a2.5. References -- 3. Meteorites and Cosmochemistry -- 3.1. Rocks falling from the sky -- 3.2. Origin of meteorites -- 3.3. Planetary differentiation and groups of meteorites -- 3.4. Chondrites and the origin of the Solar System -- 3.4.1. The chemical composition of chondrites -- 3.4.2. The mineralogy of chondrites -- 3.4.3. The isotopic characteristics of bulk meteorites -- 3.5. Differentiated meteorites -- 3.5.1. Fragments of the asteroid Vesta -- 3.5.2. Iron meteorites -- 3.5.3. Pallasites -- 3.5.4. Fragments of the planet Mars -- 3.6. Witnesses to the formation and evolution of the Solar System -- 3.7. References -- 4. Formation and Dynamic History of the Solar System¹ -- 4.1. Introduction -- 4.2. Laws of motion of the planets and satellites -- 4.2.1. Kepler's laws -- 4.2.2. Gravity -- 4.2.3. Newton's fundamental laws of dynamics -- 4.2.4. The orbital elements -- 4.3. The two-body problem -- 4.4. The three-body problem -- 4.4.1. Jacobi constant and Lagrange points -- 4.4.2. Tadpole and horseshoe orbits -- 4.4.3. Hill sphere -- 4.5. Perturbations and resonances -- 4.6. Stability and chaos in the Solar System -- 4.7. Orbits in relation to a flattened body -- 4.8. Tidal effect -- 4.8.1. Tidal deformation -- 4.8.2. Tidal torque -- 4.8.3. Roche limit -- 4.9. Nongravitational forces and orbits of small bodies -- 4.9.1. Radiation pressure (micrometer-sized grains) -- 4.9.2. Poynting-Robertson effect (small macroscopic particles) -- 4.9.3. The Yarkovsky Effect (meter to kilometer-sized particles) -- 4.9.4. Yorp torque (asymmetric bodies) -- 4.9.5. Friction from solar particles (submicrometer dust) -- 4.9.6. Friction in gas -- 4.10. Formation of planetary systems -- 4.10.1. A disk of planetoids -- 4.10.2. Formation of terrestrial planets -- 4.10.3. Formation of Jupiter -- 4.10.4. Formation of giant planets by core accretion.
327   $a4.10.5. Formation by disk instability -- 4.10.6. Disappearance of the gas -- 4.10.7. Catastrophic collisions -- 4.10.8. Small bodies -- 4.10.9. Planetary migration -- 4.10.10. Fate of the small bodies -- 4.10.11. Exoplanetary formation -- 4.11. References -- 5. Origin of Life and Extraterrestrial Life -- 5.1. Definition of life -- 5.2. The appearance of life on Earth -- 5.2.1. Physicochemical conditions -- 5.2.2. The first forms of life -- 5.2.3. The formation of living cells -- 5.3. Life elsewhere in the Solar System -- 5.3.1. Mars -- 5.3.2. Venus -- 5.3.3. Satellites of the giant planets -- 5.4. How can life be detected on exoplanets? -- 5.5. Communicating with other civilizations? -- 5.6. References -- 6 Methods for Studying the Solar System -- 6.1. History -- 6.2. Observational techniques -- 6.2.1. Remote sensing -- 6.2.2. Methods of space exploration -- 6.2.3. Virtual Observatory and databases -- 6.2.4. Perspectives of ground-based and space observations -- 6.3. Computer simulations -- 6.3.1. Dynamics -- 6.3.2. Global climate models -- 6.4. References -- Appendix Web links -- Glossary -- List of Authors -- Index -- EULA.
607   $aSolar system$xAge
608   $aElectronic books.
676   $a523.2
702   $aLequeux$b James
702   $aEncrenaz$b The?re?se
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910555017103321
996   $aThe solar system 2$92905765
997   $aUNINA