彗星塵
物理性質
編輯大小
編輯彗星活動產生的塵埃大部分為次微米級[1]至微米的大小[2][3]。然而,這一部分是短暫的,會因為輻射壓導致它們被吹出太陽系[4][5],或因為坡印廷–羅伯遜效應而螺旋向內[6][7]。
下一個尺寸等級是"蓬鬆的"("fluffly")[4][5]或"羣集類型"("cluster-type")[8],是前述顆粒的聚合物。它們的大小通常為20-100微米,但可以觀察到尺寸不是任意的[9],這是由於多孔的聚合物容易斷裂 [10] or compact.[8][11][12]。
更大的粒子是微流星體[13][14],不再是塵埃了[15][16]。在國際天文學聯合會(IAU)沒有定義的情況下[17][18],各小組設計了自己的粉塵定義:小於100微米[19]、50[20]、40[21] 30,[22]、和20微米[23] 還有<10微米[24][25][26][16]。其中一些塵埃/微流星體的定義是近似的或模稜兩可的[27][28][29],有些還重疊或自相矛盾(衝突)[30][23][22]。
IAU於2017年發佈了一份正式聲明。流星體為30微米至1米,塵埃較小,且不鼓勵使用"微流星體"一詞(儘管不是微流星體)[31]。國際流星組織 (IMO)雖然注意到了新的定義[32],但仍在其網站上顯示先前的定義[33],即0.001cm[34]。美國流星學會(AMS)也沒有給出嚴格的定義[35][36]。
成分
編輯粉塵的成分通常為球粒隕石。其單體含有鎂鐵質矽酸鹽,如橄欖石和輝石[37]。矽酸鹽富含高冷凝溫度的鎂橄欖石和頑火輝石[27]。當這些顆粒迅速凝結時,它們往往會形成非常小的顆粒,而不是合併成液滴。
與球粒隕石一樣,顆粒含有 Fe(Ni)硫化物[38][39]和嵌入金屬和硫化物的玻璃(glass with embedded metal and sulfides,GEMS)[38]。
存在不同數量的有機物(CHON)[40][41][42]。雖然有機物在宇宙中非常豐富,並且被廣泛預測存在於彗星中,但在大多數望遠鏡中,它們的光譜都是模糊的。僅在哈雷飛越期間通過質譜法確認有機物的存在[43][44]。一些有機物多以多環芳香烴(PAHs)的形式存在[45][19][46][47][48]。
塵埃和彗星的起源
編輯彗星起源的模型有[49]:
彗星塵埃的密度、化學成分、體積等特性,可以區分這些模型。例如,彗星和星際塵埃的同位素比率非常相似,表明有一個共同的起源。
在(1)星際模型說冰是在太陽之前的緻密雲中的塵埃顆粒上形成的。冰和塵埃的混合物在沒有明顯化學修飾的情況下聚集成彗星。J、梅奧·格林伯格在20世紀70年代率先提出這個想法[50][51]。
在(2)根據太陽系模型,星際雲中形成的冰是原太陽周圍氣體和塵埃吸積盤中首先蒸發的一部分。蒸發的冰後來再溶解並組裝成彗星。因此,這個模型中的彗星與那些直接由星際冰形成的彗星的成分不同。
在(3)彗星形成的原始碎石堆模型說,彗星是在木星形成的區域凝聚形成的。
星塵號在維爾特二號彗星(81P/Wild)的塵埃中發現了結晶矽酸鹽,這意味著塵埃形成於超過玻璃轉化溫度(>1000K)以上的區域,是在環繞著年輕恆星盤面的內側高溫地區,然後混合著太陽星雲從恆星內側向外輻射很遠的距離,或是在發展中的紅巨星或超巨星內凝結的塵埃粒子向外流動。星或超巨星流出的塵埃粒子,在太陽星雲中徑向混合。維爾特二號彗星塵埃的成分與新形成恆星周圍吸積盤外部區域的塵埃成分相似[52]。
彗星和它的塵埃使我們能夠研究太陽系主要行星軌道之外的區域。彗星的區別在於它們的軌道:週期超過200年的長週期彗星,有長的橢圓軌道,隨機傾斜於太陽系平面。週期小於200年的短週期彗星通常與太陽系平面的傾角小於30度,以與行星軌道相同的逆時針方向圍繞太陽旋轉。
彗星在其軌道上運行時時會經歷一系列不同的情況。對於長週期彗星來說,大多數時間它離太陽太遠,太冷了,冰不會蒸發。當它通過類地行星區域時,蒸發速度會很快,足以吹走小顆粒,但最大的顆粒可能會抵制夾帶,留在彗核上,開始形成塵埃層。在太陽附近,加熱和蒸發的速度將非常快,以至於沒有塵埃可以保留下來。因此,覆蓋彗核的塵埃層厚度可以表明彗星接近太陽的頻率與近日點的距離。如果彗星有厚厚的塵埃層堆積,它可能曾頻繁的通過近日點,但不會過度的靠近太陽。
塵埃層的厚堆積對所有短週期彗星可能是一個很好的描述,因為人們認為在短週期彗星核的表面上堆積的塵埃層厚度在米量級。隨著時間的推移,塵埃層的積累將改變這顆短週期彗星的物理特性。塵埃層既抑制了太陽對彗星冰的加熱(陽光無法穿透塵埃層,並且導熱不良),又減緩了下方彗核的氣體損失。處於短週期彗星典型軌道上的彗核會迅速降低其蒸發率,以至於無法檢測到彗髮或彗尾,天文學家可能會將其視為低反照率的近地小行星。
進一步組合和主體
編輯參考資料
編輯- ^ Mukai, T.; Mukai, S.; Kikouchi, S. Variation of Grain Properties and the Dust Outbursts. Symposium on the Diversity and Similarity of Comets, ESA SP-278. European Space Agency. 1987: 427–30.
- ^ Grun, E.; Massonne; Schwehm, G. New Properties of Cometary Dust. Symposium on the Diversity and Similarity of Comets, ESA SP-278. European Space Agency. 1987: 305–14.
- ^ Fernandez, J. Comets: Nature, Dynamics, Origins, and their Cosmogonical Relevance. Springer. 2005: 66.
- ^ 4.0 4.1 Southworth, R. Distribution of the Zodiacal Particles. Annals of the New York Academy of Sciences. 11 Nov 1964, 119: 54. S2CID 85917931. doi:10.1111/j.1749-6632.1965.tb47423.x.
- ^ 5.0 5.1 Fechtig, H. Cometary Dust In The Solar System. Comets. Tucson: University of Arizona Press. 1982: 370.
- ^ Whipple, Fred. The Mystery of Comets. Cambridge University Press. 1986: 143. ISBN 9780521324403.
- ^ Dermott, S. Ch. Orbital evolution of interplanetary dust. Grün E; Gustafson B; Dermott S; Fechtig H (編). Interplanetary Dust. SpringerVerlag. 2001: 569–39.
- ^ 8.0 8.1 Zolensky, M.; Lindstrom, D. Mineralogy of 12 large 'chondritic' interplanetary dust particles. 1991 LPSC: 161–69. Mar 1991.
- ^ Ney, E. Optical and Infrared Observations of Bright Comets in the Range 0.5 um to 20 um. Comets. Tucson: University of Arizona Press. 1982: 323.
- ^ Simpson, J.; Rabinowitz, D.; Tuzzolino, A.; Ksanfomality, L. Halley's comet dust particle mass spectra, flux distributions and jet structures derived from measurements on the Vega-1 and Vega-2 spacecraft. ESA Proceedings of the 20th ESLAB Symposium on the Exploration of Halley's Comet. Volume 2: Dust and Nucleus. European Space Agency. 1986: 11–16.
- ^ Leinert, C; Roser, S; Buitrago, J. How to maintain the spatial distribution of interplanetary dust. Astronomy & Astrophysics. 1983, 118 (2): 345–57. Bibcode:1983A&A...118..345L.
- ^ Mukai, T; fechtig, H. Packing efficient of fluffy particles. Planetary and Space Science. June 1983, 31 (6): 655–58. doi:10.1016/0032-0633(83)90006-5.
- ^ Reach, W.; Sykes, M.; Kelley, M. Large Particles From Short-Period Comets. Workshop on Cometary Dust in Astrophysics. Houston: Lunar and Planetary Institute. 2003.
- ^ Kelley, M.; Reach, W.; Woodward, C. A Search for Deep Impact’s Large Particle Ejecta. Deep Impact as a World Observatory Event: Synergies in Space, Time, and Wavelength. Berlin Heidelberg: Springer-Verlag. 2009: 125. ISBN 978-3-540-76959-0.
- ^ Beech, M; Steel, D. On the definition of the term 'meteoroid'. Q. J. R. Astron. Soc. 1995, 36: 281–84. Bibcode:1995QJRAS..36..281B. Sec. 4 Lower size limit: Meteoroid or dust?
- ^ 16.0 16.1 Rubin, A; Grossman, J. Meteorite and meteoroid: New comprehensive definitions. Meteoritics & Planetary Science. Mar 2010, 45 (1): 114–22. Bibcode:2010M&PS...45..114R. doi:10.1111/j.1945-5100.2009.01009.x. "...in practice the term is most often applied to objects smaller than approximately 100 um. These size ranges need to be modified." "By this definition, IDPs are particles smaller than 10um.""
- ^ Millman, P. A Report on Meteor Terminology. J. R. Astron. Soc. Canada. 1961, 55 (6): 265. "particle sizes in general smaller than micrometeorites"
- ^ Resolutions Adopted A. By The General Assembly (PDF). [30 Jun 2020]. (原始內容 (PDF)存檔於2022-05-08). Sec. "Commission 22 (Meteors and Meteorites/Météores et des Meteorites)"
- ^ 19.0 19.1 Greenberg, M; Li, A. Morphological structural and chemical composition of cometary nuclei and dust. Space Science Reviews. 1997, 90: 149–61. S2CID 189789755. doi:10.1023/A:1005298014670. "tenth micron particles" "very fluffy aggregates"
- ^ Klöck, W; Staderman, F. Mineralogical and chemical relationships of interplanetary dust particles, micrometeorites, and meteorites in. LPI Technical Report 94-02 Workshop on the analysis of interplanetary dust particles. 1994. "50 um"
- ^ Levasseur-regourd, A; mukai; lasue; okada. physical properties of comet and interplanetary dust. Planetary and Space Science. 2007, 55 (9): 1010–20. Bibcode:2007P&SS...55.1010L. doi:10.1016/j.pss.2006.11.014. "a radius of 20 um for the upper cut-off"
- ^ 22.0 22.1 Grun, E; Krüger, H; Srama, R. The Dawn of Dust Astronomy. Space Science Reviews. 2019, 215 (7): number 46. Bibcode:2019SSRv..215...46G. S2CID 208527737. arXiv:1912.00707 . doi:10.1007/s11214-019-0610-1. S.3 Multifaceted Scientific Dust Observations "<~ 30 micrometer"
- ^ 23.0 23.1 Levasseur-Regourd, A; Mukai, T; Lasue, J; Okada, Y. Physical properties of comet and interplanetary dust. Planetary and Space Science. Jun 2007, 55 (9): 1010–20. Bibcode:2007P&SS...55.1010L. doi:10.1016/j.pss.2006.11.014. "20 um for the upper cut-off" "50 um for the upper cut-off"
- ^ Bradley, J; Sandford, S; Walker, R. 11.1 Interplanetary Dust Particles. Meteorites and the Early Solar System. University of Arizona Press. 1988: 861. "~ 10 um i diamtr" "~ 10-3 cm in dia"
- ^ Love, S; Brownlee, D. Heating and thermal transformation of micrometeoroids entering the Earth's atmosphere. Icarus. Jan 1991, 89 (1): 26–43. Bibcode:1991Icar...89...26L. doi:10.1016/0019-1035(91)90085-8. "10 um"
- ^ Coulson, D; Wickramasinghe, N. Frictional and radiation heating of micron-sized meteoroids in the Earth's upper atmosphere. Mon. Not. R. Astron. Soc. 21 Aug 2003, 343 (4): 1123–30. Bibcode:2003MNRAS.343.1123C. doi:10.1046/j.1365-8711.2003.06478.x . "~10 um"
- ^ 27.0 27.1 27.2 Brownlee, D; Tsou, P; Aléon, J; et al. 81P/Wild 2 Under a Microscope. Science. 2006, 314 (5806): 1711–6 [2022-06-05]. PMID 17170289. S2CID 141128. doi:10.1126/science.1135840. hdl:1885/33730 . (原始內容存檔於2022-06-05).
- ^ Rehder, D. 5.3.3 Intrplntr Ds Ptcls (Prsl Grs). Chemistry in Space. Wiley-VCH. 2010. ISBN 978-3-527-32689-1. "<100um; typically 0.1-20um"
- ^ Folco, L; Cordier, C. 9. Micrometeorites. EMU Notes in Mineralogy. 2015. "10 um (Rubin and Grossman, 2010)""in the <100 um size fraction, i.e. across the transition between micrometeorites and IDPs"
- ^ Rietmeijer, F. Mesospheric Metal abundances and Meteoric Dust: Analysis of surviving Meteoroids. 34th COSPAR Scientific Assembly/2nd World Space Congress (196). Oct 2002. "stratospheric interplanetary dust particles (IDPs) (2-100 microns)" "debris from progenitors ~30 to ~1,000 microns"
- ^ Definitions of terms in meteor astronomy (PDF). [2022-06-05]. (原始內容 (PDF)存檔於2021-12-22).
- ^ Perlerin, V. Definitions of terms in meteor astronomy (IAU). [30 Jun 2020]. (原始內容存檔於2022-06-11).
- ^ Glossary. [30 Jun 2020]. (原始內容存檔於2016-10-21).
- ^ Benoit, P. Dust. [30 Jun 2020]. (原始內容存檔於2020-06-17). "0.001 cm in diameter"
- ^ METEOR FAQS. [30 Jun 2020]. (原始內容存檔於2022-05-12).
- ^ Glossary. [30 Jun 2020].
- ^ Bradley, J; Brownlee, D; Veblen, D. Pyroxene whiskers and platelets in interplanetary dust: evidence of vapor phase growth. Nature. 1983, 301 (5900): 473. Bibcode:1983Natur.301..473B. S2CID 4303275. doi:10.1038/301473a0.
- ^ 38.0 38.1 Zolensky, M; Zega, T; Yano, H; Wirick, S; Westphal, A; Weisberg, M; et al. Mineralogy and Petrology of Comet 81P/Wild 2 Nucleus Samples. Science. 15 Dec 2006, 314 (5806): 1735–9. Bibcode:2006Sci...314.1735Z. PMID 17170295. S2CID 25539280. doi:10.1126/science.1135842. hdl:1885/37338 .
- ^ Zolensky, M; Thomas, K. Iron and iron-nickel sulfides in chondritic interplanetary dust particles. Geochimica et Cosmochimica Acta. Nov 1995, 59 (22): 4707. Bibcode:1995GeCoA..59.4707Z. doi:10.1016/0016-7037(95)00329-0.
- ^ Kissel, J; Sagdeev, R; Bertaux, J; et al. Composition of comet Halley dust particles from Vega observations. Nature. 1986, 321: 280. Bibcode:1986Natur.321..280K. S2CID 122405233. doi:10.1038/321280a0.
- ^ Kissel, J; Brownlee, D; Büchler, K; et al. Composition of comet Halley dust particles from Giotto observations. Nature. 1986, 321: 336. Bibcode:1986Natur.321..336K. S2CID 186245081. doi:10.1038/321336a0.
- ^ Kissel, J; Kruger, F. The organic component in dust from comet Halley as measured by the PUMA mass spectrometer on board Vega 1. Nature. 1987, 326 (6115): 755–60. Bibcode:1987Natur.326..755K. S2CID 4358568. doi:10.1038/326755a0.
- ^ Lawler, M; Brownlee, D. CHON as a component of dust from comet Halley. Nature. 1992, 359 (6398): 810–12. Bibcode:1992Natur.359..810L. S2CID 4314100. doi:10.1038/359810a0.
- ^ Levasseur-Regourd, A; Agarwal, A; Cottin, H; Engrand, C; Flynn, G; Fulle, M; Gombosi, T; et al. Cometary Dust. Space Science Reviews. 2018, 214 (3): number 64. Bibcode:2018SSRv..214...64L. S2CID 189791473. doi:10.1007/s11214-018-0496-3.
- ^ Clemett, S; Maechling, C; Zare, R; Swan, P; Walker, R. Identification of complex aromatic molecules in individual interplanetary dust particles. Science. 1993, 262 (5134): 721–5. Bibcode:1993Sci...262..721C. PMID 17812337. S2CID 24398934. doi:10.1126/science.262.5134.721.
- ^ Lisse, C; et al. Spitzer spectral observations of the deep impact ejecta (PDF). Science. 2006, 313 (5787): 635–40 [2022-06-05]. Bibcode:2006Sci...313..635L. PMID 16840662. S2CID 3024593. doi:10.1126/science.1124694. (原始內容 (PDF)存檔於2022-06-05).
- ^ Sandford, S; et al. Organics captured from comet 81P/Wild 2 by the Stardust spacecraft. Science. 2006, 314 (5806): 1720–4. Bibcode:2006Sci...314.1720S. PMID 17170291. S2CID 2727481. doi:10.1126/science.1135841.
- ^ 48.0 48.1 Keller, L; Bajt, S; Baratta, G; Borg, J; Bradley, J; Brownlee, D; et al. IR Spectroscopy of Comet 81P/Wild 2 Samples Returned by Stardust. Science. 15 Dec 2006, 314 (5806): 1728–31. PMID 17170293. S2CID 35413527. doi:10.1126/science.1135796.
- ^ Science News 149, June 1, 1996, pp. 346–347.
- ^ Greenberg, J. From dust to comets. Comets, asteroids, meteorites: Interrelations, evolution and origins, Proceedings of the Thirty-Ninth International Colloquium. University of Toledo. 1977: 491.
- ^ Greenberg, J. What Are Comets Made Of? a Model Based on Interstellar Dust. Comets. Tucson: University of Arizona Press. 1982: 131. ISBN 0816507694.
- ^ Millan-Gabet, Rafael; Malbet, Fabien; Akeson, Rachel; Leinert, Christoph; Monnier, John; Waters, Rens. The Circumstellar Environments of Young Stars at AU Scales. Protostars and Planets V. 2006: 539. Bibcode:2007prpl.conf..539M. arXiv:astro-ph/0603554 .