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496
Barthel K. W., Swinburne N. H. M. and Morris S. C. Solnhofen: A Study of Mesozoic Palaeontology. Cambridge, Cambridge University Press, 1990. P. 197.
497
Van Valen and Sloan, 1966. P. 261.
498
Ogg, Ogg, and Gradstein, 2016. P. 167.
499
Hickey L. J. and Doyle J. A. Early Cretaceous fossil evidence for angiosperm evolution // Botanical Review. 1977. V. 43. № 1. P. 3–4.
500
Xing Xu, Zhonghe Zhou and Xiaolin Wang. The smallest known non-avian theropod dinosaur // Nature. 2000. V. 408. № 7. P. 705–708.
501
Lawson D. A. Pterosaur from the latest Cretaceous of West Texas: Discovery of the largest flying creature // Science. 1975. V. 187. № 4180. P. 947.
502
Frey E. and Martill D. M. A reappraisal of Arambourgiania (Pterosauria, Pterodactyloidea): One of the world’s largest flying animals // Neues Jahrbuch für Geologie und Paläontologie– Abhandlungen. 1996. P. 221–247.
503
Harrell T. L. Jr., Gibson M. A. and Langston W. Jr. A cervical vertebra of Arambourgiania philadelphiae (Pterosauria, Azhdarchidae) from the late Campanian micaceous facies of the Coon Creek Formation in McNairy County, Tennessee, USA // Bulletin of the Alabama Museum of Natural History. 2016. V. 33. № 2. P. 94–103.
504
Krause D. W. et al. Skeleton of a Cretaceous mammal from Madagascar reflects long-term insularity // Nature. 2020. V. 581. P. 1–7.
505
Sloan R. E. and Van Valen L. Cretaceous mammals from Montana // Science. 1965. V. 148. № 3667. P. 220–227.
506
Alvarez L. W., Alvarez W., Asaro F. and Michel H. V. Extraterrestrial cause of the Cretaceous—Tertiary extinction // Science. 1980. V. 208. № 4448. P. 1095–1108.
507
Hildebrand A. R., Penfield G. T., Kring D. A., Pilkingotn M., Camargo Z. A., Jacobsen S. B. and Boynton W. V. Chicxulub Crater: A possible Cretaceous/Tertiary impact crater in the Yucatán Peninsula, Mexico // Geology. 1991. V. 19. P. 867–871.
508
Sanford J. C., Snedden J. W. and Gulich S. P. S. The Cretaceous—Paleogene boundary deposit in the Gulf of Mexico: Large scale oceanic basin response to the Chicxulub impact // Journal of Geophysical Research, Solid Earth. 2016. V. 121. № 3. P. 1240–1261.
509
Ibid. P. 1257.
510
Morgan J. V. et al. The formation of peak rings in large impact craters // Science. 2016. V. 354. № 6314. P. 878–882.
511
Artemieva N., Morgan J. and the Expedition 364 Science Party. Quantifying the release of climate-active gases by large meteorite impacts with a case study of Chicxulub // Geophysical Research Letters. 2017. V. 44. № 20. P. 10, 180.
512
Kunio K. and Oshima N. Site of asteroid impact changed the history of life on Earth: The low probability of mass extinction // Scientific Reports. 2017. V. 7. № 1. P. 14855.
513
Jolley D., Gilmour I., Gurov E., Kelley S. and Watson J. Two large meteorite impacts at the Cretaceous—Paleogene Boundary // Geology. 2010. V. 38. № 9. P. 835–838.
514
Keller G., Adatte T., Pardo J. A. and Lopez-Oliva J. G. New evidence concerning the age and biotic effects of the Chicxulub impact in NE Mexico // Journal of the Geological Society of London. 2009. V. 166. № 3. P. 393–411.
515
Schoene B., Eddy M. P., Samperton K. M., Keller C. B., Keller G., Adatte T. and Khadri S. F. U-Pb geochronology of the Deccan Traps and relation to the end-Cretaceous mass extinction // Science. 2014. V. 363. № 6429. P. 862–866.
516
Schulte P. et al. The Chicxulub asteroid impact and mass extinction at the Cretaceous—Paleogene boundary // Science. 2010. V. 327. № 5970. P. 1214–1218.
517
Cohen K. M., Finney S. C., Gibbard P. L. and Fan J. X. The ICS international chronostratigraphic chart // Episodes. 2013 (updated 2020). V. 36. P. 199–204.
518
U. S. Geological Survey Geologic Names Committee. Divisions of geologic time – major chronostratigraphic and geochronologic units. U. S. Geological Survey Fact Sheet, 2018. № 2018–3054. 2 p.
519
Walker J. D., Geissman J. W., Bowring S. A. and Babcock L. E. The Geological Society of America geologic time scale // GSA Bulletin. 2013. V. 125. № 3–4. Р. 259–272.
520
U. S. Geological Survey Geologic Names Committee, 2018.
521
Fuentes A. J., Clyde W. C., Weissenburger K., Bercovici A., Lyson T. R., Miller I. M., Ramezani J., Isakson V., Schmitz M. D. and Johnson K. R. Constructing a time scale of biotic recovery across the Cretaceous—Paleogene boundary, Corral Bluffs, Denver Basin, Colorado, USA // Rocky Mountain Geology. 2019. V. 54. № 2. P. 133–153.
522
Gazin C. L. Paleocene mammals from the Denver Basin, Colorado // Journal of the Washington Academy of Sciences. 1941. V. 31. № 7. P. 289–295.
523
Grand Junction Daily Sentinel. Moment of extinction: How a Grand Junction geologist got a closer look at the K-T boundary. 2019. November 18. https://www.gjsentinel.com/news/western_colorado/moment-of-extinction-how-a-grandjunction-geologist-got-a/article_c5620344-09c3-11ea-bf09-20677ce07cb4.html.
524
Fuentes, Clyde, Weissenburger, Bercovici, Lyson, Miller, Ramezani, Isakson, Schmitz, and Johnson, 2019.
525
Denver Museum of Nature and Science, 2019. The mammals. https://coloradosprings. dmns. org/the-mammals/.
526
Harlan R. Notice of fossil bones found in the Tertiary in the State of Louisiana // Transactions of the American Philosophical Society, 1834. V. 4. P. 397–403.
527
Gingerich P. D., Arif M., Bhatti M. A., Anwar M. and Sanders W. J. Basilosaurus drazindai and Basiloterus hussaini, new Archaeoceti (Mammalia, Cetacea) from the middle Eocene Drazinda Formation, with a revised interpretation of ages of whale-bearing strata in the Kirthar Group of the Sulaiman Range,