Prospects of using unmanned aerial vehicles for detecting fossil mammoth ivory fields in the Arctic

 In recent decades, fossil ivory, the tusks of the Siberian mammoth of the late type (Mammuthus primigenius Blumenbach, 1799), has been in great demand on the world market of gemstone raw materials. Fossil ivory is a valuable highly liquid natural raw material of biogenic origin. With its decorative and technological characteristics, it is a fossil analogue of the tusks of the present-day African and Asian elephant (the populations of which are protected by UNESCO), used for the production of carved articles of great aesthetic value. Industrial clusters of mammoth tusks are concentrated in just a few Arctic regions of Russia: the only region today which holds confirmed industrial potential of fossil mammoth ivory (actually recoverable resources) is Northern Yakutia. This is due to the limited number of territories whose paleogeographic and landscape-ecological conditions were favorable for mammoths in the Late Pleistocene, as well as to the taphonomic conditions conducive to the long-term preservation of bone remains in permafrost conditions. Placer accumulations of mammoth tusks are formed as a result of denudation of cryogenic bone reservoirs containing up to 90% ice; the main destructive factors are various types of thermal erosion, which contributes to the formation of new accumulations. Today, just as centuries ago, the search for fossil ivory, is carried out mainly by walking over large areas in remote areas of the Russian Arctic. The search objects are fully or partially exposed fossil ivory lying on the surface (in the surface layer) of present-day sedimentary formations in various landscape-geomorphological and geobotanical settings. The current period of studying and exploiting the natural resources in Russia is characterized by the active use of unmanned aerial vehicles (UAVs) with video cameras, which significantly reduces the complexity of research in various fields of their application. We have carried out experimental and methodological work for the visual recognition of exposed mammoth tusks in the natural lansetting using a copter-type UAV equipped with video cameras and appropriate computer software. The interval of optimal heights is determined, as well as the possible width of the observation band during the search. The use of UAVs is expected to significantly increase the effectiveness of search through operational visual control of large areas of bone-bearing territories, fixation and coordinate binding of detected mammoth tusks for subsequent targeted and operational collection.

1. Аэрометоды изучения природных ресурсов. Под ред. Д.М. Кудрицкого и Г.Г. Самойловича. М.: Государственное издательство географической литературы; 1962. 340 с.

2. Кузнецова Н. Беспилотник эффективнее геологов. Инвест-Форсайт: Деловой журнал. 2018. https://www.if24.ru/tech/ (размещено 05.07.2018).

3. Смирнов А.Н. Ископаемая мамонтовая кость. СПб., ВНИИОкеангеология: Труды НИИГАВНИИОкеангеология; 2003. Т. 201. 172 с.

4. Smirnov A.N. Classification of the natural accumulation of fossil ivory. Lithosphere. 2005;4:151–164. (In Russ.)

5. Smirnov A.N. The fossil ivory resource potential in the Russian Arctic. Mineral Resources of Russia / Economics & Management. 2007;4:21–29. (In Russ.)

6. Boeskorov G.G., Kirillin N.D., Lazarev P.A., Testsov. V.V. Forecasting assessment of the mammoth tusk resources in the north of Yakutia. Problemy regionalnogo razvitya = Problems of regional development. 2008;2:106–109. (In Russ.)

7. Кириллин Н.Д. Ископаемая мамонтовая кость — особый геокриогенный природный ресурс севера России: проблемы права, экономики и организация рационального пользования. Якутск: Академия наук Республики Саха (Якутия), ООО «Компания «Дани АлмаС»; 2011. 192 с.

8. Кириллин Н.Д., Ноговицин Р.Р. Ископаемая мамонтовая кость — особый природный ресурс. Наука и техника в Якутии. 2010;1(18):19–23.

9. Томирдиаро С.В. Лессово-ледовая формация Восточной Сибири в позднем плейстоцене и голоцене. М.: Наука; 1980. 184 с.

10. Северная Якутия (физико-географическая характеристика). Под ред. Гаккеля Я.Я. и Короткевича Е.С. Л.: Изд-во «Морской транспорт», Труды ААНИИ. 1962. Т. 236. 280 с.

11. Вицентий А.В. Применение дистанционного зондирования Земли и космических технологий для развития арктических и субарктических территорий Российской Федерации. Труды Кольского НЦ РАН. 2013;5(18):40–45.

12. Smirnov A. N., Kalinovskiy K.K. Geological background to search underwater accumulations of mammoth ivory by sonar in the Russian Arctic. Arktika: ekologiya i ekonomika = Arctic: Ecology and economy. 2020;2:86–96. (In Russ.). https://doi.org/10.25283/2223-4594-2020-2-86-96

13. Нестерова Е.А., Николаева Н.Н., Горохов И.В. Поиск местонахождений остатков мамонтовой фауны в криолитозоне с использованием ГИС-технологий и геофизических методов. В кн.: Материалы XXI Всероссийской научно-практической конференции молодых ученых, аспирантов и студентов в г. Нерюнгри с мемеждународным участием, 27 февраля — 29 февраля 2020 г.: Технический институт (ф) СВФУ. Нерюнгри; 2020. С. 149–153. https://doi.org/10.18411/tifsvfu-2020-C1-196-43