{"version":"1.0","provider_name":"\u0421\u0430\u0439\u0442 \u0436\u0443\u0440\u043d\u0430\u043b\u0443 \u00ab\u0413\u0435\u043e\u0456\u043d\u0444\u043e\u0440\u043c\u0430\u0442\u0438\u043a\u0430\u00bb","provider_url":"http:\/\/www.geology.com.ua\/en","author_name":"\u0410\u0434\u043c\u0456\u043d\u0456\u0441\u0442\u0440\u0430\u0442\u043e\u0440","author_url":"http:\/\/www.geology.com.ua\/en\/blog\/author\/andriy\/","title":"Geoinformatika 2016; 2(58) : 5-23 - \u0421\u0430\u0439\u0442 \u0436\u0443\u0440\u043d\u0430\u043b\u0443 \u00ab\u0413\u0435\u043e\u0456\u043d\u0444\u043e\u0440\u043c\u0430\u0442\u0438\u043a\u0430\u00bb","type":"rich","width":600,"height":338,"html":"<blockquote class=\"wp-embedded-content\" data-secret=\"fi2JKYgjrA\"><a href=\"http:\/\/www.geology.com.ua\/en\/geoinformatika-2016-258-5-23\/\">Geoinformatika 2016; 2(58) : 5-23<\/a><\/blockquote><iframe sandbox=\"allow-scripts\" security=\"restricted\" src=\"http:\/\/www.geology.com.ua\/en\/geoinformatika-2016-258-5-23\/embed\/#?secret=fi2JKYgjrA\" width=\"600\" height=\"338\" title=\"&#8220;Geoinformatika 2016; 2(58) : 5-23&#8221; &#8212; \u0421\u0430\u0439\u0442 \u0436\u0443\u0440\u043d\u0430\u043b\u0443 \u00ab\u0413\u0435\u043e\u0456\u043d\u0444\u043e\u0440\u043c\u0430\u0442\u0438\u043a\u0430\u00bb\" data-secret=\"fi2JKYgjrA\" frameborder=\"0\" marginwidth=\"0\" marginheight=\"0\" scrolling=\"no\" class=\"wp-embedded-content\"><\/iframe><script type=\"text\/javascript\">\n\/* <![CDATA[ *\/\n\/*! This file is auto-generated *\/\n!function(d,l){\"use strict\";l.querySelector&&d.addEventListener&&\"undefined\"!=typeof URL&&(d.wp=d.wp||{},d.wp.receiveEmbedMessage||(d.wp.receiveEmbedMessage=function(e){var t=e.data;if((t||t.secret||t.message||t.value)&&!\/[^a-zA-Z0-9]\/.test(t.secret)){for(var s,r,n,a=l.querySelectorAll('iframe[data-secret=\"'+t.secret+'\"]'),o=l.querySelectorAll('blockquote[data-secret=\"'+t.secret+'\"]'),c=new RegExp(\"^https?:$\",\"i\"),i=0;i<o.length;i++)o[i].style.display=\"none\";for(i=0;i<a.length;i++)s=a[i],e.source===s.contentWindow&&(s.removeAttribute(\"style\"),\"height\"===t.message?(1e3<(r=parseInt(t.value,10))?r=1e3:~~r<200&&(r=200),s.height=r):\"link\"===t.message&&(r=new URL(s.getAttribute(\"src\")),n=new URL(t.value),c.test(n.protocol))&&n.host===r.host&&l.activeElement===s&&(d.top.location.href=t.value))}},d.addEventListener(\"message\",d.wp.receiveEmbedMessage,!1),l.addEventListener(\"DOMContentLoaded\",function(){for(var e,t,s=l.querySelectorAll(\"iframe.wp-embedded-content\"),r=0;r<s.length;r++)(t=(e=s[r]).getAttribute(\"data-secret\"))||(t=Math.random().toString(36).substring(2,12),e.src+=\"#?secret=\"+t,e.setAttribute(\"data-secret\",t)),e.contentWindow.postMessage({message:\"ready\",secret:t},\"*\")},!1)))}(window,document);\n\/\/# sourceURL=http:\/\/www.geology.com.ua\/wp-includes\/js\/wp-embed.min.js\n\/* ]]> *\/\n<\/script>\n","description":"Geoinformatika 2016; 2(58) : 5-23\u00a0(in Russian) MOBILE DIRECT-PROSPECTING TECHNOLOGY: FACTS OF CHANNELS DETECTION AND LOCALIZATION OF FLUIDS VERTICAL MIGRATION \u2013 ADDITIONAL EVIDENCE FOR DEEP HYDROCARBON SYNTHESIS S.P. Levashov1,2, N.A. Yakymchuk1,2, I.N. Korchagin3, D.N. Bozhezha2, V.V. Prylukov2 1Institute of Applied Problems of Ecology, Geophysics and Geochemistry, 1 Laboratorny Lane, Kyiv 01133, Ukraine 2Management and Marketing Center of the Institute of Geological Science, NAS ofUkraine, 1 Laboratorny Lane,\u00a0Kyiv 01133, Ukraine 3Institute of Geophysics, NAS of Ukraine, 32 Palladin Ave., Kyiv 03680, Ukraine, e-mail: korchagin@karbon.com.ua Purpose. The article has several objectives: to test advanced direct-prospecting method of frequency-resonance processing and decoding of RS data on the large Shebelinka GCF (Ukraine); to search for and localize vertical channels of deep fluids migration within the hydrocarbon fields and mapped anomalous zones of the \u201cdeposit of hydrocarbons\u201d type in various regions of the world: the Dnieper-Donets Basin, Western Siberia, the Gulf of Mexico, and the Mediterranean Sea; to develop a method to detect vertical channels of fluid migration; to improve the methodological principles of applying direct-prospecting geophysical methods and technologies during hydrocarbon accumulations prospecting in reservoirs of traditional and non-traditional types. Design\/methodology\/approach. In conducting the experimental research we used mobile technology of frequency-resonance processing of satellite images. It is based on the principles of the \u201cmatter\u201d paradigm of geophysical studies and permits to detect and map operatively the anomalous zones of the \u201cdeposit of hydrocarbons (oil, gas and gas condensate)\u201d type. A particular method of this technology allows us, within the contours of the detected anomalous zones at resonance frequencies of gas, to estimate the maximum value of the fluid pressure in the reservoirs at different intervals (including depth) of the cross-section. Findings. In the region of the Shebelinka GCF location, we have mapped an anomalous zone of 224,5 km2\u00a0area of the \u201cgas\u00a0+\u00a0condensate\u201d type with reservoir pressures in the range of 20,4\u201325,8 MPa. In the north-western and south-eastern parts of the field, we have found two vertical channels of fluid migration with the reservoir pressure of 280 and 272 MPa. Within the vertical channels, we have registered areas of anomalous responses at resonant frequencies of oil, gas, condensate, helium, hydrogen and carbon dioxide. Additionally,\u00a0 within a larger area (2220 km2), we have detected and mapped seven separate anomalous zones with total area of 259,9 km2. Relative to the observed area, all anomalous zones make up 21,82\u00a0%. A vertical channel with the pressure of 42,5 MPa was also found within the structure of \u201cvortex\u201d type in Western Siberia, and two additional channels (95,0 MPa and 110 MPa) within Machuhskoye gas field in the DDB. The vertical channel with a largest area was detected in the region of emergency well location in the Gulf of Mexico. The maximum value of the formation pressure within its contour was estimated at 165 MPa. Within two anomalous zones of the \u201cOil&amp;Gas\u201d type, found in the vicinity of the Zohr large gas field in the Mediterranean Sea, we have also mapped a vertical channel of depth fluids migration with the reservoir pressure of 141 MPa. The local sites in the areas of vertical channels location, identified within the contours of the anomalous zones, should be considered as the most promising for a detailed study by geophysical methods and location of prospecting wells. Practical significance and conclusions. The results of these studies indicate the presence within the hydrocarbons fields and mapped anomalous zones of the \u201cdeposit of hydrocarbons\u201d type of local areas with anomalously high formation pressure of fluids in the reservoirs of cross-section \u2013 the vertical channels of the deep fluids migration. Mobile and direct-prospecting methods allow us to identify and map operatively these channels using the results of anomalous responses registration on the resonant frequencies of helium, hydrogen, carbon dioxide. The tested methods of the vertical channels of fluid (HC) migration detecting and of reservoir pressures on different depths of cross-section evaluation can be widely used for the operative assessment of hydrocarbon potential of deep horizons of the cross-section. These facts of the vertical channels of fluid migration detection, as well as the presence of a significant number of anomalous zones of the \u201cOil and Gas deposit\u201d type at different levels (including depth) of the cross-section can be regarded as important evidence in favor of the abiotic origin of hydrocarbons. Keywords: vertical channel, oil, gas, well, satellite data, direct prospecting, mobile technology, anomaly of deposit type, collector, remote sensing data processing, interpretation, Shebelinka GCF, Gulf of Mexico, Mediterranean Sea. The full text of papers"}