Crude Oil rose to 65.49 USD/Bbl on July 23, 2025, up 0.27% from the previous day. Over the past month, Crude Oil's price has risen 1.73%, but it is still 15.60% lower than a year ago, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. Crude Oil - values, historical data, forecasts and news - updated on July of 2025.

Comprehensive dataset of 71 Oil stores in Sverdlovsk Oblast, Russia as of July, 2025. Includes verified contact information (email, phone), geocoded addresses, customer ratings, reviews, business categories, and operational details. Perfect for market research, lead generation, competitive analysis, and business intelligence. Download a complimentary sample to evaluate data quality and completeness.

The USGS Central Region Energy Team assesses oil and gas resources of the United States. The onshore and State water areas of the United States comprise 71 provinces. Within these provinces, Total Petroleum Systems are defined and Assessment Units are defined and assessed. Each of these provinces is defined geologically, and most province boundaries are defined by major geologic changes.
The Appalachian Basin Province is located in the eastern United States, encompassing all or parts of the counties in Alabama, Georgia, Kentucky, Maryland, New Jersey, New York, North Carolina, Ohio, Pennsylvania, Tennessee, Virginia, and West Virginia. The main population centers within the study area are Birmingham, Alabama; Buffalo, New York; Cleveland, Ohio; Pittsburgh, Pennsylvania; Chattanooga, Tennessee; and Roanoke, Virginia. The main Interstates are I-20, I-24, I-40, I-59, I-64, I-65, I-66, I-70, I-71, I-75, I-76, I-77, I-78, I-79, I-80, I-81, I-83, I-84, I-87, I-88, and I-90. The Ohi ...

Iceland Imports from Germany of Crude Oil was US$71 during 2023, according to the United Nations COMTRADE database on international trade. Iceland Imports from Germany of Crude Oil - data, historical chart and statistics - was last updated on June of 2025.

The USGS Central Region Energy Team assesses oil and gas resources of the United States. The onshore and State water areas of the United States comprise 71 provinces. Within these provinces, Total Petroleum Systems are defined and Assessment Units are defined and assessed. Each of these provinces is defined geologically, and most province boundaries are defined by major geologic changes. The Michigan Basin Province is located in all of Michigan, except for a small portion of the Upper Penninsula, eastern Wisconsin, northeastern Illinois, northern Indiana, and northwestern Ohio. The main population centers within the study area are Detroit, Grand Rapids, Lansing and Flint, Michigan; Milwakee, Wisconsin; Chicago, Illinois; Fort Wayne, Indiana; and Toledo, Ohio. Numerous Interstate highways traverse the province from north to south and east to west. The province boundary was drawn to include the geologic structures generally considered to be in or bounding the Michigan Basin.

This report describes the first five tests in a series of tests simulating zones of contrasting permeability in in-situ retorts. The objective of this series of tests is to determine the yield loss from retorting of oil shale beds with zones of contrasting flow resistance. The contrasting flow resistance is simulated by loading a cylindrical core with oil shale particles of one size range, while filling the annular space around the core with a different size range of oil shale particles. Tracer and temperature data are used to measure the flow characteristics and thermal front shapes within the bed. Examples of data summaries and preliminary evaluations are described to show some of the techniques used to develop possible relationships between oil yield and permeability contrast. A correlation between permeability ratio and oil yield shows promise as a blast design and yield prediction tool. Indications that oil yield loss from cracking and combustion may be related to permeability contrast needs confirmation. Shapes of retorting fronts were used for qualitative assessment of oil yield. 13 refs., 7 figs., 6 tabs.

Unsaturated Vegetable Oil Market Outlook

The global unsaturated vegetable oil market size is projected to witness substantial growth over the forecast period from 2024 to 2032, with an estimated CAGR of 5.8%. In 2023, the market size was valued at approximately USD 45 billion and is anticipated to reach around USD 71 billion by 2032. This growth is primarily driven by the increasing consumer preference for health-conscious dietary choices and the rising application of unsaturated oils in various sectors such as food and beverages, cosmetics, and pharmaceuticals.

A significant growth factor in the unsaturated vegetable oil market is the growing awareness of the health benefits associated with their consumption. Unsaturated oils, particularly those high in monounsaturated and polyunsaturated fats, have been linked with numerous health advantages, including improved cardiovascular health and reduced cholesterol levels. As consumers become increasingly health-conscious, there is a surging demand for healthier cooking oils and dietary fats, propelling the market's expansion. Furthermore, the trend towards organic and non-GMO products has fueled the demand for naturally sourced oils, leading to a proliferation of premium unsaturated oil products on the market.

The expansion of the food and beverage industry has further bolstered the growth of the unsaturated vegetable oil market. As global populations grow and urbanize, there is a heightened need for processed and packaged food products, many of which utilize unsaturated oils as key ingredients. Additionally, the versatility of unsaturated oils in culinary applications, ranging from salad dressings to baking, enhances their appeal among food manufacturers and home cooks alike. This versatility, combined with the ongoing innovation in product formulations to enhance flavor and health profiles, continues to expand the market opportunities for unsaturated vegetable oils.

Technological advancements in extraction and processing techniques have also played a crucial role in the market's growth. Innovations in cold-pressing and refining processes have improved oil yields and quality, thereby increasing the availability and shelf-life of unsaturated vegetable oils. Moreover, the rise of environmentally sustainable production practices aligns with consumer demands for eco-friendly products, further supporting market expansion. These advancements not only enhance the production efficiency and quality of oils but also help in meeting regulatory standards across different regions, ensuring a consistent supply of high-quality products to the market.

Regionally, the unsaturated vegetable oil market is experiencing varying levels of growth. The Asia Pacific region is witnessing robust expansion, driven by increasing disposable incomes, urbanization, and dietary shifts towards healthier oils in countries like China and India. North America and Europe are also significant markets due to their established health-conscious consumer bases and strong demand for organic and premium oils. Meanwhile, markets in Latin America and the Middle East & Africa are gradually expanding as awareness of the health benefits of unsaturated oils spreads and as local production capabilities improve. This regional variability in market dynamics is crucial for stakeholders to consider as they strategize to capture market share effectively.

Product Type Analysis

Within the unsaturated vegetable oil market, the segmentation by product type into monounsaturated oils and polyunsaturated oils offers insight into consumer preferences and industry trends. Monounsaturated oils, such as olive and canola oils, are favored for their heart health benefits and stability during cooking. These oils are rich in oleic acid and have gained popularity for their ability to reduce bad cholesterol levels and the risk of heart disease. Their versatility in various cooking methods, including frying and sautéing, makes them a staple in both household and industrial kitchens, driving their demand across the globe.

On the other hand, polyunsaturated oils, which include sunflower, soybean, and safflower oils, are prized for their high content of essential fatty acids like omega-3 and omega-6. These oils are increasingly incorporated into dietary supplements and functional food products due to their potential to support cognitive function and anti-inflammatory properties. The growing consumer trend towards functional foods that offer additional health benefits beyond basic nutrition is significantly boosting the demand for polyunsaturated oils. Furthermore, advancements in

CN: Refined Oil: YoY: Apparent Consumption: Diesel Oil data was reported at 15.800 % in Mar 2023. This records an increase from the previous number of 14.400 % for Dec 2022. CN: Refined Oil: YoY: Apparent Consumption: Diesel Oil data is updated monthly, averaging 0.800 % from Nov 2010 (Median) to Mar 2023, with 71 observations. The data reached an all-time high of 26.600 % in Nov 2021 and a record low of -23.300 % in Apr 2021. CN: Refined Oil: YoY: Apparent Consumption: Diesel Oil data remains active status in CEIC and is reported by National Development and Reform Commission. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBR: NDRC: Oil.

The USGS Central Region Energy Team assesses oil and gas resources of the United States. The onshore and State water areas of the United States comprise 71 provinces. Within these provinces, Total Petroleum Systems are defined and Assessment Units are defined and assessed. Each of these provinces is defined geologically, and most province boundaries are defined by major geologic changes. The Illinois Basin Province is located in portions of Kentucky, Illinois, Indiana, Missouri, and Tennessee. The main population centers within the study area are Louisville, Kentucky; Peoria and Springfield Illinois; Indianapolis, Indiana; Saint Louis, Missouri; and Nashville, Tennessee. The main interstates, I-80, I-70, and I-40, generally traverse the area from east to west, while interstates, I-55 and I-65 generally traverse the area from north to south. The Ohio River and Mississippi River and their tributaries drain the area. The province boundary was drawn to include the geologic structures generally considered to be in or bounding the Illinois Basin.

This digital dataset contains historical geochemical and other information for 100 samples of groundwater from 71 wells located within 3 miles of the Poso Creek Oil Field in Kern County, California. An additional 12 wells in the Poso Creek study area, but co-located within 3 miles of the adjacent Rosedale and Rosedale Ranch Oil Fields, were not included in this data release; these data are planned for a future data release associated with those fields. The sampled wells include water-supply wells used primarily for domestic, irrigation, and industrial uses. Numerical water chemistry data were compiled from two data sources: 1) Kern County Public Health Services Department (KCPHSD) PDF (Portable Document Format) files, and 2) the Eastside Water Management Area (EWMA) Groundwater Sustainability Plan (GSP) Chapter. These data sources include varying location and well-construction information. Locations for most of the wells represent either well-specific coordinates provided in the KCPHSD PDFs, approximate locations determined using ArcGIS (GIS, Geographic Information System) software based on descriptive information or location maps in the KCPHSD PDFs, parcel centroid coordinates determined from a GIS parcel shapefile (KERN PARCEL) based on parcel numbers provided by either the KCPHSD or EWMA data source, or approximate locations from Google Earth based on visual identification of well locations. For two wells (Dataset_IDs 1 and 2) coordinates represent the locations provided by the California Department of Water Resources Water Data Library (CDWR WDL) as those particular wells are located in that database in association with water-level measurement data. For three wells (Dataset_IDs 22, 30, and 42) having limited information, locations represent meridian, township, range, section, and quarter-quarter section (MTRSQQ) centroids. Information on well construction was compiled from California Department of Water Resources Well Completion Reports (CDWR-WCR) included with the PDFs located on the KCPHSD website, or located on the CDWR Well Completion Reports Map Application website. Well construction from CDWR-WCRs was available for 53 of the 71 wells. For one well (Dataset_ID 5), a WCR could not be located, however, well construction information was available in the EWMA GSP. Data were manually compiled into two separate files described as follows: 1) a summary data file that includes well identifiers, location, construction, the number of chemistry samples, the period of record, specific sample dates for each site, and an inventory of which constituent groups were sampled on each date; and 2) a data file of geochemistry analyses for selected constituents classified into one of the following groups: water-quality indicators, major and minor ions, nutrients, trace elements, naturally occurring radioactive material (NORM), and volatile organic compounds (VOCs). Ion (charge) balance calculations and percent error of these calculations were included for samples having a complete suite of major ion analyses. Parameter code, analytical method, reporting level, reporting level type, and supplemental notes were included where available or pertinent. A data dictionary was created to describe the geochemistry data file and is provided with this data release.

Mauritania Exports of crude oil to United Kingdom was US$71 during 2011, according to the United Nations COMTRADE database on international trade. Mauritania Exports of crude oil to United Kingdom - data, historical chart and statistics - was last updated on July of 2025.

Crude Oil Refining: OKPD2: VR: Saratov Region data was reported at 534.400 Ton th in Dec 2021. This records a decrease from the previous number of 538.000 Ton th for Nov 2021. Crude Oil Refining: OKPD2: VR: Saratov Region data is updated monthly, averaging 536.100 Ton th from Feb 2016 (Median) to Dec 2021, with 71 observations. The data reached an all-time high of 626.600 Ton th in Oct 2018 and a record low of 5.400 Ton th in Oct 2017. Crude Oil Refining: OKPD2: VR: Saratov Region data remains active status in CEIC and is reported by Federal State Statistics Service. The data is categorized under Russia Premium Database’s Energy Sector – Table RU.RBG001: Primary Crude Oil Refining: by Region.

71 Global export shipment records of Base Oil 600u with prices, volume & current Buyer's suppliers relationships based on actual Global export trade database.

Russia Average Export Price: Non CIS: Sunflower Oil data was reported at 735.800 USD/Ton in Nov 2018. This records a decrease from the previous number of 743.200 USD/Ton for Oct 2018. Russia Average Export Price: Non CIS: Sunflower Oil data is updated monthly, averaging 784.600 USD/Ton from Jan 2013 (Median) to Nov 2018, with 71 observations. The data reached an all-time high of 1,234.600 USD/Ton in Feb 2013 and a record low of 731.400 USD/Ton in Jun 2017. Russia Average Export Price: Non CIS: Sunflower Oil data remains active status in CEIC and is reported by Federal State Statistics Service. The data is categorized under Global Database’s Russian Federation – Table RU.PC001: Average Export Price.

Belgium Exports of crude oil to Serbia was US$71 during 2020, according to the United Nations COMTRADE database on international trade. Belgium Exports of crude oil to Serbia - data, historical chart and statistics - was last updated on June of 2025.

71 Global import shipment records of Crude Rapeseed Oil with prices, volume & current Buyer's suppliers relationships based on actual Global export trade database.

In 2022, liquified natural gas (LNG) cost approximately 18.4 U.S. dollars per million British thermal units in Japan. The country imported the majority of its natural gas supply from overseas.

Natural gas production in Japan

Since Japan has limited natural resources, it heavily depends on imports for its primary energy supply. Only a small amount of the total supply of natural gas energy is produced domestically in areas such as Hokkaido, Chiba, or Niigata Prefecture. The natural gas produced in the around 60 oil and natural gas mines operating in Japan is mainly wet and dry natural gas. Minami-Kanto natural gas fields dissolved in water, which lies across Chiba Prefecture and surrounding prefectures, yields close to 20 percent of the total production of natural gas in the country. The saltwater in the field also includes a great amount of iodine. Japan is hence one of the leading countries regarding iodine production.

LNG imports

Apart from the two percent of in-house natural gas production, the rest of the natural gas supply in Japan originates from liquefied natural gas (LNG) imports from countries like Australia, the state of Qatar, Malaysia, and Indonesia.

Japan imported over 71 megatons of LNG in recent years, making the country the world’s largest importer of LNG. Natural gas and LNG accounted for over 23 percent of the total primary energy supply in Japan, indicating that natural gas and LNG are some of the most essential resources the country requires.

Over the period 2000-2022, Danish Centre for Environment and Energy, Aarhus University (DCE), Greenland Institute of Natural Resources (GINR), and Geological Survey of Denmark and Greenland (GEUS) have published seven Environmental Oil Spill Sensitivity Atlases (see references below). Together, they cover all coastal and offshore areas within the Greenland EEZ except for areas north of latitudes 77 and 81.5 N on the west and east coast, respectively. The main purpose of the atlases is to provide oil spill response planners and responders with tools to identify resources at risk, establish protection priorities and identify appropriate response and clean-up strategies in case of a marine oil spill. The work has been financed by the Environment Agency for the Mineral Resource Activities (EAMRA), Greenland Government (and its predecessors).The web map presents the primary map layers, compiled across all seven atlases. However, the original atlases contain much more in-depth information, and we refer to the following reports:Clausen, D.S., Boertmann, D, Johansen, K.L., Potter, S., Myrup, M., Zinglersen, K.B & Mosbech, A. 2022. Environmental Oil Spill Sensitivity Atlas for Northeast Greenland (71-81.5 N). Scientific Report from DCE – Danish Centre for Environment and Energy No. 495. https://dce2.au.dk/pub/SR495.pdfClausen, D., Johansen, K.L., Mosbech, A., Boertmann, D. & Wegeberg, S. 2012. Environmental Oil Spill Sensitivity Atlas for the West Greenland (68°-72° N) Coastal Zone, 2nd revised edition. Scientific Report from DCE – Danish Centre for Environment and Energy No. 44. https://www.dmu.dk/Pub/SR44.pdfClausen, D.S., Mosbech, A., Boertmann, D., Johansen, K.L., Nymand, J., Potter, S. & Myrup, M. 2016. Environmental oil spill sensitivity atlas for the Northwest Greenland (75°-77° N) coastal zone. Scientific Report from DCE – Danish Centre for Environment and Energy No. 196. https://dce2.au.dk/pub/SR196.pdfJohansen, K.L., Boertmann, D., Clausen, D.S., Kyhn, L., Potter, S., Myrup, M., Zinglersen, K.B. & Mosbech, A. 2022. Environmental Oil Spill Sensitivity Atlas for Southeast Greenland (56-71N). Scientific Report from DCE – Danish Centre for Environment and Energy No. 492. https://dce2.au.dk/pub/SR492.pdfMosbech, A., Anthonsen, K. L., Blyth, A., Boertmann, D., Buch, E., Cake, D., Grøndahl, L., Hansen, K.Q., Kapel, H., Nielsen, S., Nielsen, N., Platen, F. V., Potter, S. & Rasch, M. 2000. Environmental Oil Spill Sensitivity Atlas for the West Greenland Coastal Zone. The Danish Energy Agency, Ministry of Environment and Energy. https://ecos.au.dk/fileadmin/bioscience/Documents/Groenland_Olie/WestGrenlandSensitivityAtlas_62-68_Chapter1-8.pdfhttps://ecos.au.dk/fileadmin/bioscience/Documents/Groenland_Olie/WestGrenlandSensitivityAtlas_62-68_Chapter9-16.pdfMosbech, A., Boertmann, D., Olsen, B. Ø., Olsvig, S., von Platen, F., Buch, E., Hansen, K.Q., Rasch, M., Nielsen, N., Møller, H. S., Potter, S., Andreasen, C., Berglund, J. & Myrup, M. 2004: Environmental Oil Spill Sensitivity Atlas for the South Greenland Coastal Zone. NERI Technical Report no. 493. https://www2.dmu.dk/1_viden/2_Miljoe-tilstand/3_natur/sensitivity_mapping/58_62/atlas_58_62.pdfStjernholm, M., Boertmann, D., Mosbech, A., Nymand, J., Merkel, F., Myrup, M., Siegstad, H. & Potter, S. 2011. Environmental Oil Spill Sensitivity Atlas for the Northern West Greenland (72°-75° N) Coastal Zone. National Environmental Research Institute, Aarhus University, Denmark. 210 pp. – NERI Technical Report no. 828. https://www.dmu.dk/Pub/FR828.pdf

The USGS Central Region Energy Team assesses oil and gas resources of the United States. The onshore and State water areas of the United States comprise 71 provinces. Within these provinces, Total Petroleum Systems are defined and Assessment Units are defined and assessed. Each of province is defined geologically, and most province boundaries are defined by major geologic changes. This dataset is a compilation of data that has been studied and published separately, and in some cases adjacent provinces do not share a common boundary. As a consequence, there are numerous gaps and overlaps in this layer.

The USGS Central Region Energy Team assesses oil and gas resources of the United States. The onshore and State water areas of the United States comprise 71 provinces. Within these provinces, Total Petroleum Systems are defined and Assessment Units are defined and assessed. Each of these provinces is defined geologically, and most province boundaries are defined by major geologic changes.
The Denver Basin Province is located in eastern Colorado, western Nebraska, southern South Dakota, and eastern Wyoming encompassing all or parts of Pueblo, El Paso, Crowley, Lincoln, Kit Carson, Elbert, Teller, Douglas, Jefferson, Denver, Arapahoe, Adams, Washington, Yuma, Morgan, Weld, Broomfield, Boulder, Larimer, Logan, Sedwick, Freemont, and Phillips Counties in Colorado. All or parts of Cheyenne, Deuel, Kimball, Banner, Scotts Bluff, Morrill, Garden, Sheridan, Box Butte, Sioux, and Dawes Counties in Nebraska. All or parts of Laramie, Platte, and Goshen Counties in Wyoming, and all of par ...