Analysis of ‘Brady Geothermal Field Borehole Pressure Data’ provided by Analyst-2 (analyst-2.ai), based on source dataset retrieved from https://catalog.data.gov/dataset/f6ec5e24-d073-4f6a-bda8-03be15c5cc7b on 12 February 2022.

--- Dataset description provided by original source is as follows ---

This submission supersedes pressure data from March 2017 which can be found as a link in the submission resources. This submission contains 3 .csv files with time series pressure data in 3 observation wells at Brady Geothermal Field as part of the PoroTomo project. These pressure files correct a time stamp issue that was in older data which did not correct for daylight savings time which occurred 13 Mar 2016 at 0900 UTC. The data here provides borehole pressures at different temperatures and times. The timeframe each resource was taken in varies between each resource and can be found in the resource descriptions.

--- Original source retains full ownership of the source dataset ---

This geospatial data set represents about 2,500 locations of boreholes, shafts, tunnels, and drifts on and around the Nevada Test Site (NTS) where rock-samples have been collected. Information from the rock-samples is summarized for each hole and includes lithologic descriptions, physical and mechanical properties, fracture characteristics, and hydraulic properties where holes were completed below the water table. The digital data are accessed from the webpage for the NTS U.S. Geological Survey (USGS) Core Library and Data Center, Mercury, Nevada. Links to additional information, such as water-level data from the National Water Inventory System (NWIS), and USGS borehole graphical information are included for some holes.

Report on a formation thermal conductivity test that was performed on the geothermal test bore at Ulbrich Heights at 38 Louis Circle Lane in Wallingford, Connecticut. Data are applicable only within the Wallingford region and should not be extrapolated for other climatic and geographic regions. The analysis assumes no systemic defects in the borehole prior to and during installing and testing. A graphite and Bentonite grouting mixture was assumed to be consistent throughout borehole length. These data were collected as part of the Community Geothermal Heating and Cooling Design and Deployment Grant Program. This associated project's goal is to design and develop a district geothermal heating and cooling system that will serve at least 50% of the heating and cooling load of a 132-unit, affordable housing complex in Wallingford, CT. The project is led by Connecticut Department of Energy and Environmental Protection (DEEP). Borehole drilling and thermal conductivity testing were conducted by Connecticut Wells Inc. and data were analyzed by Geothermal Resource Technologies Inc. (GRTI).

Analysis of ‘Project HOTSPOT: Kimama Well Borehole Geophysics Database’ provided by Analyst-2 (analyst-2.ai), based on source dataset retrieved from https://catalog.data.gov/dataset/11991798-6a97-4a25-91b9-c452a1c26df5 on 27 January 2022.

--- Dataset description provided by original source is as follows ---

The Snake River Plain (SRP), Idaho, hosts potential geothermal resources due to elevated groundwater temperatures associated with the thermal anomaly Yellowstone-Snake River hotspot. Project HOTSPOT has coordinated international institutions and organizations to understand subsurface stratigraphy and assess geothermal potential. Over 5.9km of core were drilled from three boreholes within the SRP in an attempt to acquire continuous core documenting the volcanic and sedimentary record of the hotspot: (1) Kimama, (2) Kimberly, and (3) Mountain Home. The Kimama drill site was set up to acquire a continuous record of basaltic volcanism along the central volcanic axis and to test the extent of geothermal resources beneath the Snake River aquifer.

Data submitted by project collaborator Doug Schmitt, University of Alberta

--- Original source retains full ownership of the source dataset ---

The global borehole imaging logging market is expected to reach $XX million by 2033, with a CAGR of XX% over the forecast period. Borehole imaging logging services provide detailed information about the geological formations encountered in boreholes, which is essential for resource exploration, environmental monitoring, and well planning. The increasing demand for oil and gas, along with the growing focus on environmental sustainability, is driving the market's growth. Key growth factors influencing the market include advancements in logging technologies, the increasing adoption of real-time downhole data acquisition, and the growing demand for borehole imaging data in the water treatment, metal, and mining industries. However, the high cost of borehole imaging logging equipment and the limited availability of skilled personnel may restrain market growth. Regional market analysis indicates that North America and Europe are the dominant markets, followed by Asia Pacific and the Middle East & Africa. The presence of major oil and gas fields, along with stringent environmental regulations, supports market expansion in these regions.

Temperature measurement data obtained from boreholes for the Association of American State Geologists (AASG) geothermal data project. Typically bottomhole temperatures are recorded from log headers, and this information is provided through a borehole temperature observation service for each state. Service includes header records, well logs, temperature measurements, and other information for each borehole. Information presented in Geothermal Prospector was derived from data aggregated from the borehole temperature observations for all states. For each observation, the given well location was recorded and the best available well identifier (name), temperature and depth were chosen. The "Well Name Source," "Temp. Type" and "Depth Type" attributes indicate the field used from the original service. This data was then cleaned and converted to consistent units. The accuracy of the observation's location, name, temperature or depth was note assessed beyond that originally provided by the service. Bottom hole temperature datasets from the AASG were downloaded from repository.usgin.org between May 16 and May 24, 2013. The data were cleaned to remove null and non-real entries, and units were standardized across all datasets. When selecting key attributes, specific criteria were used to determine the best available values. For temperature, corrected temperature was preferred, followed by measured temperature. For depth, depth of measurement was prioritized, with true vertical depth and driller total depth used as alternatives. Well identification was assigned based on the API number when available, followed by the well name, with the observation URI used as a last option.

Edwards Air Force Base (EAFB) is located in Kern County, CA, approximately 35 kilometers (km) northeast of Lancaster and 9 km south of California City. The Air Force Research Laboratory (AFRL) is situated on EAFB, approximately 7 km southwest of Boron, CA. Release of contaminants from the AFRL facilities have contaminated local groundwater, which is mostly restricted to fractured granitic bedrock, but studies indicate that the groundwater and contaminant plumes have moved into alluvial deposits to the north and northwest (AECOM, 2014). The U.S. Geological Survey (USGS) and the Air Force Civil Engineer Center (AFCEC) entered into a cooperative agreement in 2017 to develop a hydrogeologic framework model to help determine groundwater movement and the geologic and lithologic structures that control groundwater movement. This dataset of lithologic descriptions from boreholes was used for lithologic analysis to build a hydrogeologic framework in the EAFB area. Data includes the California Department of Water Resources borehole log number (if known), state well number (if applicable), location information, and detailed lithologic descriptions, including depth to bedrock where present, for each borehole.

This dataset contains the collated wireline logs, stratigraphy and core analysis of the three boreholes drill as part of the publicly funded Rapid Global Geological Events Project (RGGE) which ran between 1995-1998. The aim of the RGGE project was to identify the effects of climatic changes on modern sediments. The project focused on the Kimmeridge Clay due to its unbroken sequence of fossiliferous marine mudstones. These mudstones have compositional variations in organic content, minerology, fauna and clay content which reflect changes in both the climate and sea level. Over the course of the project the entire sequence of the Kimmeridge Clay was cored across three boreholes, two at Swanworth Quarry and one at Metherhills.

Market Analysis of Borehole Well Logging Software The global borehole well logging software market is projected to reach a value of X million by 2033, expanding at a CAGR of XX% during the forecast period from 2025 to 2033. This growth is primarily driven by increasing demand for efficient exploration and production methods in the oil and gas sector, coupled with rising environmental concerns and the need for accurate geological data. The market segments by type (cloud-based and local deployment) and application (oil and gas, mining, and others) provide insights into the diverse usage of borehole well logging software across industries. Major companies, such as Mount Sopris Instruments, GAEA, and RockWare, hold significant market share due to their well-established product offerings and strong customer base. The market is also characterized by the presence of several regional players, catering to specific geographical needs. Key trends influencing market growth include the adoption of cloud-based solutions for remote data access and collaboration, as well as increasing investments in geological data interpretation and analysis. However, factors such as high implementation costs and data security concerns may act as potential market restraints.

This database of selected borehole records from the Yamal Peninsula, Russia, contains environmental descriptions (textual and numerical) of the units on the index map, and relevant borehole data. The Index Map of Yamal Peninsula (VSEGINGEO-Earth Cryosphere Institute SB RAS; PI - Prof.E.S.Melnikov) was originally compiled at a scale of 1 to 1,000,000, as 'The Map of Natural Complexes of West Siberia for the Purpose of Geocryological Prediction and Planning of Nature-Protection Measures for the Mass Construction, 1 to 1 mln' (1991) by E.S.Melnikov and N.G.Moskalenko (eds.). It was taken as a base map for nature-protection regionalization. Environmental 'regions', 'sub-regions', 'landscapes' and localities' shown on a landscape map are merged into the nature-protection regions. The map was compiled by interpreting more than 1000 satellite images and aerial photos as well as from analysis of field data from several institutions. Dominating components of the landscape, composition of the surface deposits, geocryological conditions and natural protection of ground water were considered while distinguishing the Nature-Protection Regions within the limits of Environmental Regions (Melnikov, 1988). The map is supplied with relevant databases, containing the following information - number of regions and landscape type; category of resiliency; category of the ground water protection; vegetation type; geological and geocryological structure to the depth of 10-15 m; ice content (of lenses and of macro-inclusions separately); thickness of seasonally frozen and seasonally thawed layers; ground temperature; contemporary exogenic geological (periglacial) processes; and the area affected by these processes.The 55 nature-protection regions of Yamal Peninsula generalize information. To approve the ranges of geocryological and cryolithological characteristics, 160 boreholes were retrieved out of the database containing more than 4000 boreholes data obtained in 1977-1990 by Fundamentproekt Design Institute (Moscow, Russia; PI - Dr.sci.M.A.Minkin) at Kharasavey and Bovanenkovo gas fields and along the pipelines Yamal-Ukhta and Yamal-Uzhgorod. The boreholes have reference to geographical coordinates (latitude and longitude), as well as to the nature-protection region numbers shown on the Index Map. A total of 21 units are covered by borehole data, 5-8 boreholes in each unit, covering most typical conditionsThe original database consisted of 3 relational tables. The first table includes category of resiliency; locality type description; landscape type description; ground-ice content, water saturation, cryogenic structure, macro-ground-ice content; vegetation types; seasonally frozen and seasonally thawed layer depths; ground temperature at 10 m; exogenic geological processes an their paragenesis and combinations; and degree of the surface disturbance. The second relational table contains layer-by-layer description of the lithological section types. The third table for the boreholes includes the description of topography around the borehole; types of geological profiles through the active layer and depths down to the permafrost table; ground temperature at 10-m depth (close to the depth of zero annual amplitude in the area); macro-ice content; and salinity of permafrost. These data are presented on the CAPS Version 1.0 CD-ROM, June 1998.

BGS has drilled almost 600 boreholes to prove seismic interpretations of the marine Quaternary geology and bedrock from the UK Continental Shelf (UKCS). The collection also includes additional third party data and has assisted in the creation of BGS marine geology maps. The boreholes penetrate beneath the sea bed to depths ranging from about 10 m to over 300 m, depending on the target depth or technical problems associated with drilling the borehole. The data include descriptive geological core logs and data which have been captured from these, and in some cases, natural gamma logs. A variety of analyses have been conducted on the core material, such as particle size analysis (PSA), micropalaeontological analysis, geotechnical investigations, palaeomagnetic analysis and age dating. Core material is managed as part of the BGS materials collection and is available for examination and subsampling. The data are stored as part of the National Geoscience Data Centre (NGDC) and the Marine Environmental Data and Information Network (MEDIN) Data Archive Centre (DAC) for geology and geophysics. Data are delivered via the BGS GeoIndex. This dataset is covered by multiple layers, split by the type of material or sampling technique, and the type of data. Borehole-type samples (including boreholes, cores and drills), grab-type samples and other sample types are separated, and there is a metadata layer (containing metadata and links to scanned borehole logs) and a geological data layer (containing depth-bounded geological observations and/or measurements) for boreholes, grabs and other sample types. For borehole-type data, a geotechnical layer containing numerical results of geotechnical tests is also provided. Where available, particle size analysis (PSA) and geochemical data are also provided as separate layers. The data are applicable to a wide range of uses including environmental, geotechnical and geological studies. Reference: Fannin, NGT. (1989) Offshore Investigations 1966-87 British Geological Survey Technical Report WB/89/02, British Geological Survey.

The global borehole yield testing market is experiencing robust growth, driven by increasing infrastructure development, particularly in water resource management and the energy sector. Government agencies, construction firms, and oil and gas companies are significant drivers of demand, relying on accurate yield testing to assess groundwater availability for various applications, ranging from potable water supply to hydraulic fracturing. The market is segmented by application (government agencies, construction, oil and gas, power plants, geology, others) and test type (calibration, step, constant rate, recovery, others). Technological advancements in testing equipment and data analysis are enhancing the accuracy and efficiency of borehole yield testing, further fueling market expansion. The rising adoption of sustainable water management practices globally contributes significantly to this growth, as precise yield testing is crucial for optimizing water resource utilization and mitigating water scarcity. While regulatory hurdles and the high cost of specialized equipment could pose some challenges, the overall market outlook remains positive, with a projected considerable Compound Annual Growth Rate (CAGR) over the forecast period. The regional distribution of the borehole yield testing market reflects global infrastructure investment patterns. North America and Europe currently hold substantial market share, owing to their established infrastructure and robust regulatory frameworks. However, emerging economies in Asia-Pacific and the Middle East & Africa are experiencing rapid growth in demand, fueled by substantial infrastructure projects and increasing awareness of water resource management. This expansion is particularly notable in countries experiencing rapid urbanization and industrialization, where accurate assessment of groundwater resources is critical for sustainable development. Competition among established and emerging players is intensifying, leading to innovations in testing techniques and the development of more cost-effective solutions. The market is expected to witness increased consolidation through mergers and acquisitions as companies strive to gain a competitive edge.

Records of past temperature derived from boreholes drilled into the Earth crust. Parameter keywords describe what was measured in this data set. Additional summary information can be found in the abstracts of papers listed in the data set citations. Information on the University of Michigan Borehole Database data sets are found on the Borehole Data Page (http://www.ncdc.noaa.gov/paleo/borehole).

Market Overview: The Borehole Seismic Survey market is a segment of the seismic exploration industry and has experienced significant growth in recent years, with a market size of $XXX million in 2025 and a projected CAGR of XX% from 2025 to 2033, reaching a value of $XXX million by 2033. This growth has been driven by the increasing demand for accurate subsurface imaging and characterization in various applications, including oil and gas exploration, geological exploration, and mining. Market Trends and Drivers: The Borehole Seismic Survey market is influenced by several key trends and drivers. The growing emphasis on enhanced oil recovery, the need for accurate reservoir characterization, and the development of advanced data processing techniques are major factors behind its growth. The increasing adoption of horizontal drilling and multi-well development strategies has also contributed to the demand for borehole seismic surveys. Additionally, government regulations and environmental concerns are further fueling the adoption of these surveys to minimize environmental impact and ensure safety during exploration and production activities.

Borehole Extensometers Market size was valued at USD 251 Million in 2023 and is projected to reach USD 442.56 Million by 2030, growing at a CAGR of 8.7 % during the forecast period 2024-2030.

Global Borehole Extensometers Market Drivers

The growth and development of the Borehole Extensometers Market is attributed to certain main market drivers. These factors have a big impact on how integrated gas systems are demanded and adopted in different sectors. Several of the major market forces are as follows:

Infrastructure Development: The building of highways, bridges, tunnels, dams, and other large-scale infrastructure projects is frequently associated with the demand for borehole extensometers. Geotechnical monitoring equipment is becoming more and more necessary as these projects grow Environmental Monitoring: In a variety of environmental applications, such as the detection of landslides, the tracking of subsidence, and the investigation of geological phenomena, borehole extensometers are crucial for tracking ground movement. Such monitoring techniques may become more and more necessary as worries about climate change and environmental stability grow. Mining Activities: In order to monitor ground stability during mining activities, borehole extensometers are essential. The need for these tools to maintain safety and avert geological dangers may be driven by the growth or development of mining ventures. Investigation and Research: The need for monitoring equipment is influenced by ongoing investigations and research in the fields of earth sciences and geotechnical engineering. Research initiatives use borehole extensometers to collect data on the behavior and deformation of the ground. Government Regulations: Tight rules pertaining to environmental impact assessments and safety in the mining and construction sectors may encourage the use of monitoring tools such as borehole extensometers. Using cutting edge monitoring technologies is frequently necessary to ensure compliance with rules. Technological Advancements: Better sensors, wireless connectivity, and data analytics are a few examples of how advances in borehole extensometer technology can propel market expansion. These developments draw people seeking cutting-edge solutions by improving monitoring's accuracy and efficiency. Growing Awareness: The market for borehole extensometers may expand as a result of governments and businesses becoming more conscious of the value of real-time monitoring in averting disasters, guaranteeing worker safety, and streamlining construction procedures.

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Borehole Enlargement Systems Market Size 2024-2028

The borehole enlargement systems market size is forecast to increase by USD 308 million at a CAGR of 3.5% between 2023 and 2028. The market is experiencing significant growth due to the rising demand for oil and natural gas, which is driving the need for more efficient drilling techniques. One such innovation is the emergence of laser drilling technology in the oil and gas industry, which offers increased drilling accuracy and efficiency. Additionally, the change in energy mix towards cleaner sources is fueling the adoption of borehole enlargement systems for enhanced oil recovery (EOR) applications. EOR techniques, such as water flooding and gas injection, require larger boreholes to optimize reservoir production. Furthermore, the increasing focus on reducing drilling costs and enhancing productivity is propelling market growth. Upstream oil and gas equipment companies are developing seismic survey technologies and increasing investments in R&D to improve the efficiency of surveys, which is increasing the number of oil exploration activities across the world. Fossil fuels have a leading position in the energy mix, but burning fossil fuels for power generation increases the volume of greenhouse gas (GHG) emissions into the atmosphere. However, challenges such as high capital investment, complex drilling operations, and stringent regulatory requirements may hinder market expansion. Despite these challenges, the Borehole Enlargement Systems Market is expected to continue its growth trajectory due to the increasing demand for oil and gas and the ongoing technological advancements in drilling techniques. The market report forecast market size, historical data spanning from 2018 - 2022, and future projections, all presented in terms of value in USD million for each of the mentioned segments.

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Market Segmentation

The market report provides comprehensive data (region-wise segment analysis), with forecasts and estimates in 'USD million' for the period 2024-2028, as well as historical data from 2018 - 2022 for the following segments.

Application Outlook

  Onshore
  Offshore





Region Outlook

  North America

    The U.S.
    Canada





  Europe

    U.K.
    Germany
    France
    Rest of Europe





  APAC

    China
    India





  Middle East & Africa

    Saudi Arabia
    South Africa
    Rest of the Middle East & Africa


  South America

    Argentina
    Brazil
    Chile

By Application Insights

The onshore segment is estimated to witness significant growth during the forecast period. The market encompasses the production and supply of under-reamers, hole openers, and related technologies used to enhance drilling efficiency and ensure wellbore stability during the drilling process. These systems, which include under-reamers with cutter arms and steel balls, are hydraulically actuated to enlarge the wellbore and improve production capacity.

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The onshore segment accounted for USD 1.39 billion in 2018. Advanced technologies such as RFID and mud telemetry are increasingly being integrated into these systems to optimize drilling operations and ensure safety in both onshore and offshore drilling. Despite the global energy consumption and fluctuating oil prices, the demand for borehole enlargement systems remains in water well drilling and hydrocarbon recovery applications. Technological barriers, including the need for precise engineering and adherence to safety regulations such as the Offshore Safety Directive, continue to drive innovation in the market. Output/shipments of underreamers and hole openers are expected to increase as drilling companies seek to maximize production capacity and minimize casing installations.

Regional Analysis

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South America is estimated to contribute 30% to the growth of the global market during the market forecast period. Technavio's analysts have elaborately explained the regional trends and drivers that shape the market during the forecast period.

The Borehole Enlargement Systems market encompasses technologies and equipment used to enhance the drilling process in both onshore and offshore applications. These systems include under-reamers, hole openers, and cutter arms, which are utilized to enlarge the wellbore and ensure wellbore stability during drilling. Under-reamers, hydraulically actuated tools with cutter arms and steel balls, are employed to widen the wellbore and improve drilling efficiency. Advanced borehole enlargement systems incorporate RFID technology and mud telemetry to monitor drilling progress and optimize drilling parameters in real-time. The output/shipments of borehole enlargement systems are driven by global energy cons

This data was produced to support a project looking at low permeability rocks in sub-Saharan Africa. Multiple boreholes were drilled for the project with geology identified from chippings. Groundwater chemistry was analysed from the resulting boreholes. The data contained within this record is from the CD that accompanies the report: J Davies and J Cobbing, 2002. An assessment of the hydrogeology of the Afram Plains, Eastern Region, Ghana. British Geological Survey Internal Report, CR/02/137N. 66pp http://nora.nerc.ac.uk/id/eprint/505607/1/CR_02_137N.pdf The CD has not been uploaded in full elsewhere.

The Borehole Well Logging Software market is projected to grow from XXX million in 2023 to XXX million by 2033, exhibiting a CAGR of XX% during the forecast period. The growth of the market is primarily driven by the increasing demand for accurate and detailed subsurface data for various applications, such as groundwater exploration, mineral exploration, and environmental monitoring. Furthermore, the rising adoption of advanced technologies like 3D visualization and machine learning in borehole well logging is also contributing to the market's expansion. Regional analysis reveals that North America currently dominates the Borehole Well Logging Software market, followed by Europe and Asia Pacific. The presence of major oil and gas companies and advanced research institutions in North America is driving the growth in the region. Europe is witnessing significant growth due to the increasing focus on groundwater exploration and environmental protection. Asia Pacific is expected to emerge as a key growth market, driven by the rising demand for groundwater resources and mineral exploration in developing countries. Major players operating in the market include Mount Sopris Instruments, GAEA, RockWare, Novotech, Fine Software, EasyLog, Geomatrix, Groundwater Software, Rocscience, and Dogaintech. These companies are offering a wide range of software solutions tailored to meet the specific needs of various industries.

The global borehole measurement system market is experiencing robust growth, driven by the increasing demand for accurate subsurface data across various sectors. The market, valued at approximately $1.5 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 7% from 2025 to 2033. This expansion is fueled by several key factors: the burgeoning construction industry, particularly in developing economies, necessitates precise geological surveys; the mining sector relies heavily on borehole measurements for resource exploration and extraction optimization; growing environmental awareness and the need for efficient groundwater management are further stimulating demand; and advancements in sensor technology are leading to more accurate, reliable, and cost-effective measurement systems. The handheld segment currently holds the largest market share due to its portability and ease of use in various terrains, while the mining application segment dominates due to its significant usage in exploration and development activities. Major players in the market, including Stockholm Precision Tools AB, RESPEC, and IMDEX Limited, are focusing on technological innovation and strategic partnerships to expand their market reach and enhance their product offerings. Regional variations in market growth are expected, with North America and Europe holding significant shares currently. However, rapidly developing economies in Asia-Pacific, particularly China and India, are poised for substantial growth due to increased infrastructure development and mining activities. While the market faces some restraints such as the high initial investment costs associated with advanced systems and the potential for environmental regulations, the overall positive market outlook driven by technological advancements and robust demand across multiple sectors suggests a positive future trajectory for the borehole measurement system market. This report provides a detailed analysis of the global Borehole Measurement System market, projecting a market value exceeding $3.5 billion by 2028. It offers in-depth insights into market segmentation, key players, emerging trends, and growth drivers, providing invaluable information for industry stakeholders, investors, and researchers. The report leverages extensive primary and secondary research, incorporating data from reputable sources and expert interviews to ensure accuracy and relevance.