This layer identifies Site Remediation Program (SRP) cases that meet the definition of an Immediate Environmental Concern (IEC), as per N.J.A.C. 7:26E-1.8. As such, IEC cases are priority remedial cases that involve exposure to contaminants that may result in risks to human health. The IEC layer includes points representing potable well, vapor intrusion and direct contact IECs. The location of these points identifies the site where the source of the contamination originated from when known or a centralized location of a contaminated area when the source of the contamination is unknown. Additional information concerning an IEC case can be obtained by contacting Andrew Sites of the Bureau of the Immediate Concern Unit (ICU) at (609) 530-2582; the Licensed Site Remediation Professional (LSRP) if one is associated with the case and through the IEC dataminer report at https://datamine2.state.nj.us/DEP_OPRA/OpraMain/categories?category=General. The IEC layer will reflect current IEC data in NJEMS through nightly cycle updates. This metadata is specifically for a companion relational table that displays information concerning the receptor associated with the IEC case when applicable. The relationship is set up based on the following NJEMS identifiers: Internal Document ID and Subject Item ID.

This layer identifies Site Remediation Program (SRP) cases that meet the definition of an Immediate Environmental Concern (IEC), as per N.J.A.C. 7:26E-1.8. As such, IEC cases are priority remedial cases that involve exposure to contaminants that may result in risks to human health. The IEC layer includes points representing potable well, vapor intrusion and direct contact IECs. The location of these points identifies the site where the source of the contamination originated from when known or a centralized location of a contaminated area when the source of the contamination is unknown. This metadata is specifically for a companion relational table that displays information concerning the LSRP assigned to the IEC case when applicable. The relationship is set up based on the following NJEMS identifiers: Internal Document ID and Subject Item ID. Additional information concerning an IEC case can be obtained by contacting Andrew Sites of the Bureau of the Immediate Concern Unit (ICU) at (609) 530-2582; the Licensed Site Remediation Professional (LSRP) if one is associated with the case and through the IEC dataminer report at https://datamine2.state.nj.us/DEP_OPRA/OpraMain/categories?category=General. The IEC layer will reflect current IEC data in NJEMS through nightly cycle updates.

The global market for medium voltage intelligent switchgear is experiencing robust growth, driven by increasing demand for enhanced grid reliability, improved power quality, and the integration of renewable energy sources. The rising adoption of smart grids and the need for efficient power distribution in both residential and commercial sectors are key factors fueling this expansion. Industrial applications, particularly in manufacturing and data centers, are also significantly contributing to market growth due to their stringent requirements for power availability and safety. Technological advancements, such as the incorporation of advanced sensors, communication protocols (like IEC 61850), and digital twins for predictive maintenance, are further enhancing the functionality and appeal of intelligent switchgear. The shift towards gas-insulated switchgear (GIS) over air-insulated switchgear (AIS) is also a notable trend, driven by its superior performance characteristics in terms of safety, compactness, and reduced maintenance requirements. While high initial investment costs could potentially restrain market growth, the long-term benefits in terms of reduced operational costs and improved reliability are expected to outweigh this factor. Major players like ABB, Siemens, and Schneider Electric are leading the innovation and market penetration efforts, fostering healthy competition and driving technological advancements within the sector. The market is segmented geographically, with North America and Europe currently holding significant market share. However, the Asia-Pacific region, particularly China and India, is projected to witness rapid growth due to increasing infrastructure development and industrialization. The forecast period (2025-2033) is expected to see continued expansion, propelled by government initiatives promoting smart grid infrastructure and the growing awareness of the benefits of intelligent switchgear. Competitive dynamics are intense, with established players facing challenges from emerging regional manufacturers. Strategic partnerships, mergers and acquisitions, and product diversification are likely to shape the competitive landscape in the coming years. The market's overall trajectory suggests sustained, healthy growth, with opportunities for significant expansion across various geographic regions and application segments.

The North American Gas Insulated Switchgear (GIS) market is experiencing robust growth, driven by increasing demand for reliable and efficient power transmission and distribution infrastructure. The market's Compound Annual Growth Rate (CAGR) exceeding 6% from 2019-2033 reflects a sustained upward trajectory fueled by several key factors. Firstly, the expansion of renewable energy sources, particularly solar and wind power, necessitates advanced switchgear solutions capable of handling intermittent power generation and ensuring grid stability. Secondly, the growing focus on improving grid modernization and smart grid technologies is boosting investments in GIS, which offers superior performance and protection compared to traditional air-insulated switchgear. Furthermore, stringent government regulations aimed at improving grid reliability and safety are pushing utilities to adopt more advanced switchgear technologies. The market is segmented by voltage (low, medium, and high voltage), end-user (commercial, residential, and industrial), and geography (Canada, the United States, and Mexico). The US holds the largest market share due to its extensive power grid and higher adoption rates of advanced technologies. Industrial applications dominate the end-user segment, driven by the need for reliable power supply in manufacturing facilities and data centers. However, challenges such as high initial investment costs and the need for specialized expertise in installation and maintenance could potentially restrain market growth. The competitive landscape is characterized by the presence of both established global players and regional manufacturers. Key players like Hitachi, Schneider Electric, GE, Eaton, Toshiba, Mitsubishi Electric, Siemens, Hyosung, Bharat Heavy Electricals, and Powell Industries are actively engaged in developing innovative GIS solutions and expanding their market presence. The market is expected to witness increased mergers and acquisitions as companies strive to consolidate their market share and broaden their product portfolios. The forecast period (2025-2033) anticipates continued growth, driven by ongoing investments in grid infrastructure modernization, renewable energy integration, and the increasing demand for advanced power management solutions across all end-user segments. The market will likely witness technological advancements, such as the integration of digital technologies and the adoption of eco-friendly materials, further enhancing the performance and sustainability of GIS systems. Recent developments include: October 2022: Mitsubishi Electric Power Product Company, Inc. (MEPPI) announced the first shipments of its 72 kV vacuum circuit breaker (VCB) with dry-air insulation. These are designed, assembled, and tested in the United States of America. The company's 72 kV vacuum circuit breaker meets all applicable IEEE, IEC, and ANSI certification standards. The 72 kV vacuum circuit breaker employs the company's 65-year history of vacuum interrupter technology. It provides customers with a cost-effective, environmentally responsible, zero-global-warming potential alternative to SF6 gas and alternative gas-insulating mediums., May 2022: The federal government launched USD 2.5 billion in funds to modernize and expand the country's power grid capacity under the Transmission Facilitation Program (TFP) created by the Bipartisan Infrastructure Law. As part of this, the U.S. Department of Energy (DOE) issued a request for information (RFI) to seek public input on the structure of the new revolving fund program.. Notable trends are: High Voltage Hold Significant Market Share.

This layer identifies Site Remediation Program (SRP) cases that meet the definition of an Immediate Environmental Concern (IEC), as per N.J.A.C. 7:26E-1.8. As such, IEC cases are priority remedial cases that involve exposure to contaminants that may result in risks to human health. The IEC layer includes points representing potable well, vapor intrusion and direct contact IECs. The location of these points identifies the site where the source of the contamination originated from when known or a centralized location of a contaminated area when the source of the contamination is unknown. Additional information concerning an IEC case can be obtained by contacting Andrew Sites of the Bureau of the Immediate Concern Unit (ICU) at (609) 530-2582; the Licensed Site Remediation Professional (LSRP) if one is associated with the case and through the IEC Dataminer report at https://datamine2.state.nj.us/DEP_OPRA/OpraMain/categories?category=General. The IEC layer will reflect current IEC data in NJEMS through nightly cycle updates.

This data layer contains information about areas in the state which are specified as the Currently Known Extent (CKE) of ground water pollution. CKEs are geographically defined areas within which the local ground water resources are known to be compromised because the water quality exceeds drinking water and ground water quality standards for specific contaminants. Historically, a number of the CKEs have also been identified as Well Restriction Areas (WRAs). The regulatory authority for developing CKEs is in N.J.A.C. 7:1J, entitled Processing of Damage Claims Pursuant to the Spill Compensation and Control Act. CKEs are used by NJDEP staff, water purveyors, and local officials to make decisions concerning appropriate treatment and/or replacement of contaminated drinking water supplies. Additional guidance on the mapping of CKEs for potable well Immediate Environmental Concerns (IECs) can be found in Section 4.1.6. and Appendix A of the NJDEP Site Remediation Program IEC Guidance Document. The CKE areas, as shown, are intended to provide information to the public about contaminated ground water areas in the state. Unless precautionary measures are taken to protect potable users, well installation should be avoided. This information is being made available so informed decisions can be made on well location, design, or treatment before wells are proposed, permitted, and installed. The Department is currently engaged in the reassessment and investigation of existing CKEs; however, it is important to note that CKEs are approximations of the actual aerial extent of ground water contamination and the boundaries presented here may change over time as new information is developed and plume migration occurs. At this time, the records of the CKEs in this database application may include a list of the specific ground water contaminants where available. Also, it should be noted that CKE areas might overlap with other CKEs and Classification Exception Areas (CEAs). Revisions and additions will be used to update the CKE database as new information is received and processed. In this application, the CKE is represented as a GIS-based polygon coverage that depicts the spatial extent of known potable well contamination in an area (as determined by NJDEP Site Remediation staff). The CKE polygon will usually follow the property boundary lines of all the contiguous properties with contaminated wells when the wells are within 1,000 feet of each other. However, on properties larger than 3.5 acres the boundary of the CKE may be based on the location of the contaminated well and may not encompass the entire property. Also, in some areas contaminated wells may have been detected in proximity to an established CKE but have not been included within the boundary of the CKE because the well is outside the 1,000 foot radius. For further information contact NJDEPs Site Remediation Waste Management Program (SRWMP), Bureau of Environmental Management and Site Assessment (BEMSA), the lead program for CKE case oversight at (609) 530-2474. Be advised that CKEs have not been created for IECs where public supply wells that have been impacted by ground water contamination and a CKE has not yet been developed for all areas where a domestic potable well IEC exists.

This dataset represents lithogeochemistry of Saskatchewan samples.

This dataset represents the exhaustive mapping and sampling program of the Athabasca Group between 1975 and 1981 by the Saskatchewan Geological Survey (SGS), the results of which are contained in Ramaekers (1990). These samples are now stored at the Ministry of Energy and Resources, Subsurface Geological Laboratory in Regina, Saskatchewan. A selection of these samples was chosen to help characterize the background geochemical signature of the Athabasca Group and to identify anomalous regions. A total of 837 samples were chosen. All samples in this data set were processed at the Geoanalytical Laboratories at the Saskatchewan Research Council (SRC) in Saskatoon, Saskatchewan, an ISO/IEC 17025:2005 certified facility (i.e., meets the General Requirements for the Competence of Mineral Testing and Calibration Laboratories). Samples were crushed, split, agate ground, and then run with Sandstone Exploration Package ICPMS 1. The package produces three separate analysis types: inductively coupled plasma mass spectroscopy (ICP MS) partial digestion for trace elements; ICP MS total digestion for trace elements; and ICP–Optical Emission Spectrometry (ICP–OES) total digestion for major and minor elements. Details and detection limits are available on the SRC’s website. ICP total digestion: a 0.250 g pulp is gently heated in a mixture of ultrapure HF/HNO3/HClO4until dry and the residue dissolved in dilute ultrapure HNO3; ICP MS total digestion: a 0.250 g pulp is gently heated in a mixture of ultrapure HF/HNO3/HClO4until dry and the residue dissolved in dilute ultrapure HNO3; ICP MS partial digestion: a 2.00 g pulp is digested with 2.25 ml of 8:1 ultrapure HNO3:HCl for 1 hour at 95° C; Detection limits are from the SRC's 2011 Analytical Fee Schedule; null values indicate that elements are below the detection limit. NOTE: Attribute data headings ending with TD indicate Total Digestion, those ending with PD indicate Partial Digestion. Majors oxides are in percent; all other elements are in ppm.**Please Note – All published Saskatchewan Geological Survey datasets, including those available through the Saskatchewan Mining and Petroleum GeoAtlas, are sourced from the Enterprise GIS Data Warehouse. They are therefore identical and share the same refresh schedule.