About Gratings Incorporated
Gratings Incorporated specializes in the integration of nanostructures for renewable energy applications within the solar energy sector. The company offers products and services that include the development of c-Si based renewable energy technologies and LabVIEW-based characterization tools. Gratings Incorporated primarily serves sectors that require advanced solar cell technology and renewable energy microgrids. It is based in Albuquerque, New Mexico.
Expert Collections containing Gratings Incorporated
Expert Collections are analyst-curated lists that highlight the companies you need to know in the most important technology spaces.
Gratings Incorporated is included in 2 Expert Collections, including Renewable Energy.
Companies in the Renewable Energy space, including solar, wind, hydro, geothermal, and nuclear energy providers, as well as related software developers.
Semiconductors, Chips, and Advanced Electronics
Companies in the semiconductors & HPC space, including integrated device manufacturers (IDMs), fabless firms, semiconductor production equipment manufacturers, electronic design automation (EDA), advanced semiconductor material companies, and more
Latest Gratings Incorporated News
Nov 11, 2020
Market Overview The Pressure Locked Gratings report provides a detailed analysis of global market size, regional and country-level market size, segmentation market growth, market share, competitive Landscape, sales analysis, impact of domestic and global market players, value chain optimization, trade regulations, recent developments, opportunities analysis, strategic market growth analysis, product launches, area marketplace expanding, and technological innovations. The global Pressure Locked Gratings market size is expected to gain market growth in the forecast period of 2020 to 2025, with a CAGR of XX%% in the forecast period of 2020 to 2025 and will expected to reach USD XX million by 2025, from USD XX million in 2019. Market segmentation Pressure Locked Gratings is split by Type and by Application. For the period 2015-2025, the growth among segments provide accurate calculations and forecasts for sales by Type and by Application in terms of volume and value. This analysis can help you expand your business by targeting qualified niche markets. AMICO Regions and Countries Level Analysis Regional analysis is another highly comprehensive part of the research and analysis study of the global Pressure Locked Gratings is presented in the report. This section sheds light on the sales growth of different regional and country-level Exchangeable Tip Drills. For the historical and forecast period 2015 to 2025, it provides detailed and accurate country-wise volume analysis and region-wise market size analysis of the global Exchangeable Tip Drill. The report offers in-depth assessment of the growth and other aspects of the Pressure Locked Gratings is in important countries (regions), including United States, Canada, Mexico, Germany, France, United Kingdom, Russia, Italy, China, Japan, Korea, India, Southeast Asia, Australia, Brazil and Saudi Arabia, etc. It also throws light on the progress of key regional Exchangeable Tip Drills such as North America, Europe, Asia-Pacific, South America and Middle East & Africa. Competitive Landscape and Pressure Locked Gratings is Share Analysis Pea Starch Concentrate competitive landscape provides details by vendors, including company overview, company total revenue (financials), market potential, global presence,Pressure Locked Gratings is Concentrate sales and revenue generated, market share, price, production sites and facilities, SWOT analysis, product launch. For the period 2015-2020, this study provides the Pressure Locked Gratings is Concentrate sales, revenue and market share for each player covered in this report. Customization Service of the Report : Global Info Research provides customization of reports as per your need. This report can be personalized to meet your requirements. Get in touch with our sales team, who will guarantee you to get a report that suits your necessities. About Us: GlobaI Info Research（GIR） is a report publisher, a customer, interest-based suppliers. Is in the best interests of our clients, they determine our every move. At the same time, we have great respect for the views of customers. With the improvement of the quality of our research, we develop custom interdisciplinary and comprehensive solution. For further development, we will do better and better. Global Info Research will with excellent professional knowledge and experience to carry out all aspects of our business. At the same time, we will thoroughly look for information, to give a more comprehensive development.
Gratings Incorporated Frequently Asked Questions (FAQ)
Where is Gratings Incorporated's headquarters?
Gratings Incorporated's headquarters is located at 2700b Broadbent Pkwy Ne, Albuquerque.
What is Gratings Incorporated's latest funding round?
Gratings Incorporated's latest funding round is Grant.
How much did Gratings Incorporated raise?
Gratings Incorporated raised a total of $150K.
Who are the investors of Gratings Incorporated?
Investors of Gratings Incorporated include National Science Foundation.
Who are Gratings Incorporated's competitors?
Competitors of Gratings Incorporated include Bossa Nova Vision, Accustrata, Tisol, Jem Enterprises, Meridian Deployment Corporation and 7 more.
Compare Gratings Incorporated to Competitors
MVSystems is a provider of thin film deposition systems and technology for the semiconductor industry. The company designs and manufactures ultra-high vacuum deposition systems for research and development, prototype production, and small production lines, with a focus on ensuring high-quality opto-electronic properties of thin films. MVSystems' products are utilized in the creation of semiconductors, with an emphasis on amorphous and nanocrystalline silicon, dielectrics, and transparent conductive oxides. It is based in Golden, Colorado.
Anteos is a company that received a SBIR Phase II grant for a project entitled: Relief-Free Infrared Diffractive Optics Based on Semiconductor Materials. Their award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5) and their project will develop a new generation of relief-free thin-plate components of diffractive optics operating in the infrared region of spectrum. The diffractive optics employs volume phase holographic structures, which are optically recorded in semiconductor materials transparent at the infrared wavelengths using proprietary process of photo-modification for producing dramatic change of the material refractive index under illumination with low intensity light. Phase I of this project proved feasibility of the proposed concept by demonstrating photo modification of ZnSe infrared material and fabricating the first model components. The developed technology can be immediately applied to fabrication of diffractive optics, volume phase holographic gratings, and phase retardation plates for wavelengths up to 1.9 m, as well as antireflection layers for wavelengths up to 8 m. In Phase II project the technology will be optimized and applied to fabrication of the prototype components of infrared diffractive optics operating at longer wavelengths, including the important wavelength of CO2 laser 10.6 m and windows of atmospheric transparency 3-5 and 8-12 m. The developed photo-modification process is highly adaptable and creates a rich technology platform for fabrication of a broad range of products for a large variety of markets. Successful implementation of this technology will result in a new generation of high efficiency relief-free infrared diffractive optics and sub-wavelength components, including diffraction gratings, beam splitters, beam shapers, semiconductor materials with artificial birefringence, phase retardation plates and wave plates. The relief-free components of infrared diffractive optics based on semiconductor materials are capable to withstand high light intensities and perform complicated light management functions. Another important application is the fabrication of highly stable anti-reflection (AR) layers on infrared semiconductor optics. The market for infrared diffractive optics includes defense and airspace industry, laser industry, spectral devices, sensors and detectors, night vision optics, industrial process control, material processing, cutting and welding, environmental monitoring, medical diagnostics and surgery. Anteos is a company that received a SBIR Phase II grant for a project entitled: High-Efficiency Nanocomposite Photovoltaics and Solar Cells. Their project is focused on development of an innovative technology for fabrication of high-efficiency thin film nanocomposite photovoltaic materials and solar cells taking advantage of the recently discovered effect of carrier multiplication in semiconductor nanocrystals. The proposed concept employs smart design of the solar cells providing fast and effective spatial separation of electrons and holes photo-generated in the nanocrystals. The proposed reach nanotechnology platform solves the challenging problem of electrical communications with nanoscale objects, such as nanocrystals, nanorods, nanowires, nanotubes, etc. It can be employed for development of many other nanocomposite optoelectronic devices having numerous commercial and military applications. If successful the development of new generation of high-efficiency photovoltaic materials and solar cells based on the demonstrated technology will have broad impact on the entire solar energy industry resulting in considerable energy savings and environmental protection. The technology has great commercialization potential and niche market. The proposed all-inorganic, high-efficiency, thin film, flexible nanostructured photovoltaic materials and solar cells, which can operate in extreme environment conditions and offer significant mass and volume savings, are ideally suitable for numerous applications, including power generating residential rooftops, power supplies for utility grid, emergency signals and telephones, water pumps, activate switches, battery chargers, residential and commercial lighting, etc.
Jem Enterprises is a company that received a SBIR Phase I grant for a project entitled: Tin(II) Sulfide Photovoltaics. Their project aims to develop photovoltaic devices based on tin (II) sulfide (SnS). The properties of SnS, including bandgaps, carrier density and mobility, chemical and thermal stability, and metallurgical properties, promise the possibility to achieve relatively high conversion efficiency given state-of-art process control and device design. In this project, close space sublimation (CSS) technique, a thin film fabrication method proven for low cost and high manufacturability, will be used to synthesize SnS. The broader/commercial impact of this project will be the potential to produce photovoltaic devices based on low-cost and environmentally-friendly materials. There is no doubt that solar electricity has attracted a lot of attention in recent years as an alternative and renewable energy source. However, most of the current solar cell technologies have one or more of the following issues that, (1) raw materials are not abundantly available; (2) toxic materials are used; (3) overall cost is high. This project will address these issues by developing photovoltaic devices using SnS, a semiconductor material that can be supplied on a massive scale and at low recovery costs.
Isosceles is a company that received a STTR Phase I grant for a project entitled: Full Spectrum Conjugated Polymers for Highly Efficient Organic Photovoltaics. Their their award is funded under the American Recovery and Reinvestment Act of 2009 and their project will demonstrate the feasibility of forming full spectrum highly efficient polymer solar cells from newly designed conjugated and potentially variable bandgap polymers that harvest visible through infrared light. The novel materials will be forged by incorporating Silole and donor-acceptor-donor moieties into the backbone and are expected to increase light harvesting and carrier mobility, and hence short circuit current output potentially by a factor of three over the state of the art. The key innovations of this work will also optimize energy levels to reduce voltage loss and further optimization of device structure and film morphology is expected improve fill factor. The primary objective of phase I is to determine the feasibility of forging full spectrum and high carrier mobility conjugated polymers that achieve highly efficient solar conversion. An ancillary goal of this work is arrive at an understanding of photophysical processes and device physics that will lead to optimal device fabrication during phase II. The environmental, societal and economic impacts of this technology are enormously broad. The ensuing abrupt drop in energy costs stemming from full spectrum harvesting promises to deliver stability and urgently needed relief to today's volatile oil based global economy. While photovoltaic (PV) production is already the fastest growing source of energy across the globe, the planned efforts of this STTR project are expected to disruptively reduce the projected cost of photovoltaic production in 2010 by a factor of 3. At a forecasted production cost of $0.70 per Watt, this research will demonstrate a technology that is competitive with the cost of electricity that is produced from fossil fuels. This technology will provide clean and cost competitive energy for home and industrial power, vehicle propulsion, consumer electronics, remote sensing, security, and an endless list of existing applications that currently rely on energy from fossil fuel.
Silicon Photonics Group is a company that received a STTR Phase I grant for a project entitled: Advanced Si-Ge-Sn-based Photonic Materials and Devices. Their research project aims to demonstrate prototype infrared light detectors and photovoltaic (solar cell) devices based on technology developed at Arizona State University. The new technology to be explored consists in growing optical-quality alloys of tin and germanium (Ge1-ySny) directly on silicon wafers. These alloys act as infrared materials, and they can also be used as templates for the subsequent growth of other semiconductors on silicon. Of particular interest for this project is the ternary alloy Ge1-x-ySixSny, grown for the first time at Arizona State University. Using this technology, it should be possible to build infrared detectors covering a spectral range previously inaccessible to silicon-based detectors, and to build multijunction photovoltaic devices for a more efficient capture of solar photons. The fabrication of semiconductor devices on cheap silicon wafers is of great significance because of the potentially enormous cost reductions and the possibility of integrating optoelectronic and microelectronic functions, which further reduces costs and contributes to system miniaturization. The infrared detectors proposed here cover the so-called telecom C-,L-, and U-bands within the wavelength window around 1500 nm, a region of great interest to the telecommunications industry. In the photovoltaics arena, the proposed devices have the potential to offer increased efficiencies to make crystalline silicon-based devices competitive with amorphous silicon solutions.
Solarno Incorporated is an early-stage technology development company, focusing on the commercialization of emerging nanotechnologies in the solar energy sector. The company's main offerings include the development of nanomaterials for solar water heater systems, advanced solar cells devices, high energy density supercapacitors, and lighting solutions. Solarno primarily sells to the renewable energy industry. It is based in Coppell, Texas.