carbon discovery,its properties and uses

Carbon

Carbon is a chemical element with the symbol C and atomic number 6. It is a non-metallic element and is the fourth most abundant element in the universe by mass. Carbon is an essential element for life, as it forms the basis of all organic molecules, including proteins, carbohydrates, and nucleic acids. It can also form many other important compounds, such as carbon dioxide, carbon monoxide, and methane. Carbon is found in a variety of forms, including graphite, diamond, charcoal, and fullerene. It is also a key component in many industrial processes, including steel production, petroleum refining, and the manufacture of plastics and other synthetic materials. - Carbon has six electrons, with two electrons in the first shell and four electrons in the second shell. It has four valence electrons, which make it a versatile element for forming bonds with other elements. - Carbon has three naturally occurring isotopes: carbon-12, carbon-13, and carbon-14. Carbon-12 is the most common isotope, making up about 98.9% of all carbon. Carbon-14 is radioactive and is used in carbon dating to determine the age of ancient objects. - Carbon can exist in several allotropes, which are different forms of the same element. The most well-known allotropes of carbon are diamond and graphite. Diamond is a transparent, extremely hard substance, while graphite is a soft, black material that is commonly used in pencils. Other allotropes of carbon include fullerenes, carbon nanotubes, and graphene. - Carbon is a crucial component in the Earth's carbon cycle, which involves the exchange of carbon between the atmosphere, oceans, and biosphere. Carbon dioxide is a greenhouse gas that plays a significant role in regulating the Earth's temperature and climate. - Human activities, such as burning fossil fuels and deforestation, have increased the amount of carbon dioxide in the atmosphere, leading to concerns about climate change and global warming. - Carbon is used in a wide range of applications, including in the production of steel, as a fuel source in the form of coal, oil, and natural gas, and in the manufacturing of various consumer products such as plastics, rubber, and textiles. - Carbon is a key element in the chemistry of life. Organic compounds such as carbohydrates, lipids, proteins, and nucleic acids all contain carbon atoms in their structure. Carbon's ability to form a large number of covalent bonds with other atoms allows for the formation of complex molecules necessary for life. - Carbon can form double and triple bonds with other elements, which gives it a high degree of chemical reactivity. This makes it useful in a variety of industrial applications, such as in the production of fertilizers, plastics, and pharmaceuticals. - Carbon is found in many minerals, including limestone, marble, and graphite. It is also found in the Earth's crust in the form of coal, oil, and natural gas. - Carbon can be transformed into other useful materials through a process called  carbonization . This involves heating carbon-rich materials such as wood, coal, or bones in the absence of air to produce char, which can be used as a fuel or a source of carbon for other applications. - Carbon can also be used as an electrode in batteries and fuel cells, due to its ability to store and release electrons. - Carbon is an important element in the study of chemistry and materials science, and is the subject of ongoing research in fields such as nanotechnology and materials engineering

Discovery of carbon

Carbon is an element that has been known since ancient times, as it is found in abundance in nature and is a key component of many organic compounds. The discovery of carbon, therefore, cannot be attributed to a single individual or event. However, the concept of carbon as an element with its own unique properties and atomic structure emerged gradually over several centuries through the work of many scientists. The ancient Greeks and Romans were familiar with carbon in the form of charcoal, which was used for fuel and as a writing material. In the 18th century, chemists such as Antoine Lavoisier and Joseph Black began to study the properties of carbon more systematically. Lavoisier was the first to recognize carbon as an element, and he named it "carbon" based on its abundance in organic compounds.

Properties

- Allotropy: Carbon exists in several allotropes, including diamond, graphite, and fullerenes, each with its own distinct properties. - Solid at room temperature: Carbon is a solid at room temperature and standard pressure. - High melting and boiling points: Carbon has a high melting point of 3,550 °C and a boiling point of 4,827 °C. - Electrical conductivity: Graphite is an excellent conductor of electricity due to its unique crystal structure. - Non-metallic: Carbon is classified as a non-metal, meaning it lacks metallic properties such as luster, malleability, and ductility. - Covalent bonding: Carbon is known for its ability to form covalent bonds with other elements, including itself, resulting in a wide range of organic and inorganic compounds. - Strong chemical bonds: Carbon forms strong covalent bonds with other carbon atoms, giving rise to the stability and strength of organic compounds. - Versatility: Carbon is a key component of all known life on Earth and is found in a wide range of organic compounds, including carbohydrates, proteins, and nucleic acids. - Refractory: Diamond, one of the allotropes of carbon, is extremely hard and refractory, making it useful in cutting and drilling tools, as well as in electronic and optical applications. - Adsorption: Activated carbon, a form of carbon with a large surface area, is used for adsorption and purification in a wide range of applications, including air and water purification, gas separation, and catalysis. Uses Carbon is a widely used element with numerous applications in different fields. Some of the most common uses of carbon are: - Fuel: Carbon is an important component of fossil fuels such as coal, oil, and natural gas, which are used for heating, electricity generation, and transportation. - Steel production: Carbon is added to iron to produce steel, which is used in construction, transportation, and manufacturing. - Carbon fibers: Carbon fibers are used in the production of lightweight, high-strength materials for use in aerospace, automotive, and sporting goods applications. - Batteries: Carbon is used as an electrode material in batteries, such as lithium-ion batteries, due to its high electrical conductivity. - Water purification: Activated carbon is used in water treatment to remove impurities and contaminants from drinking water. - Air purification: Carbon is used in air filters to remove pollutants and impurities from the air. - Carbon dating: The radioactive isotope carbon-14 is used to determine the age of fossils, archaeological artifacts, and other organic materials. - Medical applications: Carbon is used in medical applications such as implants, dental fillings, and surgical instruments due to its biocompatibility and corrosion resistance. - Electronics: Carbon is used in the production of electronic components, such as resistors and capacitors. - Carbon black: Carbon black, a form of elemental carbon, is used as a pigment in inks, paints, and coatings, as well as in the production of rubber products such as tires. Carbon footprint Carbon footprint is a term used to describe the total amount of greenhouse gases (GHG), primarily carbon dioxide, emitted by an individual, organization, product or activity. It is a measure of the impact that human activities have on the environment in terms of their contribution to climate change. The carbon footprint is usually measured in tons of CO2 equivalent, which takes into account the global warming potential of other GHG such as methane and nitrous oxide. There are two main types of carbon footprint: direct and indirect. Direct carbon footprint refers to the emissions produced by activities that an individual or organization directly controls, such as heating a building or driving a car. Indirect carbon footprint refers to the emissions associated with the production and consumption of goods and services that an individual or organization uses, such as the emissions produced during the manufacturing of a product. Reducing carbon footprint has become a key issue in mitigating climate change, and various methods are being used to reduce it. These include adopting more energy-efficient practices, using renewable energy sources, reducing waste, and encouraging sustainable lifestyles. Governments and organizations around the world have also implemented carbon pricing and carbon trading schemes to incentivize reduction of GHG emissions. Carbon sequestration Carbon sequestration is the process of capturing and storing carbon dioxide (CO2) from the atmosphere in a long-term storage location, such as underground geological formations, oceans, or forests. This process helps to mitigate the impact of greenhouse gas emissions on the environment by removing carbon dioxide from the atmosphere. There are several different methods of carbon sequestration, including: - Geological sequestration: This method involves injecting carbon dioxide into deep underground geological formations, such as depleted oil and gas reservoirs or saline aquifers, where it can be stored for thousands of years. - Ocean sequestration: This method involves injecting carbon dioxide into the deep ocean, where it can dissolve and be stored for centuries. - Terrestrial sequestration: This method involves using plants and trees to absorb carbon dioxide from the atmosphere through photosynthesis and store it in the soil and biomass. This can be done through reforestation, afforestation, and sustainable land management practices. Carbon sequestration is an important strategy for mitigating climate change, and research is ongoing to develop and improve the technology and methods involved. However, it is important to note that carbon sequestration alone is not a substitute for reducing greenhouse gas emissions, which is essential in addressing climate change. Carbon emissions Carbon emissions refer to the release of carbon dioxide (CO2) and other greenhouse gases (GHGs) into the atmosphere as a result of human activities, such as burning fossil fuels, deforestation, and industrial processes. These emissions contribute to the greenhouse effect, which traps heat in the Earth's atmosphere and leads to global warming and climate change. Carbon emissions are a major environmental and social concern, as the effects of climate change can include rising sea levels, more frequent and severe natural disasters, food and water shortages, and other significant impacts on human health and wellbeing. Efforts to reduce carbon emissions have become a global priority, and there are many strategies being employed to achieve this goal. These include: - Transitioning to clean and renewable energy sources such as solar, wind, and hydropower. - Implementing energy efficiency measures to reduce the amount of energy used in buildings, transportation, and industry. - Promoting sustainable land use practices, such as reforestation and reducing deforestation. - Encouraging the adoption of low-carbon transportation options, such as public transit, cycling, and electric vehicles. - Introducing carbon pricing and cap-and-trade systems, which create economic incentives for reducing emissions. - Promoting awareness and education about the impact of carbon emissions and climate change, and encouraging individual action to reduce emissions. Reducing carbon emissions is a complex challenge that requires collective action at the individual, local, national, and global levels. Carbon cycle The carbon cycle refers to the movement of carbon atoms between living and non-living components of the Earth's system, including the atmosphere, oceans, land, and living organisms. Carbon is an essential element for life and is constantly being cycled through different forms and locations. The carbon cycle can be broken down into several main processes: - Photosynthesis: Carbon dioxide is absorbed by plants during photosynthesis, where it is converted into organic compounds, such as sugars and carbohydrates. - Respiration: Both plants and animals release carbon dioxide back into the atmosphere through respiration, as they convert organic compounds into energy. - Decomposition: When organisms die, their bodies decompose and release carbon back into the soil or atmosphere. - Fossil fuel formation: Organic matter that is not decomposed over time can become fossil fuels, such as coal, oil, and natural gas. - Combustion: Burning of fossil fuels and other organic matter releases carbon dioxide back into the atmosphere. - Ocean uptake: The oceans absorb and release carbon dioxide through processes such as photosynthesis and dissolution. - Weathering and erosion: Carbon is released from rocks and soil through weathering and erosion processes, which can lead to the formation of new rocks and minerals that store carbon. The carbon cycle is an important natural process that helps regulate the Earth's climate and maintain the balance of atmospheric carbon dioxide. However, human activities, such as the burning of fossil fuels and deforestation, have significantly disrupted the carbon cycle, leading to an increase in atmospheric carbon dioxide levels and contributing to climate change. Carbon storage Carbon storage refers to the process of storing carbon in various forms and locations, such as in forests, soils, and geological formations, in order to mitigate greenhouse gas emissions and combat climate change. Carbon storage can be achieved through natural or artificial means. Natural carbon storage occurs through processes such as photosynthesis, which converts atmospheric carbon dioxide into organic compounds in plants and trees, and the decomposition of organic matter, which returns carbon to the soil. Forests and other natural ecosystems are important carbon storage sinks, as they can store significant amounts of carbon in their biomass and soils. Artificial carbon storage, also known as carbon capture and storage (CCS), involves capturing carbon dioxide emissions from industrial processes and storing them in geological formations, such as depleted oil and gas reservoirs, saline aquifers, or deep ocean sediments. CCS is an important strategy for reducing carbon emissions from industrial sources, such as power plants and factories. Another form of carbon storage is carbon sequestration, which involves capturing carbon dioxide from the atmosphere and storing it in long-term storage locations, such as geological formations or forests. This process can be achieved through methods such as afforestation, reforestation, and sustainable land management practices. Carbon storage is an important strategy for mitigating the impacts of climate change, as it helps to reduce the amount of carbon dioxide in the atmosphere and slow the rate of global warming. However, it is important to note that carbon storage alone is not a substitute for reducing greenhouse gas emissions, which is essential in addressing climate change. Carbon capture and storage Carbon capture and storage (CCS) is a process that involves capturing carbon dioxide (CO2) emissions from industrial and energy production processes, transporting them to storage locations, and storing them in deep underground geological formations or other long-term storage facilities. CCS is considered a critical technology for reducing greenhouse gas emissions and mitigating climate change. The CCS process typically involves the following steps: - Capture: Carbon dioxide emissions are captured from industrial and energy production processes using technologies such as absorption, adsorption, or membrane separation. - Transport: The captured carbon dioxide is transported via pipeline, ship, or truck to storage locations. - Storage: The carbon dioxide is stored in geological formations such as depleted oil and gas reservoirs, deep saline aquifers, or unmineable coal seams. Alternatively, the carbon dioxide can be used for enhanced oil recovery (EOR), where it is injected into oil reservoirs to increase production. CCS has the potential to reduce greenhouse gas emissions from industrial and energy production processes by up to 90%, making it an important strategy for mitigating climate change. However, there are several challenges associated with CCS, including the high cost of capture and storage, the need for extensive infrastructure, and potential risks associated with the storage process, such as leakage. Despite these challenges, there are several large-scale CCS projects in operation around the world, including the Sleipner project in Norway and the Petra Nova project in the United States. Additionally, research is ongoing to develop new and more efficient CCS technologies, including direct air capture and utilization of CO2 as a feedstock for industrial processes. Carbon pricing Carbon pricing refers to a policy tool that puts a price on greenhouse gas emissions, such as carbon dioxide, in order to incentivize individuals and businesses to reduce their carbon footprint and mitigate climate change. Carbon pricing is typically implemented through a carbon tax or a cap-and-trade system. A carbon tax is a direct tax on carbon emissions, where emitters are required to pay a fee for each unit of carbon they produce. The tax is typically based on the amount of carbon dioxide emitted, with higher fees applied to more carbon-intensive activities. The goal of a carbon tax is to encourage individuals and businesses to reduce their carbon emissions by increasing the cost of emitting carbon. A cap-and-trade system, on the other hand, sets a cap on the total amount of carbon emissions allowed in a given jurisdiction, such as a country or region. Emissions permits are then issued to emitters, which can be bought and sold on a carbon market. Emitters that reduce their emissions below their allotted permits can sell their excess permits to other emitters that exceed their allotment. The goal of a cap-and-trade system is to incentivize emitters to reduce their emissions in order to stay below the emissions cap, while providing flexibility for emitters to buy and sell permits. Carbon pricing is considered an effective tool for reducing greenhouse gas emissions, as it provides a clear financial incentive for individuals and businesses to reduce their carbon footprint. However, carbon pricing policies can be controversial, as they can increase costs for consumers and businesses and may disproportionately affect low-income households. Read the full article

Fullerene Nanotubes Market – Global Industry Analysis and Forecast (2022-2028) – By Type, Material, Application, Industry and Region.

Fullerene Nanotubes Market – Global Industry Analysis and Forecast (2022-2028) – By Type, Material, Application, Industry and Region.

Report Summary The Fullerene Nanotubes market 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,…

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Fullerene Market Size, Share & Trends Analysis Report By Product, By Application, By Region And Segment Forecasts, 2019 – 2027

Market Synopsis

According to the MRFR analysis, the Global Fullerene Market is estimated to exhibit a CAGR of 15%

Fullerene is an allotropic form of carbon and is made of hollow cage structure. Fullerene finds a wide range of applications in cosmetics, renewable energy, automotive, electronics, and semiconductor industries. The wide application of fullerene is owing to its high antioxidant characteristic, unique molecular structure, biocompatibility, and anti-aging properties. Moreover, owing to its cage-like structure fullerene is used as a drug delivery mechanism. Endohedral fullerene is carbon fullerene having additional ions, atoms, or clusters enclosed within their inner spheres.

 Pricing and Regulatory Analysis

The Fullerene Market price varies from USD 50 to 80 per gram. The variation in price is associated with purity. The high cost of fullerene is attributed to expensive production methods and unavailability of bulk production method.

Currently, there are no regulations governing the production and use of fullerene. However, according to Globally Harmonized System of Classification and Labelling of Chemicals (GHZ) fullerene is classified as H228 (flammable solid) and H315-H319 (causes skin irritation and serious eye irritation).

 Segmentation

By Type

1.       C60: C60 fullerene is most widely used in cosmetics, pharmaceuticals, and semiconductor applications. The segment accounted for more than 60% share in 2018 and is projected to register highest growth owing to wide range of applications

2.       C70: It is mainly used as organic photovoltaics (OPV), catalysts and antioxidants. This segment is expected to witness high growth owing to increasing solar PV installations in China, India and the Middle East & African countries.

3.       Others: The others segment is expected to witness a moderate growth owing to niche applications in pharmaceuticals and cosmetics applications. This includes higher fullerenes such as C240, C540, and C720.

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 By Application

Pharmaceuticals: Largest application     segment and high growth owing to increasing usage in the pharmaceuticals     industry owing to its unique molecular structure, antioxidant effect, and     biological compatibility. Furthermore, the increasing use of fullerene for     cancer treatments and usage as a drug delivery system is expected to boost     the segment’s growth during the forecast period.

Cosmetics: The segment is expected to be     the fastest-growing in the market. Fullerene owing to its antioxidant     characteristics is used as an anti-aging and anti-damage agent in the     cosmetic sector. Owing to increasing disposable income, changing lifestyle     and rapid urbanization the cosmetic industry is witnessing a robust growth     thereby driving the growth of fullerene in the market. Moreover,     increasing demand for male grooming products particularly in emerging     market is surfacing new growth platform for the market during the forecast     period.

Renewable Energy: Increasing investment     in the development of renewable energy across the globe is driving the     growth of the segment. The use of fullerene as organic photovoltaic     materials help in high energy harvest in the solar photovoltaic units. The     Chinese government has set plans to install 105 GW of solar capacity by     2020, and the Indian Government has set a target to install 100 GW of     solar capacity to be achieved by 2022. Fullerene is also used PEM Fuel     Cell application to be used in automotive and portable power applications.     The robust growth of hydrogen fuel cell vehicle across the US and Europe     is also augmenting the market growth.

Electronics: In electronics industry     fullerene is used in the manufacturing of semiconductors and sensors.

Others: The segment includes catalysts,     water purification, and lubricants. The increasing research and     development in the fullerene market are expected to widen the scope of     application.

 By Region

North America: Market growth in the     region is driven by increasing investment in the medical field and well     established cosmetic and electronics industries.

Europe: The largest regional market.     Increasing research & development in the region is augmenting the     market growth.

Asia-Pacific: The fastest-growing     regional market, owing to booming cosmetic and pharmaceuticals industry in     countries such as China and India.

Latin America: The high growth of the     market is attributed to the booming cosmetic industry and economic growth.

Middle East & Africa: Growing     cosmetic industry and solar power installation in the region.

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Global Fullerene Market Size, Manufacturers, Supply Chain, Sales Channel and Clients, 2021-2027

A fullerene is a molecule of carbon in the form of a hollow sphere, ellipsoid, tube, and many other shapes. Spherical fullerenes, also referred to as Buckminsterfullerenes (buckyballs), resemble the balls used in football (soccer). Cylindrical fullerenes are also called carbon nanotubes (buckytubes). Fullerenes are similar in structure to graphite, which is composed of stacked graphene sheets of linked hexagonal rings; unless they are cylindrical, they must also contain pentagonal (or sometimes heptagonal) rings.

The players in Fullerene industry are concentrated in Japan and China, with USA and Europe also has some long history players. In terms of sales volume, Frontier Carbon Corporation VC60 and Nano-C are global leading players, with about 47% market shares.

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Market Analysis and Insights: Global Fullerene Market

In 2020, the global Fullerene market size was US$ 512.4 million and it is expected to reach US$ 796.9 million by the end of 2027, with a CAGR of 6.1% during 2021-2027.

Global Fullerene Scope and Market Size

Fullerene market is segmented by region, by country, company, type, application and by sales channels. Players, stakeholders, and other participants in the global Fullerene market will be able to gain the upper hand as they use the report as a powerful resource. The segmental analysis focuses on sales, revenue and forecast by region, by country, company, type, application and by sales channels for the period 2016-2027.

Segment by Type, the Fullerene market is segmented into

C60

C70

Others

Segment by Application, the Fullerene market is segmented into

Cosmetics

Pharmaceutical

Semiconductor & Electronics

Renewable Energy

Others

Regional and Country-level Analysis:

North America

United States

Canada

Asia-Pacific

China

Japan

South Korea

India

Southeast Asia

Australia

Rest of Asia-Pacific

Europe

Germany

France

U.K.

Italy

Russia

Nordic Countries

Rest of Europe

Latin America

Mexico

Brazil

Rest of Latin America

Middle East & Africa

Turkey

Saudi Arabia

UAE

Rest of MEA

Competitive Landscape and Fullerene Market Share Analysis

Fullerene market competitive landscape provides details and data information by companies. The report offers comprehensive analysis and accurate statistics on revenue by the player for the period 2016-2021. It also offers detailed analysis supported by reliable statistics on sale and revenue by players for the period 2016-2021. Details included are company description, major business, Fullerene product introduction, recent developments, Fullerene sales by region, type, application and by sales channel.

The major companies include:

VC60

Nano-C

Frontier Carbon Corporation

Solenne BV

MTR

BuckyUSA

EMFUTUR Technologies

MER Holdings

NeoTechProduct

Xiamen Funano

COCC

Suzhou Dade

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Table of content

1 Study Coverage 1.1 Fullerene Product Introduction 1.2 Market by Type 1.2.1 Global Fullerene Market Size Growth Rate by Type 1.2.2 C60 1.2.3 C70 1.2.4 Others 1.3 Market by Application 1.3.1 Global Fullerene Market Size Growth Rate by Application 1.3.2 Cosmetics 1.3.3 Pharmaceutical 1.3.4 Semiconductor & Electronics 1.3.5 Renewable Energy 1.3.6 Others 1.4 Study Objectives 1.5 Years Considered 2 Executive Summary 2.1 Global Fullerene Market Size Estimates and Forecasts 2.1.1 Global Fullerene Revenue 2016-2027 2.1.2 Global Fullerene Sales 2016-2027 2.2 Fullerene Market Size by Region: 2021 Versus 2027 2.3 Fullerene Sales by Region (2016-2027) 2.3.1 Global Fullerene Sales by Region: 2016-2021 2.3.2 Global Fullerene Sales Forecast by Region (2022-2027) 2.3.3 Global Fullerene Sales Market Share by Region (2016-2027) 2.4 Fullerene Market Estimates and Projections by Region (2022-2027) 2.4.1 Global Fullerene Revenue by Region: 2016-2021 2.4.2 Global Fullerene Revenue Forecast by Region (2022-2027) 2.4.3 Global Fullerene Revenue Market Share by Region (2016-2027) 3 Global Fullerene by Manufacturers 3.1 Global Top Fullerene Manufacturers by Sales 3.1.1 Global Fullerene Sales by Manufacturer (2016-2021) 3.1.2 Global Fullerene Sales Market Share by Manufa

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Nanomaterials In Batteries and Supercapacitors Market 2021 | Expecting Remarkable Growth Until 2026-Key Players

" A research study conducted on the Nanomaterials In Batteries and Supercapacitors market offers substantial information about market size and estimation, market share, growth, and product significance. The Nanomaterials In Batteries and Supercapacitors market report consists of a thorough analysis of the market which will help clients acquire Nanomaterials In Batteries and Supercapacitors market knowledge and use for business purposes. This report provides data to the customers that is of historical as well as statistical significance making it usefully informative. Crucial analysis done in this report also includes studies of the market dynamics, market segmentation and map positioning, market share, supply chain & Industry demand, challenges as well as threats and the competitive landscape. Business investors can acquire the quantitative and qualitative knowledge provided in the Nanomaterials In Batteries and Supercapacitors market report. >> Download FREE Research Sample with Industry Insights (150+ Pages PDF Report) @  

The major players involved in the Nanomaterials In Batteries and Supercapacitors market are:  Amprius Inc BAK Power BeDimensional Bodi Energy Dongxu Optoelectronic Technology Co., Ltd. HE3DA s.r.o. HPQ Silicon Resources Inc. Nexeon Sila Nanotechnologies Inc. Ray Techniques Ltd

Drivers responsible for the economic growth in the past, present, and future along with market volume, cost structure and potential growth factors provide an all-inclusive data of the Nanomaterials In Batteries and Supercapacitors market. Along with this, the Nanomaterials In Batteries and Supercapacitors market trends, and geographic dominance and regional segmentation forms the most significant part of the research study. These are the factors responsible for the anticipated growth of the Nanomaterials In Batteries and Supercapacitors market. However, regional segmentation specifies whether the USA, UK, China, or Europe will dominate the Nanomaterials In Batteries and Supercapacitors market in future. This report also includes an environmental perspective in that the growing concerns of imbalanced ecosystems, emergence of sustainability as key concerns in most of the industries and reducing waste. The Nanomaterials In Batteries and Supercapacitors market report includes data regarding how Nanomaterials In Batteries and Supercapacitors industries across the globe are adapting to more sustainable strategies for the benefit of the mankind. Also, special efforts taken by the Nanomaterials In Batteries and Supercapacitors industry to spread awareness by implementing strategies to the new world post pandemic are of great significance in this report. By the product type, the market is primarily split into: Graphene Carbon Nanotubes Fullerenes By the end-users/application, this report covers the following segments: Lithium-Sulfur Batteries Sodium-Ion Batteries Lithium-Air Batteries Nanomaterials In Batteries and Supercapacitors Market: Key Highlights of the Report for 2020-2026 ��� Compound Annual Growth Rate (CAGR) of the market in forecast years 2020-2026 is given. The data provided here about the Nanomaterials In Batteries and Supercapacitors market accurately determines the performance investments over a period of time. It helps the businesses drive their financial goals to fulfillment. • Detailed information on key factors that are expected to drive Nanomaterials In Batteries and Supercapacitors market growth during the next five to ten years is provided in the report. • Accurate market size estimates and the contribution of the parent market in the Nanomaterials In Batteries and Supercapacitors market share and size. • A detailed analysis of the upcoming trends, opportunities, threats, risks, and changes of consumer behavior towards the products and services. • Demographics of growth in the Nanomaterials In Batteries and Supercapacitors market across different countries in the geographical regions such as America, APAC, MEA, and Europe. • Information on the major vendors in the Nanomaterials In Batteries and Supercapacitors market and competitive analysis. • Comprehensive details of the vendors that drive the Nanomaterials In Batteries and Supercapacitors market. Geographical Segmentation and Competition Analysis – North America (U.S., Canada, Mexico) – Europe (U.K., France, Germany, Spain, Italy, Central & Eastern Europe, CIS) – Asia Pacific (China, Japan, South Korea, ASEAN, India, Rest of Asia Pacific) – Latin America (Brazil, Rest of L.A.) – Middle East and Africa (Turkey, GCC, Rest of Middle East) Report Highlights • Provides forecast trends for the year 2021-2027 for the Nanomaterials In Batteries and Supercapacitors market. • Net profit gained by leading enterprises in particular segments is highlighted in the study. • To study growth and productivity of the Nanomaterials In Batteries and Supercapacitors market companies. • Provides information on diversified ancillary activities involved in the Nanomaterials In Batteries and Supercapacitors market. • The demand for local goods and services in the Nanomaterials In Batteries and Supercapacitors market. • Public interventions regulating the Nanomaterials In Batteries and Supercapacitors market. • The study highlights the difficulties faced by producers and consumers to market the products and services in the Nanomaterials In Batteries and Supercapacitors industry. The report forecasts or predicts the future behavior or future trends of the Nanomaterials In Batteries and Supercapacitors market based on its productivity and growth factors. Strategies adopted the leading players for effective utilization and modernization of their existing resources for maximum profits is briefed in the study.

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Table of Contents Chapter One: Report Overview 1.1 Study Scope 1.2 Key Market Segments 1.3 Players Covered: Ranking by Nanomaterials In Batteries and Supercapacitors Revenue 1.4 Market Analysis by Type 1.4.1 Nanomaterials In Batteries and Supercapacitors Market Size Growth Rate by Type: 2020 VS 2026 1.5 Market by Application 1.5.1 Nanomaterials In Batteries and Supercapacitors Market Share by Application: 2020 VS 2026 1.6 Study Objectives 1.7 Years Considered Chapter Two: Growth Trends by Regions 2.1 Nanomaterials In Batteries and Supercapacitors Market Perspective (2015-2026) 2.2 Nanomaterials In Batteries and Supercapacitors Growth Trends by Regions 2.2.1 Nanomaterials In Batteries and Supercapacitors Market Size by Regions: 2015 VS 2020 VS 2026 2.2.2 Nanomaterials In Batteries and Supercapacitors Historic Market Share by Regions (2015-2020) 2.2.3 Nanomaterials In Batteries and Supercapacitors Forecasted Market Size by Regions (2021-2026) 2.3 Industry Trends and Growth Strategy 2.3.1 Market Top Trends 2.3.2 Market Drivers 2.3.3 Market Challenges 2.3.4 Porter’s Five Forces Analysis 2.3.5 Nanomaterials In Batteries and Supercapacitors Market Growth Strategy 2.3.6 Primary Interviews with Key Nanomaterials In Batteries and Supercapacitors Players (Opinion Leaders) Chapter Three: Competition Landscape by Key Players 3.1 Top Nanomaterials In Batteries and Supercapacitors Players by Market Size 3.1.1 Top Nanomaterials In Batteries and Supercapacitors Players by Revenue (2015-2020) 3.1.2 Nanomaterials In Batteries and Supercapacitors Revenue Market Share by Players (2015-2020) 3.1.3 Nanomaterials In Batteries and Supercapacitors Market Share by Company Type (Tier 1, Tier Chapter Two: and Tier 3) 3.2 Nanomaterials In Batteries and Supercapacitors Market Concentration Ratio 3.2.1 Nanomaterials In Batteries and Supercapacitors Market Concentration Ratio (CRChapter Five: and HHI) 3.2.2 Top Chapter Ten: and Top 5 Companies by Nanomaterials In Batteries and Supercapacitors Revenue in 2020 3.3 Nanomaterials In Batteries and Supercapacitors Key Players Head office and Area Served 3.4 Key Players Nanomaterials In Batteries and Supercapacitors Product Solution and Service 3.5 Date of Enter into Nanomaterials In Batteries and Supercapacitors Market 3.6 Mergers & Acquisitions, Expansion Plans Chapter Four: Research results and conclusion Chapter Five: Methodology and data source 5.1 Methodology / Research approach 5.2 Data source 5.3 List of authors 5.4 Disclaimer …… Chapter Six: Conclusion >> [With unrivaled insights into the Nanomaterials In Batteries and Supercapacitors market, our industry research will help you take your Nanomaterials In Batteries and Supercapacitors business to new heights.] <<

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Global Graphene Market -Strategic Recommendations, Trends, Segmentation, Use Case Analysis, Competitive Intelligence, Global And Regional Forecast (To 2027)

Graphene Market – Market Overview

Graphene is an allotrope of carbon having a single layer of carbon atoms arranged in hexagonal lattice form. It is the basic structural element of many other allotropes of carbon, such as graphite, charcoal, carbon nanotubes and fullerenes. Graphene is emerging as one of the most promising nanomaterial because of its unique combination of superb properties, which opens a way for its exploitation in a wide spectrum of applications ranging from electronics to optics, sensors, and bio devices. Graphene is technically a non-metal but is often referred to as a quasi-metal due to its properties being like that of a semi-conducting metal, which enable its application in electronics and energy sector.

According to the leading research organizations the global market for electronics products has grown at an average CAGR of about 13% per year from past five year. Growing demand for energy storage systems, rust free coating, printed electronics are some of the major driving factors operating into the market. In addition to this, increasing spending economic power of middle class population have led the greater adoption of electronic devices over the past five years. In addition to this, rapid industrialization fuelling the growth of automotive and aerospace sectors.

Growing use of the light weight vehicles in automotive industry is projected to boost growth of the market which is anticipated to continue in the coming years which may consolidate graphene demand. Increasing research & development activities along with growing focus on development of new products and technological innovation is expected to provide fuel the growth of this market over the forecast period. On the other hand, global market growth is held back by increasing environmental concern. However, the high price of manufacturing technology and equipment, along with technical limitations for commercial production are the major factors restricting the market growth. As per the study published by Market Research Future on graphene market, the trend for electronics industry is projected to drive demand for Graphene in the coming years.

Access Complete Report @ https://www.marketresearchfuture.com/reports/graphene-market-2987

market position. Growing manufacturing industries, and continuous collaborations and agreements between manufacturers, distributers, and marketing firms are key factors for the growth of graphene in the global market. Taking into account these trends, the global Graphene market is likely to witness considerable competition over the forecast period of 2017-2023.

Industry/ Innovation/ Related News:

August 17, 2016- Angstron Materials, Inc. and Gustav Grolman GmbH & Co KG entered into a pan-Europe distribution agreement for Angstron’s high performance graphene products. Angstron is the world’s largest producer of graphene nanomaterial with a production capacity of over 300 tpa. On the other hand the Grolman Group operates an international specialty chemical distribution business from a number of well renowned suppliers. This development is expected to boost sale of the product in this region.

September 29, 2016- Vorbeck has introduced Vor-flex™ Engineered HNBR Elastomer which is a Rubber Reinforced with Vor-x® Graphene. It is the first in a new family of graphene-enhanced, engineered elastomer products. Vor-flex exhibits high temperature stability, which allows it to serve in some of the most demanding environments, such as those found in automotive and petrochemical applications. This is likely to enhance the application scope of the Vorbeck graphene products.

September 13, 2016- Reliance Industries Ltd, one of Asia’s top petrochemical production companies, and Vorbeck Materials Corp., a leading producer of graphene and graphene-based products announced that they have signed a joint development agreement to develop graphene-enhanced synthetic elastomer products. This may help Vorbeck to expand its production pfacility Asia Pacific region and gain the advantage of grwoth in this region.

Key Players:

CVD Equipment Corporation (US), Vorbeck Materials (US), Graphene NanoChem (UK), XG Sciences, Inc. (US), Angstron Materials, Inc (US), Graphene Laboratories, Inc. (US), BGT Materials Limited, Ltd (UK), Graphenea Inc. (US), Grafoid Inc (North America), Haydale Limited (UK), and Others are some of the prominent players at the forefront of competition in the Global Graphene Market and are profiled in MRFR Analysis.

Graphene Market- Competitive Landscape

The global graphene is highly matured market driven by flourishing growth in aerospace & defence industry, along with the flourishing transportation sector.  CVD Equipment Corporation, Vorbeck Materials, Graphene NanoChem, XG Sciences, Inc., Angstron Materials, Inc, Graphene Laboratories, Inc. are the major shareholders in this market. Most of these market participants are adopting the expansion and collaboration tactic of their production capacities to strengthen their

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Graphene Market Global Size, Segments, Growth and Trends by Forecast to 2023

Graphene Market – Overview:

According to the leading research organizations the Global Graphene Market for electronics products has grown at an average CAGR of about 13% per year from past five year. Growing demand for energy storage systems, rust free coating, printed electronics are some of the major driving factors operating into the market. In addition to this, increasing spending economic power of middle-class population have led the greater adoption of electronic devices over the past five years. In addition to this, rapid industrialization fuelling the growth of automotive and aerospace sectors.

Graphene is an allotrope of carbon having a single layer of carbon atoms arranged in hexagonal lattice form. It is the basic structural element of many other allotropes of carbon, such as graphite, charcoal, carbon nanotubes and fullerenes. Graphene is emerging as one of the most promising nanomaterial because of its unique combination of superb properties, which opens a way for its exploitation in a wide spectrum of applications ranging from electronics to optics, sensors, and bio devices. Graphene is technically a non-metal but is often referred to as a quasi-metal due to its properties being like that of a semi-conducting metal, which enable its application in electronics and energy sector.

Growing use of the lightweight vehicles in automotive industry is projected to boost growth of the market which is anticipated to continue in the coming years which may consolidate graphene demand. Increasing research & development activities along with growing focus on development of new products and technological innovation is expected to provide fuel the growth of this market over the forecast period. On the other hand, global market growth is held back by increasing environmental concern. However, the high price of manufacturing technology and equipment, along with technical limitations for commercial production are the major factors restricting the market growth. As per the study published by Market Research Future on Graphene Market, the trend for electronics industry is projected to drive demand for Graphene in the coming years.

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Key Players:

CVD Equipment Corporation (US), Vorbeck Materials (US), Graphene NanoChem (UK), XG Sciences, Inc. (US), Angstron Materials, Inc (US), Graphene Laboratories, Inc. (US), BGT Materials Limited, Ltd (UK), Graphenea Inc. (US), Grafoid Inc (North America), Haydale Limited (UK), and Others are some of the prominent players at the forefront of competition in the Global Graphene Market and are profiled in MRFR Analysis.

Graphene Market - Competitive Landscape:

Global Graphene Market is highly matured market driven by flourishing growth in aerospace & defence industry, along with the flourishing transportation sector.  CVD Equipment Corporation, Vorbeck Materials, Graphene NanoChem, XG Sciences, Inc., Angstron Materials, Inc, Graphene Laboratories, Inc. are the major shareholders in this market. Most of these market participants are adopting the expansion and collaboration tactic of their production capacities to strengthen their market position. Growing manufacturing industries, and continuous collaborations and agreements between manufacturers, distributers, and marketing firms are key factors for the growth of graphene in the global market. Taking into account these trends, the Global Graphene market is likely to witness considerable competition over the forecast period of 2017-2023.

Industry/ Innovation/ Related News:

August 17, 2016- Angstron Materials, Inc. and Gustav Grolman GmbH & Co KG entered into a pan-Europe distribution agreement for Angstron’s high performance graphene products. Angstron is the world’s largest producer of graphene nanomaterial with a production capacity of over 300 tpa. On the other hand, the Grolman Group operates an international specialty chemical distribution business from a number of well renowned suppliers. This development is expected to boost sale of the product in this region.

Access Complete Report @ https://www.marketresearchfuture.com/reports/graphene-market-2987

September 29, 2016- Vorbeck has introduced Vor-flex™ Engineered HNBR Elastomer which is a Rubber Reinforced with Vor-x® Graphene. It is the first in a new family of graphene-enhanced, engineered elastomer products. Vor-flex exhibits high temperature stability, which allows it to serve in some of the most demanding environments, such as those found in automotive and petrochemical applications. This is likely to enhance the application scope of the Vorbeck graphene products.

September 13, 2016- Reliance Industries Ltd, one of Asia’s top petrochemical production companies, and Vorbeck Materials Corp., a leading producer of graphene and graphene-based products announced that they have signed a joint development agreement to develop graphene-enhanced synthetic elastomer products. This may help Vorbeck to expand its production pfacility Asia Pacific region and gain the advantage of grwoth in this region.

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Global Nanomaterials in Theranostics Market 2019 | Manufacturers In-Depth Analysis Report to 2024

The latest trending report Global Nanomaterials in Theranostics Market 2019-2024 added by DecisionDatabases.com

In the fabrication of nano-machines that can deliver their cargo (a drug) to a precise location (the tumor tissue of a specific organ) so that healthy tissues are minimally affected.

The worldwide market for Nanomaterials in Theranostics is expected to grow at a CAGR of roughly xx% over the next five years, will reach xx million US$ in 2024, from xx million US$ in 2019.

This report focuses on the Nanomaterials in Theranostics in global market, especially in North America, Europe and Asia-Pacific, South America, Middle East and Africa. This report categorizes the market based on manufacturers, regions, type and application.

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Market Segment by Manufacturers, this report covers

·          ACS Materials

·          Arkema

·          Nanocyl

·          NanoIntegris

·          Nanophase Technologies

Market Segment by Regions, regional analysis covers

·          North America (United States, Canada and Mexico)

·          Europe (Germany, France, UK, Russia and Italy)

·          Asia-Pacific (China, Japan, Korea, India and Southeast Asia)

·          South America (Brazil, Argentina, Colombia etc.)

·          Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa)

Market Segment by Type, covers

·          Fullerene C60

·          Carbon Nanotubes

·          Quantum Dots

·          Gold Nanoparticles

Market Segment by Applications, can be divided into

·          Diagnostic Applications

·          Imaging Applications

·          Therapeutic Applications

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There are 15 Chapters to deeply display the global Nanomaterials in Theranostics market.

Chapter 1, to describe Nanomaterials in Theranostics product scope, market overview, market opportunities, market driving force and market risks. Chapter 2, to profile the top manufacturers of Nanomaterials in Theranostics, with price, sales, revenue and global market share of Nanomaterials in Theranostics in 2017 and 2018. Chapter 3, the Nanomaterials in Theranostics competitive situation, sales, revenue and global market share of top manufacturers are analyzed emphatically by landscape contrast. Chapter 4, the Nanomaterials in Theranostics breakdown data are shown at the regional level, to show the sales, revenue and growth by regions, from 2014 to 2019. Chapter 5, 6, 7, 8 and 9, to break the sales data at the country level, with sales, revenue and market share for key countries in the world, from 2014 to 2019. Chapter 10 and 11, to segment the sales by type and application, with sales market share and growth rate by type, application, from 2014 to 2019. Chapter 12, Nanomaterials in Theranostics market forecast, by regions, type and application, with sales and revenue, from 2019 to 2024. Chapter 13, 14 and 15, to describe Nanomaterials in Theranostics sales channel, distributors, customers, research findings and conclusion, appendix and data source.

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carbon discovery,its properties and uses

Carbon

Carbon is a chemical element with the symbol C and atomic number 6. It is a non-metallic element and is the fourth most abundant element in the universe by mass. Carbon is an essential element for life, as it forms the basis of all organic molecules, including proteins, carbohydrates, and nucleic acids. It can also form many other important compounds, such as carbon dioxide, carbon monoxide, and methane. Carbon is found in a variety of forms, including graphite, diamond, charcoal, and fullerene. It is also a key component in many industrial processes, including steel production, petroleum refining, and the manufacture of plastics and other synthetic materials. - Carbon has six electrons, with two electrons in the first shell and four electrons in the second shell. It has four valence electrons, which make it a versatile element for forming bonds with other elements. - Carbon has three naturally occurring isotopes: carbon-12, carbon-13, and carbon-14. Carbon-12 is the most common isotope, making up about 98.9% of all carbon. Carbon-14 is radioactive and is used in carbon dating to determine the age of ancient objects. - Carbon can exist in several allotropes, which are different forms of the same element. The most well-known allotropes of carbon are diamond and graphite. Diamond is a transparent, extremely hard substance, while graphite is a soft, black material that is commonly used in pencils. Other allotropes of carbon include fullerenes, carbon nanotubes, and graphene. - Carbon is a crucial component in the Earth's carbon cycle, which involves the exchange of carbon between the atmosphere, oceans, and biosphere. Carbon dioxide is a greenhouse gas that plays a significant role in regulating the Earth's temperature and climate. - Human activities, such as burning fossil fuels and deforestation, have increased the amount of carbon dioxide in the atmosphere, leading to concerns about climate change and global warming. - Carbon is used in a wide range of applications, including in the production of steel, as a fuel source in the form of coal, oil, and natural gas, and in the manufacturing of various consumer products such as plastics, rubber, and textiles. - Carbon is a key element in the chemistry of life. Organic compounds such as carbohydrates, lipids, proteins, and nucleic acids all contain carbon atoms in their structure. Carbon's ability to form a large number of covalent bonds with other atoms allows for the formation of complex molecules necessary for life. - Carbon can form double and triple bonds with other elements, which gives it a high degree of chemical reactivity. This makes it useful in a variety of industrial applications, such as in the production of fertilizers, plastics, and pharmaceuticals. - Carbon is found in many minerals, including limestone, marble, and graphite. It is also found in the Earth's crust in the form of coal, oil, and natural gas. - Carbon can be transformed into other useful materials through a process called  carbonization . This involves heating carbon-rich materials such as wood, coal, or bones in the absence of air to produce char, which can be used as a fuel or a source of carbon for other applications. - Carbon can also be used as an electrode in batteries and fuel cells, due to its ability to store and release electrons. - Carbon is an important element in the study of chemistry and materials science, and is the subject of ongoing research in fields such as nanotechnology and materials engineering

Discovery of carbon

Carbon is an element that has been known since ancient times, as it is found in abundance in nature and is a key component of many organic compounds. The discovery of carbon, therefore, cannot be attributed to a single individual or event. However, the concept of carbon as an element with its own unique properties and atomic structure emerged gradually over several centuries through the work of many scientists. The ancient Greeks and Romans were familiar with carbon in the form of charcoal, which was used for fuel and as a writing material. In the 18th century, chemists such as Antoine Lavoisier and Joseph Black began to study the properties of carbon more systematically. Lavoisier was the first to recognize carbon as an element, and he named it "carbon" based on its abundance in organic compounds.

Properties

- Allotropy: Carbon exists in several allotropes, including diamond, graphite, and fullerenes, each with its own distinct properties. - Solid at room temperature: Carbon is a solid at room temperature and standard pressure. - High melting and boiling points: Carbon has a high melting point of 3,550 °C and a boiling point of 4,827 °C. - Electrical conductivity: Graphite is an excellent conductor of electricity due to its unique crystal structure. - Non-metallic: Carbon is classified as a non-metal, meaning it lacks metallic properties such as luster, malleability, and ductility. - Covalent bonding: Carbon is known for its ability to form covalent bonds with other elements, including itself, resulting in a wide range of organic and inorganic compounds. - Strong chemical bonds: Carbon forms strong covalent bonds with other carbon atoms, giving rise to the stability and strength of organic compounds. - Versatility: Carbon is a key component of all known life on Earth and is found in a wide range of organic compounds, including carbohydrates, proteins, and nucleic acids. - Refractory: Diamond, one of the allotropes of carbon, is extremely hard and refractory, making it useful in cutting and drilling tools, as well as in electronic and optical applications. - Adsorption: Activated carbon, a form of carbon with a large surface area, is used for adsorption and purification in a wide range of applications, including air and water purification, gas separation, and catalysis. Uses Carbon is a widely used element with numerous applications in different fields. Some of the most common uses of carbon are: - Fuel: Carbon is an important component of fossil fuels such as coal, oil, and natural gas, which are used for heating, electricity generation, and transportation. - Steel production: Carbon is added to iron to produce steel, which is used in construction, transportation, and manufacturing. - Carbon fibers: Carbon fibers are used in the production of lightweight, high-strength materials for use in aerospace, automotive, and sporting goods applications. - Batteries: Carbon is used as an electrode material in batteries, such as lithium-ion batteries, due to its high electrical conductivity. - Water purification: Activated carbon is used in water treatment to remove impurities and contaminants from drinking water. - Air purification: Carbon is used in air filters to remove pollutants and impurities from the air. - Carbon dating: The radioactive isotope carbon-14 is used to determine the age of fossils, archaeological artifacts, and other organic materials. - Medical applications: Carbon is used in medical applications such as implants, dental fillings, and surgical instruments due to its biocompatibility and corrosion resistance. - Electronics: Carbon is used in the production of electronic components, such as resistors and capacitors. - Carbon black: Carbon black, a form of elemental carbon, is used as a pigment in inks, paints, and coatings, as well as in the production of rubber products such as tires. Carbon footprint Carbon footprint is a term used to describe the total amount of greenhouse gases (GHG), primarily carbon dioxide, emitted by an individual, organization, product or activity. It is a measure of the impact that human activities have on the environment in terms of their contribution to climate change. The carbon footprint is usually measured in tons of CO2 equivalent, which takes into account the global warming potential of other GHG such as methane and nitrous oxide. There are two main types of carbon footprint: direct and indirect. Direct carbon footprint refers to the emissions produced by activities that an individual or organization directly controls, such as heating a building or driving a car. Indirect carbon footprint refers to the emissions associated with the production and consumption of goods and services that an individual or organization uses, such as the emissions produced during the manufacturing of a product. Reducing carbon footprint has become a key issue in mitigating climate change, and various methods are being used to reduce it. These include adopting more energy-efficient practices, using renewable energy sources, reducing waste, and encouraging sustainable lifestyles. Governments and organizations around the world have also implemented carbon pricing and carbon trading schemes to incentivize reduction of GHG emissions. Carbon sequestration Carbon sequestration is the process of capturing and storing carbon dioxide (CO2) from the atmosphere in a long-term storage location, such as underground geological formations, oceans, or forests. This process helps to mitigate the impact of greenhouse gas emissions on the environment by removing carbon dioxide from the atmosphere. There are several different methods of carbon sequestration, including: - Geological sequestration: This method involves injecting carbon dioxide into deep underground geological formations, such as depleted oil and gas reservoirs or saline aquifers, where it can be stored for thousands of years. - Ocean sequestration: This method involves injecting carbon dioxide into the deep ocean, where it can dissolve and be stored for centuries. - Terrestrial sequestration: This method involves using plants and trees to absorb carbon dioxide from the atmosphere through photosynthesis and store it in the soil and biomass. This can be done through reforestation, afforestation, and sustainable land management practices. Carbon sequestration is an important strategy for mitigating climate change, and research is ongoing to develop and improve the technology and methods involved. However, it is important to note that carbon sequestration alone is not a substitute for reducing greenhouse gas emissions, which is essential in addressing climate change. Carbon emissions Carbon emissions refer to the release of carbon dioxide (CO2) and other greenhouse gases (GHGs) into the atmosphere as a result of human activities, such as burning fossil fuels, deforestation, and industrial processes. These emissions contribute to the greenhouse effect, which traps heat in the Earth's atmosphere and leads to global warming and climate change. Carbon emissions are a major environmental and social concern, as the effects of climate change can include rising sea levels, more frequent and severe natural disasters, food and water shortages, and other significant impacts on human health and wellbeing. Efforts to reduce carbon emissions have become a global priority, and there are many strategies being employed to achieve this goal. These include: - Transitioning to clean and renewable energy sources such as solar, wind, and hydropower. - Implementing energy efficiency measures to reduce the amount of energy used in buildings, transportation, and industry. - Promoting sustainable land use practices, such as reforestation and reducing deforestation. - Encouraging the adoption of low-carbon transportation options, such as public transit, cycling, and electric vehicles. - Introducing carbon pricing and cap-and-trade systems, which create economic incentives for reducing emissions. - Promoting awareness and education about the impact of carbon emissions and climate change, and encouraging individual action to reduce emissions. Reducing carbon emissions is a complex challenge that requires collective action at the individual, local, national, and global levels. Carbon cycle The carbon cycle refers to the movement of carbon atoms between living and non-living components of the Earth's system, including the atmosphere, oceans, land, and living organisms. Carbon is an essential element for life and is constantly being cycled through different forms and locations. The carbon cycle can be broken down into several main processes: - Photosynthesis: Carbon dioxide is absorbed by plants during photosynthesis, where it is converted into organic compounds, such as sugars and carbohydrates. - Respiration: Both plants and animals release carbon dioxide back into the atmosphere through respiration, as they convert organic compounds into energy. - Decomposition: When organisms die, their bodies decompose and release carbon back into the soil or atmosphere. - Fossil fuel formation: Organic matter that is not decomposed over time can become fossil fuels, such as coal, oil, and natural gas. - Combustion: Burning of fossil fuels and other organic matter releases carbon dioxide back into the atmosphere. - Ocean uptake: The oceans absorb and release carbon dioxide through processes such as photosynthesis and dissolution. - Weathering and erosion: Carbon is released from rocks and soil through weathering and erosion processes, which can lead to the formation of new rocks and minerals that store carbon. The carbon cycle is an important natural process that helps regulate the Earth's climate and maintain the balance of atmospheric carbon dioxide. However, human activities, such as the burning of fossil fuels and deforestation, have significantly disrupted the carbon cycle, leading to an increase in atmospheric carbon dioxide levels and contributing to climate change. Carbon storage Carbon storage refers to the process of storing carbon in various forms and locations, such as in forests, soils, and geological formations, in order to mitigate greenhouse gas emissions and combat climate change. Carbon storage can be achieved through natural or artificial means. Natural carbon storage occurs through processes such as photosynthesis, which converts atmospheric carbon dioxide into organic compounds in plants and trees, and the decomposition of organic matter, which returns carbon to the soil. Forests and other natural ecosystems are important carbon storage sinks, as they can store significant amounts of carbon in their biomass and soils. Artificial carbon storage, also known as carbon capture and storage (CCS), involves capturing carbon dioxide emissions from industrial processes and storing them in geological formations, such as depleted oil and gas reservoirs, saline aquifers, or deep ocean sediments. CCS is an important strategy for reducing carbon emissions from industrial sources, such as power plants and factories. Another form of carbon storage is carbon sequestration, which involves capturing carbon dioxide from the atmosphere and storing it in long-term storage locations, such as geological formations or forests. This process can be achieved through methods such as afforestation, reforestation, and sustainable land management practices. Carbon storage is an important strategy for mitigating the impacts of climate change, as it helps to reduce the amount of carbon dioxide in the atmosphere and slow the rate of global warming. However, it is important to note that carbon storage alone is not a substitute for reducing greenhouse gas emissions, which is essential in addressing climate change. Carbon capture and storage Carbon capture and storage (CCS) is a process that involves capturing carbon dioxide (CO2) emissions from industrial and energy production processes, transporting them to storage locations, and storing them in deep underground geological formations or other long-term storage facilities. CCS is considered a critical technology for reducing greenhouse gas emissions and mitigating climate change. The CCS process typically involves the following steps: - Capture: Carbon dioxide emissions are captured from industrial and energy production processes using technologies such as absorption, adsorption, or membrane separation. - Transport: The captured carbon dioxide is transported via pipeline, ship, or truck to storage locations. - Storage: The carbon dioxide is stored in geological formations such as depleted oil and gas reservoirs, deep saline aquifers, or unmineable coal seams. Alternatively, the carbon dioxide can be used for enhanced oil recovery (EOR), where it is injected into oil reservoirs to increase production. CCS has the potential to reduce greenhouse gas emissions from industrial and energy production processes by up to 90%, making it an important strategy for mitigating climate change. However, there are several challenges associated with CCS, including the high cost of capture and storage, the need for extensive infrastructure, and potential risks associated with the storage process, such as leakage. Despite these challenges, there are several large-scale CCS projects in operation around the world, including the Sleipner project in Norway and the Petra Nova project in the United States. Additionally, research is ongoing to develop new and more efficient CCS technologies, including direct air capture and utilization of CO2 as a feedstock for industrial processes. Carbon pricing Carbon pricing refers to a policy tool that puts a price on greenhouse gas emissions, such as carbon dioxide, in order to incentivize individuals and businesses to reduce their carbon footprint and mitigate climate change. Carbon pricing is typically implemented through a carbon tax or a cap-and-trade system. A carbon tax is a direct tax on carbon emissions, where emitters are required to pay a fee for each unit of carbon they produce. The tax is typically based on the amount of carbon dioxide emitted, with higher fees applied to more carbon-intensive activities. The goal of a carbon tax is to encourage individuals and businesses to reduce their carbon emissions by increasing the cost of emitting carbon. A cap-and-trade system, on the other hand, sets a cap on the total amount of carbon emissions allowed in a given jurisdiction, such as a country or region. Emissions permits are then issued to emitters, which can be bought and sold on a carbon market. Emitters that reduce their emissions below their allotted permits can sell their excess permits to other emitters that exceed their allotment. The goal of a cap-and-trade system is to incentivize emitters to reduce their emissions in order to stay below the emissions cap, while providing flexibility for emitters to buy and sell permits. Carbon pricing is considered an effective tool for reducing greenhouse gas emissions, as it provides a clear financial incentive for individuals and businesses to reduce their carbon footprint. However, carbon pricing policies can be controversial, as they can increase costs for consumers and businesses and may disproportionately affect low-income households. Read the full article

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New Post has been published on http://engineer.city/shape-shifter/

Shape shifter

Carbon nanobuds offer vehicle interior designers new opportunities to take advantage of 3D-shaped smart surfaces with physical haptic technology, as Canatu’s CEO, Juha Kokkonen, explains

There is an ongoing evolution in automotive interiors where physical dials and switches are being replaced by displays and touch icons. The current solutions are 2D tablet-like displays that require a lot of focus when operating. However, there is a new nanomaterial available from Canatu, carbon nanobuds (CNBs), that enables 3D-shaped, smart touch surfaces. 3D shapes help users to find controls without looking and are tactile and can be found by fingers, which decreases driver distraction. Instead of 2D displays, the new kind of enhanced HMI design enables a 3D-shaped user interface, making the interior fully functional.

Due to the fact that there are no restrictions on the placement or form of functions, engineers can enjoy design freedom and create sleek interiors where controls are integrated seamlessly with the rest of the interior. Smart surfaces can flow from door panel to information panel, across centre consoles, or sweep the full width of the cockpit even up to the roof switches. This enables a living-room like space creation that will be dominant in the future of autonomous driving. A multipurpose interface, where there are several functions under one control, saves space compared to mechanical switches, which require separate controls for each function. Thanks to the software-based controls, the user interface can be personalised depending for example on driving mode or user profile. Also, over-the-air upgrades of functionalities will be possible after the initial setup, enabling the option for OEMs to offer advanced features after the initial purchase of the vehicle.

As CNB is carbon-based, it does not reflect or scatter light, and it has low haze. This is especially beneficial when thinking about the display readability. Carbon also enables true black and crisp images for displays.

The transparent and stretchable CNB film offers light weight with good optical properties. It can be used with plastic, glass and even leather and textiles. The 3D shapes can be added on top of displays, and the surface can be transparent or black with a decorative layer. The transparency allows the functions to be backlit, either continuously or only when needed, so remaining hidden until lit. Haptic feedback integrated into the functionalities increases the usability of the touch functions.

Autonomous driving in any weather

The material has very good electrical conductivity and it can also be used to heat up and keep Advanced Driver Assistance Systems (ADAS) sensors clear. Autonomous driving requires many kinds of sensors that collect information about the surroundings. Those sensors need to be fully functional whatever the weather to be reliable. However, currently in cold or humid conditions cameras and lidars can easily be blocked by snow, ice or fog.

Nowadays LED front lights are becoming the dominant choice in cars, but do not create heat, so also suffer in poor weather conditions. CNB-based 3D-shaped heaters can be seamlessly integrated to enable even heating of the surface without local hot spots.

The stretchable material can be thermoformed to any complicated shape and it can be either moulded or laminated directly to the surface enabling seamless body design as well as 360º or fish-eye views. The nanotubes and nanobuds fall in a curved and curled manner on the substrate and they slide over each other, enabling 200% stretchability and thermoforming with a 1mm radius.

CNB is a new nanocarbon allotrope discovered by the Technical University of Helsinki in 2008. It consists of a single wall carbon nanotube with covalently bonded c60-fullerene on the side. Just like its fellow nanocarbon allotropes graphene, carbon nanotubes and buckyballs, it has lots of extraordinary properties that could revolutionise many different industries.

It has taken several years to develop the manufacturing equipment and commercialise the nanobuds. The molecules are made in a special reactor, where carbon-based gases are introduced to a furnace at extreme temperatures. Inside the reactor the carbon breaks free and starts to form the CNBs. These are collected under the reactor and directly printed to the final substrate. This is called direct dry printing. The process, the synthesis and the carbon nanobud molecule itself are all patent-protected.

Juha Kokkonen is CEO at Canatu

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Source: engineerlive.com

Global Fullerene Market 2019 | Manufacturers In-Depth Analysis Report to 2024

The latest trending report Global Fullerene Market 2019-2024 added by DecisionDatabases.com

A fullerene is a molecule of carbon in the form of a hollow sphere, ellipsoid, tube, and many other shapes. Spherical fullerenes, also referred to as Buckminsterfullerenes (buckyballs), resemble the balls used in football (soccer). Cylindrical fullerenes are also called carbon nanotubes (buckytubes). Fullerenes are similar in structure to graphite, which is composed of stacked graphene sheets of linked hexagonal rings; unless they are cylindrical, they must also contain pentagonal (or sometimes heptagonal) rings.

The worldwide market for Fullerene is expected to grow at a CAGR of roughly xx% over the next five years, will reach xx million US$ in 2024, from xx million US$ in 2019.

This report focuses on the Fullerene in global market, especially in North America, Europe and Asia-Pacific, South America, Middle East and Africa. This report categorizes the market based on manufacturers, regions, type and application.

Browse the complete report and table of contents @ https://www.decisiondatabases.com/ip/25813-fullerene-market-analysis-report

Market Segment by Manufacturers, this report covers

 VC60

 Nano-C

 Frontier Carbon Corporation

 Solenne BV

 MTR

 BuckyUSA

 EMFUTUR Technologies

 MER Holdings

 NeoTechProduct

 Xiamen Funano

 COCC

 Suzhou Dade

Market Segment by Regions, regional analysis covers

 North America (United States, Canada and     Mexico)

 Europe (Germany, France, UK, Russia and     Italy)

 Asia-Pacific (China, Japan, Korea, India     and Southeast Asia)

 South America (Brazil, Argentina,     Colombia etc.)

 Middle East and Africa (Saudi Arabia,     UAE, Egypt, Nigeria and South Africa)

Market Segment by Type, covers

 C60

 C70

 Other

Market Segment by Applications, can be divided into

 Cosmetics

 Pharmaceutical

 Semiconductor & Electronics

 Renewable Energy

 Other

Download Free Sample Report of Global Fullerene Market @ https://www.decisiondatabases.com/contact/download-sample-25813

The content of the study subjects, includes a total of 15 chapters: Chapter 1, to describe Fullerene product scope, market overview, market opportunities, market driving force and market risks. Chapter 2, to profile the top manufacturers of Fullerene, with price, sales, revenue and global market share of Fullerene in 2017 and 2018. Chapter 3, the Fullerene competitive situation, sales, revenue and global market share of top manufacturers are analyzed emphatically by landscape contrast. Chapter 4, the Fullerene breakdown data are shown at the regional level, to show the sales, revenue and growth by regions, from 2014 to 2019. Chapter 5, 6, 7, 8 and 9, to break the sales data at the country level, with sales, revenue and market share for key countries in the world, from 2014 to 2019. Chapter 10 and 11, to segment the sales by type and application, with sales market share and growth rate by type, application, from 2014 to 2019. Chapter 12, Fullerene market forecast, by regions, type and application, with sales and revenue, from 2019 to 2024. Chapter 13, 14 and 15, to describe Fullerene sales channel, distributors, customers, research findings and conclusion, appendix and data source.

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Other Reports by DecisionDatabases.com:

Global Polystyrene Market 2019 by Manufacturers, Regions, Type and Application, Forecast to 2024 @ https://www.decisiondatabases.com/ip/40618-polystyrene-industry-analysis-report

Global General Purpose Polystyrene (GPPS) Market 2019 by Manufacturers, Regions, Type and Application, Forecast to 2024 @ https://www.decisiondatabases.com/ip/41394-general-purpose-polystyrene-gpps-industry-analysis-report

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Our expert research analysts have been trained to map client’s research requirements to the correct research resource leading to a distinctive edge over its competitors. We provide intellectual, precise and meaningful data at a lightning speed.

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Strategic Insight into the Advanced Carbon Materials Market

Advanced carbon materials have excellent thermal stability and mechanical property such as tensile strength than ordinary materials. Graphene, carbon fibers, carbon foams structural graphite, and nanotubes are majorly used advanced carbon materials as engineering materials. Rising focus toward lightweight composites from the automotive and aviation industry and increasing demand of carbon fiber-reinforced plastic in the construction industry is anticipated to drive the global market. However, wastage in the manufacturing of finished products and high associated with cost of carbon fiber composites are projected to hinder the growth of the market during the forecast period.

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https://www.transparencymarketresearch.com/advanced-carbon-materials-market.html

Global Advanced Carbon Materials Market: Segmentation

The global advanced carbon materials market can be segmented based on product, application and region.  In terms of product , the advanced carbon materials market can be divided into carbon fibers, special graphite, carbon nanotubes, grapheme, carbon foams (includes carbon nanofoams) and others such as fullerenes, diamond-like carbon (dlc), nanocrystalline and diamond (ncd). Carbon fibers is a major product segment of global advanced carbon materials market owing to its high consumption in end use industries such as automotive, construction, electronics and energy applications as manufacturing composites. Moreover, the carbon fiber application in aerospace manufacturing industry is being popular due to rising concern of galvanic corrosion of aluminum in aerospace applications. This in turn, is projected to drive the advanced carbon materials market during the forecast period.

Based on application, aerospace & defense, electronics, sports, automotive, construction, and energy. Aerospace & defense is a application key segment of the global advanced carbon materials market. The innovative product design of flexible integrated circuits suitable for high temperature operations in high speed military aero planes is driving the demand of aerospace & defense advanced carbon materials. Furthermore, the focus on light weight aircraft manufacturing has resulted in to design of composite derived wing boxes. The material requirement of these light weight systems are augmenting the demand of advanced carbon materials.

Automotive application of advanced carbon materials is anticipated to experience significant growth during the forecast period. Increasing automotive manufacturing output in emerging economies such as India, China and Mexico is projected to fuel the advanced carbon materials market as the regulations initiatives to promote energy efficient vehicles is resulting into rise of usage of lightweight materials in the design. This in turn augmenting the demand of advanced carbon materials as fillers in the application.

Global Advanced Carbon Materials Market: Regional Outlook

Based on region, the global advanced carbon materials market can be classified into North America, Europe, Asia Pacific, Latin America, and Middle East & Africa. Europe accounts for a large share in the global advanced carbon materials market. The region has well established aerospace manufacturing industry with the key aerospace manufacturers operating the region such as Bell Helicopters, Augusta Westland, Boeing, etc. The ease of accessibility to consumable products for aerospace manufacturing has attributed to significant impact on Europe advanced carbon materials market. Asia Pacific region is anticipated to exhibit rapid growth during the forecast period. Governmental initiatives by government of China to develop energy efficient automotive systems are projected to augment the demand of light weight and durable materials. This, in turn is estimated to fuel the Asia Pacific advanced carbon materials market.

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Global Advanced Carbon Materials Market: Competitive Landscape

Various key players in the global advanced carbon materials market tend to gain competitive advantage by means of product innovation in the field of light weight and durable material. Key players operating in the global advanced carbon materials market include Hexcel, Zoltek, Arkema, Nippon Graphite Fiber Corporation., Cnano Technology, ANAORI CARBON Co., Ltd. Grupo, Antolin Grupo, Graphenano, CVD Equipment Corporation, Haydale Graphene Industries PLC, Showa Denko K.K., Mitsubishi Chemical Carbon Fiber and Composites, Inc., company name and others.

Global Graphene Market- By Application (Electronics, Aerospace & Defense, Energy, Automotive, Healthcare, Others), Forecast And Opportunities, 2025 Growth Potential, Price Trends, Competitive Market Share & Forecast, 2019 – 2027

Graphene Market – Market Overview

Graphene is an allotrope of carbon having a single layer of carbon atoms arranged in hexagonal lattice form. It is the basic structural element of many other allotropes of carbon, such as graphite, charcoal, carbon nanotubes and fullerenes. Graphene is emerging as one of the most promising nanomaterial because of its unique combination of superb properties, which opens a way for its exploitation in a wide spectrum of applications ranging from electronics to optics, sensors, and bio devices. Graphene is technically a non-metal but is often referred to as a quasi-metal due to its properties being like that of a semi-conducting metal, which enable its application in electronics and energy sector.

According to the leading research organizations the global market for electronics products has grown at an average CAGR of about 13% per year from past five year. Growing demand for energy storage systems, rust free coating, printed electronics are some of the major driving factors operating into the market. In addition to this, increasing spending economic power of middle class population have led the greater adoption of electronic devices over the past five years. In addition to this, rapid industrialization fuelling the growth of automotive and aerospace sectors.

Growing use of the light weight vehicles in automotive industry is projected to boost growth of the market which is anticipated to continue in the coming years which may consolidate graphene demand. Increasing research & development activities along with growing focus on development of new products and technological innovation is expected to provide fuel the growth of this market over the forecast period. On the other hand, global market growth is held back by increasing environmental concern. However, the high price of manufacturing technology and equipment, along with technical limitations for commercial production are the major factors restricting the market growth. As per the study published by Market Research Future on graphene market, the trend for electronics industry is projected to drive demand for Graphene in the coming years.

Access Complete Report @ https://www.marketresearchfuture.com/reports/graphene-market-2987

Key Players:

CVD Equipment Corporation (US), Vorbeck Materials (US), Graphene NanoChem (UK), XG Sciences, Inc. (US), Angstron Materials, Inc (US), Graphene Laboratories, Inc. (US), BGT Materials Limited, Ltd (UK), Graphenea Inc. (US), Grafoid Inc (North America), Haydale Limited (UK), and Others are some of the prominent players at the forefront of competition in the Global Graphene Market and are profiled in MRFR Analysis.

Graphene Market- Competitive Landscape

The global graphene is highly matured market driven by flourishing growth in aerospace & defence industry, along with the flourishing transportation sector.  CVD Equipment Corporation, Vorbeck Materials, Graphene NanoChem, XG Sciences, Inc., Angstron Materials, Inc, Graphene Laboratories, Inc. are the major shareholders in this market. Most of these market participants are adopting the expansion and collaboration tactic of their production capacities to strengthen their market position. Growing manufacturing industries, and continuous collaborations and agreements between manufacturers, distributers, and marketing firms are key factors for the growth of graphene in the global market. Taking into account these trends, the global Graphene market is likely to witness considerable competition over the forecast period of 2017-2023.

Industry/ Innovation/ Related News:

August 17, 2016- Angstron Materials, Inc. and Gustav Grolman GmbH & Co KG entered into a pan-Europe distribution agreement for Angstron’s high performance graphene products. Angstron is the world’s largest producer of graphene nanomaterial with a production capacity of over 300 tpa. On the other hand the Grolman Group operates an international specialty chemical distribution business from a number of well renowned suppliers. This development is expected to boost sale of the product in this region.

September 29, 2016- Vorbeck has introduced Vor-flex™ Engineered HNBR Elastomer which is a Rubber Reinforced with Vor-x® Graphene. It is the first in a new family of graphene-enhanced, engineered elastomer products. Vor-flex exhibits high temperature stability, which allows it to serve in some of the most demanding environments, such as those found in automotive and petrochemical applications. This is likely to enhance the application scope of the Vorbeck graphene products.

September 13, 2016- Reliance Industries Ltd, one of Asia’s top petrochemical production companies, and Vorbeck Materials Corp., a leading producer of graphene and graphene-based products announced that they have signed a joint development agreement to develop graphene-enhanced synthetic elastomer products. This may help Vorbeck to expand its production pfacility Asia Pacific region and gain the advantage of grwoth in this region.

   NOTE: Our Team of Researchers are Studying Covid19 and its Impact on Various Industry Verticals and wherever required we will be considering Covid19 Footprints for Better Analysis of Market and Industries. Cordially get in Touch for More Details.

Nanostructured Carbon Composites Market Emerging Trends and Strong Application Scope by 2025

Nanostructured carbon composites are multiphase solid materials having allotropes of carbon. They possess cylindrical nanostructure. Carbon composites are employed in nanotechnology, electronics, optics, and other fields of material science and technology due to the various attributes exhibited by carbon molecules. Fullerene, graphene, carbon nanotubes, and carbon nanofiber are some nanostructured carbon composites. They are nothing but one, two, or three dimensional allotropes of carbon. They are exceptionally strong and exhibit high stiffness. Graphene is about 200 times stronger than steel. Carbon nanotubes possess high level of strength. Nanostructured carbon composites are good conductors of heat and electricity; therefore, they are extensively used as additives in a wide range of structural materials such as golf clubs, baseball bats, car parts, damascus steel, etc.

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​https://www.transparencymarketresearch.com/nanostructured-carbon-composites-market.html

They are employed in numerous applications in end-user industries such as electronics, bio-medical, aerospace, construction, automotive etc. owing to the different attributes exhibited by them. In the electronics industry, nanostructured carbon composites are employed in a number of material or device applications such as solar cells, light-emitting diodes, and touch panels of smartphones. They are also highly engaged to manufacture supercapacitors used to store energy. Supercapacitors can act as a substitute to the conventional electrolytic batteries, as they possess numerous advantages over the latter, such as less time required for charging, longevity, and eco-friendly production process. Supercapacitors are extensively employed in the automotive industry as replacement for lithium-ion batteries or for regenerative braking. However, the production of nanostructured carbon composites is expensive than that of its substitutes. Furthermore, working with nanostructured carbon composites is difficult as they are small in size. Thus, there is always the need to find a substitute for them.

Based on application, the nanostructured carbon composites market can be segmented into electronics, automotive, bio-medical, energy, aerospace, and others. The electronics industry at present dominates the market and is anticipated to retain its position during the forecast period. The automotive industry is expected to expand significantly in the near future. Development in the automotive and electronics industries in Asia Pacific and North America is projected to drive the nanostructured carbon composites market in these regions in the next few years.

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Based on geography, the nanostructured carbon composites market can be divided into North America, Europe, Latin America, Asia Pacific, and Middle East & Africa. Asia Pacific is projected to dominate the nanostructured carbon composites market during the forecast period, due to the expansion of end-user industries in the region. Rapid industrial, infrastructural, and economic progress in the developing countries such as India and China and rise in standard of living and disposable income of the people have boosted the demand for automobiles and electronics in these countries, which in turn, has propelled the nanostructured carbon composites market in the region. The healthcare industry is expected to develop at a steady pace in Latin America, thus driving the growth of nanostructured carbon composites in the region.

Major players operating in the nanostructured carbon composites market are Bayer Material Science, Catalytic Materials, Emfutur Technologies, NanoAmor, Applied Sciences, Graphene Nanochem, XG Sciences, and Applied NanoStructured Solutions.

Asia Pacific is anticipated to provide ample opportunities for growth to the existing as well as new players in the market. Developing countries such as China, India, Indonesia, and Vietnam with evolving manufacturing infrastructure are expected to contribute significantly to the nanostructured carbon composites market during the forecast period.

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The Global Market for Carbon and Graphite is Projected to Reach US$20.1 Billion by 2024

Novel Applications Including Use in Li-Ion Batteries in the Emerging Electric Vehicle Market to Drive the Global Carbon & Graphite Market, According to a New Report by Global Industry Analysts, Inc.

GIA launches comprehensive analysis of industry segments, trends, growth drivers, market share, size and demand forecasts on the global Carbon and Graphite market. The global market for Carbon and Graphite is projected to reach US$20.1 billion by 2024, driven by their indispensability in the production of a wide range of products in end-use sectors such as steel, automotive, energy, and aerospace; and emerging new uses in Lithium ion batteries, electric vehicles, graphene electronics, and carbon nanostructures.  

The thriving end-use industries such as steel, transportation, electronics, semiconductor, solar, and petrochemical, among others, drive demand for carbon and graphite. Industrial manufacturing applications of graphite range from the humble pencil to the moderate battery coating application, and ultimately to the highly complex hot forging lubricants and electric arc furnace steel production. Graphite electrodes are extensively used in the production of steel. The state of the steel industry therefore is a major factor deciding the pace of market growth for graphite. Furthermore, metallurgy operations create sustained demand for graphite.

Many technological advancements of the world created newer markets for graphite as well. Lithium ion battery manufacture is one such major and rapidly growing application for graphite. Synthetic graphite and natural flake graphite represent one of the core raw materials used in Lithium ion batteries, which find increased usage in electric vehicles (EV). The booming EV market worldwide is anticipated to emerge as a key growth driver for the global market for graphite in the coming years. Other end uses include graphene, fuel cells, solar panels and pebble-bed nuclear reactors. The evolving demand from batteries used in electric vehicles and base-load battery storage, and the advent of smaller nuclear reactors are expected to stimulate graphite demand in the coming years. Owing to its use in many energy-related applications, graphite has also been identified as a critical and strategic mineral by several governments.

However, China’s dominance in graphite started declining in 2017 with the country’s government imposing closures on plants, in a move to minimize pollution and inefficiencies. China also shifted to the EAF steelmaking method and started consuming more graphite electrodes domestically. This negatively impacted Chinese exports to the world and prices of graphite electrodes shot up worldwide. The same trend is expected for 2018 and beyond. Because of supply uncertainty from the Chinese market and graphite electrode prices shooting up globally, steel production is likely to take off from other countries. Supply constraints are also leading to lesser demand of steel overall. The emergence of other strategic end-use markets such as batteries for graphite electrodes also would support this shift.  Further, with carbon emerging into a key ingredient in the field of nanotechnology, the growing production of fullerenes, buckyballs and carbon nanotubes (CNTs) will spur growth in the market.

Sales of EVs have been rapidly increasing globally since 2014, which hints at a market with very high growth potential for graphite. EVs are expected to make up for about 5% of the global light vehicles demand by the year 2020. However, currently only a small percentage of graphite that is produced worldwide actually goes into the manufacturing of Lithium ion batteries for EVs. Though fast growing, it is a miniscule application currently. In addition, enough global supply capacity is lacking for flake graphite, which is used in batteries. This highlights the urgent need for existing as well as new miners to expand capacities and be ready to tackle a potentially robust Li-ion battery market, which would demand large amounts of the mineral.

As stated by the new market research report on Carbon and Graphite, Asia-Pacific represents the largest market worldwide, led by steady economic growth, sustained demand from developing aerospace and automotive sectors, and increasing investments in nanotechnology and fuel cells research. Steady growth in demand for steel and other metals is also contributing to the sustained demand for graphite electrodes in the region. Rest of World represents the fastest growing market, however, on account of newer graphite mines being discovered in the East African region, coupled with graphite supply constraints from Asia-Pacific.

Major players in the market include Cabot Corporation, Solvay S.A., GrafTech International Holdings Inc., HEG Ltd., Hexcel Corporation, Mersen S.A., Mitsubishi Chemical Holdings Corporation, Mitsubishi Chemical Carbon Fiber and Composites, Morgan Advanced Materials plc, Nippon Carbon Co. Ltd., Orion Engineered Carbons LLC, SGL Group – The Carbon Company, Showa Denko K.K, Showa Denko Carbon Inc., Superior Graphite, Teijin Ltd., Tokai Carbon Co. Ltd., Toray Industries Inc., and ZOLTEK™ Carbon Fiber, among others.

The research report titled “Carbon and Graphite: A Global Strategic Business Report” announced by Global Industry Analysts Inc., provides a comprehensive review of market trends, issues, drivers, mergers, acquisitions and other strategic industry activities of global companies. The report provides market estimates and projections for all major geographic markets such as the US, Canada, Japan, Europe (France, Germany, Italy, UK, Spain, Russia and Rest of Europe), Asia-Pacific (China, India, and Rest of Asia Pacific), Latin America (Brazil, Mexico, and Rest of Latin America) and Rest of World. The Carbon and Graphite market is analyzed by the following Product Categories/Segments – Carbon & Graphite Electrodes (Carbon Electrodes and Graphite Electrodes), Carbon & Graphite Fibers, Carbon & Graphite Powder and Others. The Carbon & Graphite Fibers market is additionally analyzed by the end-use sectors of Industrial, Aerospace, and Others (Including Automotive, Sporting Goods, and Wind Energy Sector among Others).

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Nanochemicals Market to be at Forefront by 2023

Chemicals generated by using nanotechnology on conventional chemical building blocks such as ethane, propane, and butane are called nanochemicals. Nanochemicals exhibit beneficial properties such as self-catalysis and anti-corrosion as compared to other conventional chemicals. These chemicals carry out chemical reactions in less time.

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Nanochemicals are segmented based on end-user applications into construction chemicals, semiconductors and IC process chemicals, mining chemicals, rubber chemicals, pesticides, printing ink, plastic additives, pigments, specialty polymers, and water treatment. Zinc oxide and titanium dioxide are among the chemicals that are widely used in semiconductors and IC process chemicals. Growth in the electronic sector is expected to boost demand for these chemicals in the near future. Carbon nanotube, graphene, and fullerenes have gained wide applications due to their distinct mechanical and electrical properties. Carbon nanotubes are primarily used in the bicycle manufacturing industry as the material produced is very dense and lightweight. Increased awareness regarding pollution-free environment and enhanced focus on health and fitness are key factors fueling demand for bicycles. This, in turn, would result in rising demand for carbon nanotubes in the near future. Printing ink is produced by titanium dioxide pigments due to its properties such as brightness and high refractive index. Nanochemicals are used in the manufacture of nano-sized ceramic ink, which gives high color strength to ceramics in different applications.

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Global increase in demand for nano chemical-based products is due to factors such as enhancement of multiphase chemical reaction and maximum product yield. These factors have driven demand for nanochemicals globally, thus acting as chief driver for the nanochemicals market. In addition increase in applications of nanochemicals in sectors such as agrochemicals, manufacturing and multifunctional coating are expected to further propel the demand for nanochemicals globally. Development in nano chemistry would lead to increase in application of nanochemicals. This, in turn, is anticipated to propel demand for nanochemicals in the next few years. Restraining governmental regulations regarding the manufacture of chemicals is estimated to offer high growth opportunities to the nanochemicals market in the next few years.

The global nanochemicals market is segmented based on regions into North America, Europe, Asia Pacific, Middle East and Africa, and Latin America. North America is anticipated to be the largest market for nanochemicals followed by Europe and Asia Pacific during the forecast period. Technological developments and increase in regulatory efforts to use nanochemicals in materials have driven demand for nanochemicals in North America. Europe being the second-largest market for nanochemicals has large number of suppliers for titanium-based products. Increased growth in the pigment and printing ink sector is anticipated to boost demand for nanochemicals in the near future. Asia Pacific is expected to experience high demand for nanochemicals in the near future due to various factors such as industrial development and shifting of companies from convectional chemicals to nano-based chemicals. Growing applications of nanochemicals in sectors such as construction, electronics, and rubber is projected to fuel the market in Asia Pacific as these sectors are experiencing significant growth in developing economies such as India and China. Increase in foreign investment and governmental support such as tax benefits in developing economies is anticipated to create strong market opportunities for nanochemicals in Asia Pacific during the forecast period.

Some of the key global companies operating in the nanochemicals market are ANP Co.,Ltd, BASF SE, E. I. Du Pont de Nemours and Company, Akzo Nobel N.V and Graphene NanoChem amongst others.

The report has been compiled through extensive primary research (through interviews, surveys, and observations of seasoned analysts) and secondary research (which entails reputable paid sources, trade journals, and industry body databases). The report also features a complete qualitative and quantitative assessment by analyzing data gathered from industry analysts and market participants across key points in the industry’s value chain.

A separate analysis of prevailing trends in the parent market, macro- and micro-economic indicators, and regulations and mandates is included under the purview of the study. By doing so, the report projects the attractiveness of each major segment over the forecast period.

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