Category Archives: Nanotechnology

The report is a highly reliable document to understand dominant segments prevalent in the market. Each of the segments identified comprise product and service segments, besides end-use applications and functionality. The potential of each of the segments has been discussed at length to unravel their revenue generation potential and scope of development in forthcoming years. Based on these crucial insights, market players may well design and deploy growth proficient business discretion through the forecast span in global Agricultural Nanotechnology market.

Access the PDF sample of the Agricultural Nanotechnology market report @ https://www.orbisresearch.com/contacts/request-sample/2456168?utm_source=Atish

The key players covered in this studyCatalytic MaterialsChasm TechnologiesHybrid PlasticsHyperion Catalysis InternationalIntegran TechnologiesNanoMaterials TechnologyNanocylNanophase TechnologiesNanosysPENQuantum SphereShenzhen Nanotech PortStarpharmaZyvexEspin TechnologiesMarket analysis by product typeCrop ProtectionSoil ImprovementWater PurificationPlant BreedingNanoparticles ProductionMarket analysis by marketFarmers/ProducersR&DGovernment OrganizationsMarket analysis by RegionUnited StatesEuropeChinaJapanSoutheast AsiaIndiaCentral & South AmericaThe study objectives of this report are:To analyze global Agricultural Nanotechnology status, future forecast, growth opportunity, key market and key players.To present the Agricultural Nanotechnology development in United States, Europe and China.To strategically profile the key players and comprehensively analyze their development plan and strategies.To define, describe and forecast the market by product type, market and key regions.In this study, the years considered to estimate the market size of Agricultural Nanotechnology are as follows:History Year: 2018-2019Base Year: 2018Estimated Year: 2019Forecast Year 2019 to 2025For the data information by region, company, type and application, 2018 is considered as the base year. Whenever data information was unavailable for the base year, the prior year has been considered.

The report specifically highlights economic scenario across various regional belts. Each of the growth beds pertaining to global Agricultural Nanotechnology market has been meticulously scanned to obtain crucial understanding on steaming competition across each regional segment, technological innovations, regulatory framework, core dynamics, as well as production and consumption alterations across these regions. Core regional growth hubs pinned in the report are also followed by country specific analysis with meticulous detailing of several countries across the Americas, Europe, Asian countries as well as MEA and GCC nations.

Key Questions Addressed in the Report

This report attempts to forecast market size and dimensions in the coming timeframe, 2020-25The report categorically identifies notable trends likely to remain dominant through the growth timeframeThe report specifically identifies key market players and manufacturers flagged as leading playersThe report identifies key growth propellants of the marketThe report aids reader comprehension by understanding the prevailing challenges in the market and their subsequent implicationsA clear profile of market stakeholders, traders and dealers spread across the marketThe report also identifies dominant market threats and challenges, besides mapping core opportunities likely to influence vendor activities and subsequent market growth scenarioThe report also aims to understand market growth trends in the previous years as well as also makes accurate predictions about futuristic possibilities pertaining to global Agricultural Nanotechnology market.

Make an enquiry of Agricultural Nanotechnology market report @ https://www.orbisresearch.com/contacts/enquiry-before-buying/2456168?utm_source=Atish

Nanotechnology in agriculture is the application of extremely small tools such as sensors, which can be used for agricultural development.The global agricultural nanotechnology market is also segmented by end users which includes: farmers/producers, R&D institutes and government organizations.In 2018, the global Agricultural Nanotechnology market size was xx million US$ and it is expected to reach xx million US$ by the end of 2025, with a CAGR of xx% during 2019-2025.This report focuses on the global Agricultural Nanotechnology status, future forecast, growth opportunity, key market and key players. The study objectives are to present the Agricultural Nanotechnology development in United States, Europe and China.The key players covered in this studyCatalytic MaterialsChasm TechnologiesHybrid PlasticsHyperion Catalysis InternationalIntegran TechnologiesNanoMaterials TechnologyNanocylNanophase TechnologiesNanosysPENQuantum SphereShenzhen Nanotech PortStarpharmaZyvexEspin TechnologiesMarket analysis by product typeCrop ProtectionSoil ImprovementWater PurificationPlant BreedingNanoparticles ProductionMarket analysis by marketFarmers/ProducersR&DGovernment OrganizationsMarket analysis by RegionUnited StatesEuropeChinaJapanSoutheast AsiaIndiaCentral & South AmericaThe study objectives of this report are:To analyze global Agricultural Nanotechnology status, future forecast, growth opportunity, key market and key players.To present the Agricultural Nanotechnology development in United States, Europe and China.To strategically profile the key players and comprehensively analyze their development plan and strategies.To define, describe and forecast the market by product type, market and key regions.In this study, the years considered to estimate the market size of Agricultural Nanotechnology are as follows:History Year: 2018-2019Base Year: 2018Estimated Year: 2019Forecast Year 2019 to 2025For the data information by region, company, type and application, 2018 is considered as the base year. Whenever data information was unavailable for the base year, the prior year has been considered.

Nanotechnology in agriculture is the application of extremely small tools such as sensors, which can be used for agricultural development.The global agricultural nanotechnology market is also segmented by end users which includes: farmers/producers, R&D institutes and government organizations.In 2018, the global Agricultural Nanotechnology market size was xx million US$ and it is expected to reach xx million US$ by the end of 2025, with a CAGR of xx% during 2019-2025.This report focuses on the global Agricultural Nanotechnology status, future forecast, growth opportunity, key market and key players. The study objectives are to present the Agricultural Nanotechnology development in United States, Europe and China.The key players covered in this studyCatalytic MaterialsChasm TechnologiesHybrid PlasticsHyperion Catalysis InternationalIntegran TechnologiesNanoMaterials TechnologyNanocylNanophase TechnologiesNanosysPENQuantum SphereShenzhen Nanotech PortStarpharmaZyvexEspin TechnologiesMarket analysis by product typeCrop ProtectionSoil ImprovementWater PurificationPlant BreedingNanoparticles ProductionMarket analysis by marketFarmers/ProducersR&DGovernment OrganizationsMarket analysis by RegionUnited StatesEuropeChinaJapanSoutheast AsiaIndiaCentral & South AmericaThe study objectives of this report are:To analyze global Agricultural Nanotechnology status, future forecast, growth opportunity, key market and key players.To present the Agricultural Nanotechnology development in United States, Europe and China.To strategically profile the key players and comprehensively analyze their development plan and strategies.To define, describe and forecast the market by product type, market and key regions.In this study, the years considered to estimate the market size of Agricultural Nanotechnology are as follows:History Year: 2018-2019Base Year: 2018Estimated Year: 2019Forecast Year 2019 to 2025For the data information by region, company, type and application, 2018 is considered as the base year. Whenever data information was unavailable for the base year, the prior year has been considered.

Guide to Report Investment:

This holistic research report renders uncompromised access to COVID-19 impact assessment, besides designing and deploying a concrete action plan for quick recoveryThe report progresses further with offering specific market details bordering along market size and dimensions, growth hotspots and regional belts influencing balanced and holistic growth trajectoryThe report also sheds ample light on regional overview, encompassing details in core growth beds comprising North and Latin Americas, Europe, APAC, and MEA.Details pertaining to competition assessment with highlights on progressive market players and their specific growth strategies, trend assessment and revenue forecasts have also been widely discussed in this versatile report on global Agricultural Nanotechnology market.

Browse the complete Agricultural Nanotechnology market report @ https://www.orbisresearch.com/reports/index/global-agricultural-nanotechnology-market-size-status-and-forecast-2019-2025?utm_source=Atish

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Agricultural Nanotechnology Market 2021: Analysis Of The Industry By Size, Share, Consumption, Demand, Growth, Revenues, Key Companies, Types,...

Nanotechnology Enabled Coatings for Aircraft Market Forecast 2029: Revenue, Size & Growth

Global Nanotechnology Enabled Coatings for Aircraft MarketForecast till 2029research includes reliable economic, international, and country-level forecasts and analysis. It offers a holistic view of the competitive market and thorough analyses of the supply chain to help companies identify closely significant trends in the company practices seen in the sector. Major Companies listed in this Reports areAnCatt (United States), Applied Thin Films (United States), FlightShield (United States), Glonatech (Greece), tripleO (United States), CHOOSE NanoTech (United Kingdom), General Nano (United States), Surfactis Technologies (France), Tesla NanoCoatings (United States).

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Regional Breakout for Nanotechnology Enabled Coatings for Aircraft Market: North America XXX million $, Europe XXX million $, Asia XXX million $ & Rest of World.

OverviewNanotechnology Enabled Coatings for Aircraft Market including Types & Application:

North America:United States, Canada, and MexicoSouth & Central America:Argentina, Chile, and BrazilMiddle East & Africa:Saudi Arabia, UAE, Turkey, Egypt and South AfricaEurope:UK, France, Italy, Germany, Spain, and Russia

Application: [Application]

Types:[Type]

Nanotechnology Enabled Coatings for Aircraft Market Leading Competition:In this section, the report provides information on Competitive situations and trends including merger and acquisition and expansion, market shares of the top ten players, and market concentration rate. Readers could also be provided with production, revenue, and average price shares by manufacturers.

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Research Methodology:

The market engineering process uses a top-down and bottom-up approach and several data triangulation methods to evaluate and validate the size of the entire market and other dependent sub-markets listed in Nanotechnology Enabled Coatings for Aircraft report. Numerous qualitative and quantitative analyzes have been conducted in the market engineering process to list key information / insights. The major players in the market were identified through the second survey and the market rankings were determined through the first and second surveys.

Primary Research:

During the first survey, we interviewed various key sources of supply and demand to obtain qualitative and quantitative information related to Nanotechnology Enabled Coatings for Aircraft report. Key supply sources include key industry participants, subject matter specialists from key companies, and consultants from several major companies and organizations active in the digital signage market.

Secondary Research:

The second study was conducted to obtain key information on the supply chain of the Nanotechnology Enabled Coatings for Aircraft industry, the markets currency chain, pools of major companies, and market segmentation, with the lowest level, geographical market, and technology-oriented perspectives. Secondary data was collected and analyzed to reach the total market size, which was verified by the first survey.

Global Nanotechnology Enabled Coatings for Aircraft Market Detailed study of each point:

TheNanotechnology Enabled Coatings for Aircraft Marketstudy offers a comprehensive overview of the current market and forecasts by 2020-2029 to help identify emerging business opportunities on which to capitalize.

The report provides an in-depth review of industry dynamics in Nanotechnology Enabled Coatings for Aircraft, including existing and potential developments to represent prevailing consumer pockets of investment.

The report provides details concerning key drivers, constraints and opportunities and their effect on the Nanotechnology Enabled Coatings for Aircraft market.

Industry players AnCatt (United States), Applied Thin Films (United States), FlightShield (United States), Glonatech (Greece), tripleO (United States), CHOOSE NanoTech (United Kingdom), General Nano (United States), Surfactis Technologies (France), Tesla NanoCoatings (United States) strategic analysis and industry position in the global Nanotechnology Enabled Coatings for Aircraft market;

The report elaborates on the SWOT analysis and Porters Five Forces model.

The market-study value chain review gives a good view of the positions of the stakeholders.

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Major Highlights of Nanotechnology Enabled Coatings for Aircraft Market in Covid-19 pandemic covered in report:

Market Competition by key manufacturers in the Nanotechnology Enabled Coatings for Aircraft industry. Discussed Sourcing strategies, industrial chain information and downstream buyers data. Distributors and traders on Nanotechnology Enabled Coatings for Aircraft marketing strategy analysis focusing on region wise needs in covid-19 pandemic. Vendors who are providing a wide range of product lines and intensifying the competitive scenario in Nanotechnology Enabled Coatings for Aircraft covid-19 crisis. Also highlights of the key growth sectors of Nanotechnology Enabled Coatings for Aircraft market and how they will perform in coming years.

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** The demand is measured on the basis of the weighted average sale price (WASP), which requires the manufacturers taxes. The currency conversions that were used to construct this study were determined using a given annual average rate of currency exchange from 2020.

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Nanotechnology Enabled Coatings for Aircraft Market to Eyewitness Massive Growth by 2028: AnCatt (United States), Applied Thin Films (United States),...

By Steve Nadis, MIT Department of Materials Science and EngineeringJanuary 27, 2021

MIT researchers have designed small molecules that spontaneously form nanoribbons when water is added. These molecules include a Kevlar-inspired aramid domain in their design, in green, which fixes each molecule in place and leads to nanoribbons that are stronger than steel. Parts of the molecules attracted to or repulsed from water, shown in purple and blue respectively, orient and guide the molecules to form a nanostructure. This image depicts three Kevlar-inspired aramid amphiphile nanoribbons. Credit: Peter Allen

Self-assembly of Kevlar-inspired molecules leads to structures with robust properties, offering new materials for solid-state applications.

Self-assembly is ubiquitous in the natural world, serving as a route to form organized structures in every living organism. This phenomenon can be seen, for instance, when two strands of DNA without any external prodding or guidance join to form a double helix, or when large numbers of molecules combine to create membranes or other vital cellular structures. Everything goes to its rightful place without an unseen builder having to put all the pieces together, one at a time.

For the past couple of decades, scientists and engineers have been following natures lead, designing molecules that assemble themselves in water, with the goal of making nanostructures, primarily for biomedical applications such as drug delivery or tissue engineering. These small-molecule-based materials tend to degrade rather quickly, explains Julia Ortony, assistant professor in MITs Department of Materials Science and Engineering (DMSE), and theyre chemically unstable, too. The whole structure falls apart when you remove the water, particularly when any kind of external force is applied.

She and her team, however, have designed a new class of small molecules that spontaneously assemble into nanoribbons with unprecedented strength, retaining their structure outside of water. The results of this multi-year effort, which could inspire a broad range of applications, were described on January 21, 2021, in Nature Nanotechnology by Ortony and coauthors.

Professor Julia Ortony (left) and PhD student Yukio Cho. Ortony and her team have designed a new class of small molecules that spontaneously assemble into nanoribbons with unprecedented strength, retaining their structure outside of water. Credit: Lee Hopkins

This seminal work which yielded anomalous mechanical properties through highly controlled self-assembly should have a big impact on the field, asserts Professor Tazuko Aida, deputy director for the RIKEN Center for Emergent Matter Science and professor of chemistry and biotechnology at the University of Tokyo, who was not involved in the research.

The material the MIT group constructed or rather, allowed to construct itself is modeled after a cell membrane. Its outer part is hydrophilic, which means it likes to be in water, whereas its inner part is hydrophobic, meaning it tries to avoid water. This configuration, Ortony comments, provides a driving force for self-assembly, as the molecules orient themselves to minimize interactions between the hydrophobic regions and water, consequently taking on a nanoscale shape.

PhD student Ty Christoff-Tempesta works in the laboratory.Credit: Lee Hopkins

The shape, in this case, is conferred by water, and ordinarily the whole structure would collapse when dried. But Ortony and her colleagues came up with a plan to keep that from happening. When molecules are loosely bound together, they move around quickly, analogous to a fluid; as the strength of intermolecular forces increases, motion slows and molecules assume a solid-like state. The idea, Ortony explains, is to slow molecular motion through small modifications to the individual molecules, which can lead to a collective, and hopefully dramatic, change in the nanostructures properties.

One way of slowing down molecules, notes Ty Christoff-Tempesta, a PhD student and first author of the paper, is to have them cling to each other more strongly than in biological systems. That can be accomplished when a dense network of strong hydrogen bonds join the molecules together. Thats what gives a material like Kevlar constructed of so-called aramids its chemical stability and strength, states Christoff-Tempesta.

Ortonys team incorporated that capability into their design of a molecule that has three main components: an outer portion that likes to interact with water, aramids in the middle for binding, and an inner part that has a strong aversion to water. The researchers tested dozens of molecules meeting these criteria before finding the design that led to long ribbons with nanometer-scale thickness. The authors then measured the nanoribbons strength and stiffness to understand the impact of including Kevlar-like interactions between molecules. They discovered that the nanoribbons were unexpectedly sturdy stronger than steel, in fact.

This finding led the authors to wonder if the nanoribbons could be bundled to produce stable macroscopic materials. Ortonys group devised a strategy whereby aligned nanoribbons were pulled into long threads that could be dried and handled. Notably, Ortonys team showed that the threads could hold 200 times their own weight and have extraordinarily high surface areas 200 square meters per gram of material. This high surface-to-mass ratio offers promise for miniaturizing technologies by performing more chemistry with less material, explains Christoff-Tempesta. To this end, they have already developed nanoribbons whose surfaces are coated with molecules that can pull heavy metals, like lead or arsenic, out of contaminated water. Other efforts in the research group are aimed at using bundled nanoribbons in electronic devices and batteries.

Ortony, for her part, is still amazed that theyve been able to achieve their original research goal of tuning the internal state of matter to create exceptionally strong molecular nanostructures. Things could easily have gone the other way; these materials might have proved to be disorganized, or their structures fragile, like their predecessors, only holding up in water. But, she says, we were excited to see that our modifications to the molecular structure were indeed amplified by the collective behavior of molecules, creating nanostructures with extremely robust mechanical properties. The next step, figuring out the most important applications, will be exciting.

Reference: Self-assembly of aramid amphiphiles into ultra-stable nanoribbons and aligned nanoribbon threads by Ty Christoff-Tempesta, Yukio Cho, Dae-Yoon Kim, Michela Geri, Guillaume Lamour, Andrew J. Lew, Xiaobing Zuo, William R. Lindemann and Julia H. Ortony, 18 January 2021, Nature Nanotechnology.DOI: 10.1038/s41565-020-00840-w

The work was supported by the National Science Foundation, the Professor Amar G. Bose Research Grant Program, and the Abdul Latif Jameel Water and Food Systems Lab (J-WAFS).

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Kevlar-Inspired Molecular Nanofibers Constructed That Are Stronger Than Steel - SciTechDaily

I followed the option Nanobiotechnology at KU Leuven and UGA Grenoble, and graduated in 2016. I discovered this program by accident and never believed that I would actually be accepted. This program and the amazing professors running it opened up great opportunities for me, which not only changed my life, but also me. Among these opportunities were the experience of living in two different countries and meeting wonderful people from all around the world. In particular, I was given the opportunity to gain valuable knowledge and understanding from many different fields ranging from physics to electronics and chemistry to biology, and that is what according to me makes this program so extraordinary. This interdisciplinary background then opens up the possibility to look at scientific problems from an entirely different perspective and offers exciting career paths you would never have expected before starting this program. So if you are wondering if you should apply and you are not afraid of challenges, do not hesitate, as this program is definitely worth it.

Previous education: Bachelor Nanotechnology,Technical University of Liberec, Czeck Republic. Present position: PhD student at EPFL Lausanne, Switzerlandhttps://www.linkedin.com/in/barbora-lavi%C4%8Dkov%C3%A1-6ab9105b/

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EMM Nano | Erasmus Mundus

Dublin, Jan. 20, 2021 (GLOBE NEWSWIRE) -- The "The Global Market for Nanotechnology and Nanomaterials in Packaging" report has been added to ResearchAndMarkets.com's offering.

Nanomaterials have already been commercialized at various stages of the packaging supply chain from food storage to traceability and tracking. Their enhanced properties, such as UV protection, barrier to moisture, gases and volatile components, mechanical strength, significantly improve packaging materials.

Nanomaterials-based packaging is used to:

The use of nanomaterials in packaging will play a significant role in:

Nanomaterials utilized in packaging include:

Report contents include:

Key Topics Covered:

1 INTRODUCTION 1.1 Aims and objectives of the study 1.1.1 Properties of nanomaterials 1.1.2 Categorization

2 RESEARCH METHODOLOGY

3 EXECUTIVE SUMMARY 3.1 Market drivers and trends in packaging 3.1.1 Antimicrobial packaging for food safety 3.1.2 Active packaging 3.1.3 Intelligent/smart packaging 3.1.4 Biobased packaging and sustainable packaging 3.1.5 Improved barrier function to increase shelf life 3.2 Market challenges and risk assessment 3.3 Global market demand and revenues for nanopackaging

4 TYPES OF PACKAGING 4.1 Barrier films and coatings 4.2 Antimicrobial active packaging 4.3 Anti-counterfeit packaging 4.4 Intelligent packaging

5 NANOMATERIALS USED IN PACKAGING 5.1 Composites 5.2 Coatings and films 5.3 Nanosensors 5.4 Cellulose nanofibers (CNFs) 5.4.1 Paper and board packaging 5.4.2 Barrier films 5.4.3 Antimicrobial packaging 5.5 Cellulose nanocrystals 5.5.1 Properties 5.5.2 Applications 5.5.2.1 Barrier films 5.5.2.2 Anti-counterfeiting films 5.5.2.3 Antimicrobial coatings 5.6 Bacterials nanocellulose (BNC) 5.6.1 Applications 5.7 Graphene 5.7.1 Properties 5.7.2 Barrier films for food packaging 5.7.3 Anti-bacterial activity 5.7.4 Anti-viral activity 5.7.4.1 Reduced graphene oxide (rGO) 5.8 Nanosilver 5.8.1 Properties 5.8.2 Antimicrobial and antiviral activity 5.8.3 Nanosilver in packaging 5.9 Nanosilica 5.9.1 Properties 5.9.2 Antimicrobial and antiviral activity 5.9.3 Easy-clean and dirt repellent 5.10 Zinc oxide nanoparticles 5.10.1 Properties 5.10.2 Antimicrobial packaging films 5.11 Carbon nanotubes 5.11.1 Properties 5.11.2 Antimicrobial activity 5.12 Chitosan nanoparticles 5.12.1 Antimicrobial coatings 5.12.2 Packaging coatings and films 5.13 Nanoclays 5.13.1 Properties 5.13.2 Barrier films 5.13.3 Nanoclay producers 5.14 Titanium dioxide nanoparticles 5.14.1 Properties 5.14.2 Antibacterial films 5.15 Copper nanoparticles 5.15.1 Properties 5.15.2 Anti-microbial coatings 5.16 Hydrophobic and hydrophilic coatings 5.16.1 Hydrophilic coatings 5.16.2 Hydrophobic coatings 5.16.2.1 Properties 5.17 Superhydrophobic coatings 5.17.1 Properties 5.17.1.1 Anti-microbial use

6 COMPANY PROFILES

7 REFERENCES

For more information about this report visit https://www.researchandmarkets.com/r/wmf9q

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2021 Outlook on the Packaging Nanotechnology and Nanomaterials Market - Key Drivers and Trends - GlobeNewswire

DUBLIN--(BUSINESS WIRE)--The "The Global Market for Nanotechnology and Nanomaterials in Packaging" report has been added to ResearchAndMarkets.com's offering.

Nanomaterials have already been commercialized at various stages of the packaging supply chain from food storage to traceability and tracking. Their enhanced properties, such as UV protection, barrier to moisture, gases and volatile components, mechanical strength, significantly improve packaging materials.

Companies Mentioned

Nanomaterials-based packaging is used to:

The use of nanomaterials in packaging will play a significant role in:

Nanomaterials utilized in packaging include:

Report contents include:

Key Topics Covered:

1 INTRODUCTION

2 RESEARCH METHODOLOGY

3 EXECUTIVE SUMMARY

3.1 Market drivers and trends in packaging

3.1.1 Antimicrobial packaging for food safety

3.1.2 Active packaging

3.1.3 Intelligent/smart packaging

3.1.4 Biobased packaging and sustainable packaging

3.1.5 Improved barrier function to increase shelf life

3.2 Market challenges and risk assessment

3.3 Global market demand and revenues for nanopackaging

4 TYPES OF PACKAGING

4.1 Barrier films and coatings

4.2 Antimicrobial active packaging

4.3 Anti-counterfeit packaging

4.4 Intelligent packaging

5 NANOMATERIALS USED IN PACKAGING

5.1 Composites

5.2 Coatings and films

5.3 Nanosensors

5.4 Cellulose nanofibers (CNFs)

5.4.1 Paper and board packaging

5.4.2 Barrier films

5.4.3 Antimicrobial packaging

5.5 Cellulose nanocrystals

5.5.1 Properties

5.5.2 Applications

5.5.2.1 Barrier films

5.5.2.2 Anti-counterfeiting films

5.5.2.3 Antimicrobial coatings

5.6 Bacterials nanocellulose (BNC)

5.6.1 Applications

5.7 Graphene

5.7.1 Properties

5.7.2 Barrier films for food packaging

5.7.3 Anti-bacterial activity

5.7.4 Anti-viral activity

5.7.4.1 Reduced graphene oxide (rGO)

5.8 Nanosilver

5.8.1 Properties

5.8.2 Antimicrobial and antiviral activity

5.8.3 Nanosilver in packaging

5.9 Nanosilica

5.9.1 Properties

5.9.2 Antimicrobial and antiviral activity

5.9.3 Easy-clean and dirt repellent

5.10 Zinc oxide nanoparticles

5.10.1 Properties

5.10.2 Antimicrobial packaging films

5.11 Carbon nanotubes

5.11.1 Properties

5.11.2 Antimicrobial activity

5.12 Chitosan nanoparticles

5.12.1 Antimicrobial coatings

5.12.2 Packaging coatings and films

5.13 Nanoclays

5.13.1 Properties

5.13.2 Barrier films

5.13.3 Nanoclay producers

5.14 Titanium dioxide nanoparticles

5.14.1 Properties

5.14.2 Antibacterial films

5.15 Copper nanoparticles

5.15.1 Properties

5.15.2 Anti-microbial coatings

5.16 Hydrophobic and hydrophilic coatings

5.16.1 Hydrophilic coatings

5.16.2 Hydrophobic coatings

5.16.2.1 Properties

5.17 Superhydrophobic coatings

5.17.1 Properties

5.17.1.1 Anti-microbial use

6 COMPANY PROFILES

7 REFERENCES

For more information about this report visit https://www.researchandmarkets.com/r/g9vux7

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Global Market for Nanotechnology and Nanomaterials in Packaging - Reduce Reliance on Petroleum-based Packaging - ResearchAndMarkets.com - Business...