Category Archives: Nanotechnology

Rice husk, a renewable resource produced as a waste product of rice milling, is used for a plethora of diverse applications in the personal care market. This engagement helps accelerate Dows commitment towards a bio-based offering. The newly added ingredient sold under the Dow trademark EcoSmooth Rice Husk Cosmetic Powder - delivers optical benefits and a unique sensorial experience for consumers in skin care, hair care and color cosmetic applications.

"Dow's partnership with BSB Nanotechnology shines a light on how we continue to deliver on our commitment to transition towards a circular and low-carbon personal care offering while fostering valuable relationships with industry trailblazers," said Isabel Almiro do Vale, global marketing and strategy director for Dow Personal Care. "This partnership is another significant milestone allowing Dow to expand its portfolio of products that enable eco-conscious claims, prioritizing solutions that deliver high-quality, benefits backed by science."

The product of choice for the eco-conscious consumer, the EcoSmooth Rice Husk Cosmetic Powder is the exclusive ingredient to make its debut between the two parties. Compiled from non-GMO natural sources, this silica powder is upcycled from rice husk, a by-product from agriculture. It delivers a smooth feel combined with optical benefits like blurring imperfections and mattifying skin.

This agreement signifies not only the first step towards a collaboration between Dow and BSB in the personal care sector but has also opened new pathways to other business sectors within Dow where BSBs bio-based rice husk silica can offer sustainability and multifunctionality, said Hung Nguyen, CEO of BSB. BSB will continue to create more innovative and green solutions for the world and offer these additives through global partners like Dow.

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Dow Announces Partnership with BSB Nanotechnology to Expand Bio-based, and Low-carbon Ingredients in the Global Personal Care Market - Statnano

In brief

By National Law No. 27,685 ("Law"), published on 16 September 2022, Law No. 26,270 was amended, expanding throughout the entire national territory the promotion regime for the development and production of modern biotechnology and nanotechnology. The regime will be in force up to 31 December 2034.

The Law set forth the following tax benefits: (i) the accelerated amortization of the capital goods, special equipment, and parts or elements forming those new goods, which were acquired for the project; (ii) the anticipated refund for the VAT corresponding to the goods acquired for the project; and (iii) the granting of a tax credit bond equivalent to 50% of expenses paid for hiring investigative and development services from institutions that are part of the national public system of science, technology and innovation. The tax credit bond will be valid for 10 years and it will only be transferable once.

In focus

The Law includes the concept of nanotechnology in the definition of "Modern Biotechnology", which means every technological application based on rational knowledge and scientific principles that derive from biology, biochemistry, microbiology, bioinformatics, molecular biology and genetic engineering, or that uses live organisms or parts of them, either for the production of goods and services, or for the substantial improvement of products and productive processes.

The Law set forth the following tax benefits:

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Argentina: Promotion of modern biotechnology and nanotechnology - Lexology

LONDON, Sept. 22, 2022 (GLOBE NEWSWIRE) -- According to The Business Research Companys research report on the filters market, nanotechnology is gaining popularity in the filters market trends. Nanotechnology in filters refers to the use of nanomaterials and nanoparticles to improve the performance of filters. One such filter system based on nanotechnology is a nanotech-based water purification system that is thought to be modular, highly efficient, and cost-effective compared to traditional water filtration procedures. These systems are made up of carbonaceous nanomaterials, metal oxide nanoparticles, zeolites, and other nanomaterials that are integrated into a polymeric matrix to improve the performance of traditional polymeric membranes. For instance, in February 2020, Parker Hannifin Corporation, a US-based motion and control technology company, and its Industrial Gas Filtration and Generation Division introduced ProTura SB Nano Pleated Filters, which is a dust collection filter used in a variety of applications. The ProTura SB Nano Pleated Filters use advanced nanofibre filtration technology whose filters are made from a 100% synthetic base media with a proprietary nanofiber layer applied to the collection surface, designed for demanding applications.

Request for a sample of the global filters market report

The global filters market size is expected to grow from $68.28 billion in 2021 to $72.23 billion in 2022 at a compound annual growth rate (CAGR) of 4.95%. The global filters market share is expected to grow to $94.30 billion in 2026 at a compound annual growth rate (CAGR) of 6.89%.

The rapidly increasing adoption of air purifiers due to increasing toxic gas release in the air causing severe health hazards is expected to fuel the filter market demand. Air toxics cause a broad range of health effects depending on the specific pollutant, the amount of exposure, and how people are exposed. People inhaling high levels of air toxics experience nose, throat and eye irritation, and breathing difficulty. Long term exposure to air toxics such as carbon monoxide, nitrogen oxides, lead and others can cause cancer and lead to a long-term damage to the respiratory, neurological, immune, and reproductive systems. For instance, according to a study from British Lung Foundation (BLF) and Asthma UK published in February 2021, nearly 6 million people aged over 65 in England are at higher risk of lung damage and asthma attacks because of toxic air. This rise in toxic air would increase the demand for air purifies thus driving the filters market growth.

Major players in the filters market are 3M Company, Airex Filter Corp, Koch Filter, Freudenberg Filtration Technologies SE & Co KG, Donaldson Company Inc, Camfil AB, Parker Hannifin Corp, DENSO Corp, Clark Air Systems, Spectrum Filtration Pvt Ltd, MANN+HUMMEL, Clear Edge Filtration Group, Pall Corporation, Danaher Corporation, TFI Filtration (India) Private Limited and Aarkays Air Equipment Private Limited.

The global filters market is segmented by product into fluid filters, ICE filters, air filters; by distribution channel into offline stores, online stores; by application into motor vehicles, consumer goods, utilities, industrial and manufacturing, others.

Asia-Pacific was the largest region in the global filters market in 2021. The regions covered in the global filters market report are Asia-Pacific, Western Europe, Eastern Europe, North America, South America, the Middle East, and Africa.

Filters Global Market Report 2022 Market Size, Trends, And Global Forecast 2022-2026 is one of a series of new reports from The Business Research Company that provide filters market overviews, filters market analyze and forecast market size and growth for the whole market, filters market segments and geographies, filters market trends, filters market drivers, filters market restraints, filters market leading competitors revenues, profiles and market shares in over 1,000 industry reports, covering over 2,500 market segments and 60 geographies.

The report also gives in-depth analysis of the impact of COVID-19 on the market. The reports draw on 150,000 datasets, extensive secondary research, and exclusive insights from interviews with industry leaders. A highly experienced and expert team of analysts and modelers provides market analysis and forecasts. The reports identify top countries and segments for opportunities and strategies based on market trends and leading competitors approaches.

Not the market you are looking for? Check out some similar market intelligence reports:

Air Purifiers Global Market Report 2022 By Technology (HEPA Filter, Activated Carbon), By Type (Dust Collectors, Fume & Smoke Collectors), By End-User (Residential, Commercial) Market Size, Trends, And Global Forecast 2022-2026

Water Purifiers Global Market Report 2022 By Technology Type (RO Water Purifier, UV Water Purifier, Gravity-Based Water Purifier), By End-User (Industrial, Commercial, Household), By Distribution Channel (Retail Stores, Direct Sales, Online), By Portability (Portable, Non-Portable), By Device Type (Wall Mounted, Countertop, Tabletop, Faucet-Mounted, Under-The-Sink (UTS)) Market Size, Trends, And Global Forecast 2022-2026

Nanotechnology Services Global Market Report 2022 - By Service (Research And Development, Information Tracking, Technology Scouting, Standardisation, Regulation Briefings), By Application (Pharmaceuticals, Medical Equipment, Food And Beverages, It), By Provider (Large Enterprise, Small And Medium Enterprise) - Market Size, Trends, And Global Forecast 2022 - 2026

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Companies In The Filters Market Are Incorporating Nanotechnology To Improve The Efficiency Of The Filters As Per The Business Research Company's...

DUBLIN--(BUSINESS WIRE)--The "Saudi Arabia Nanotechnology in Cosmetics Market: Prospects, Trends Analysis, Market Size and Forecasts up to 2028" report has been added to ResearchAndMarkets.com's offering.

The country research report on Saudi Arabia nanotechnology in cosmetics market is a customer intelligence and competitive study of the Saudi Arabia market. Moreover, the report provides deep insights into demand forecasts, market trends, and, micro and macro indicators in the Saudi Arabia market.

Also, factors that are driving and restraining the nanotechnology in cosmetics market are highlighted in the study. This is an in-depth business intelligence report based on qualitative and quantitative parameters of the market. Additionally, this report provides readers with market insights and a detailed analysis of market segments to possible micro levels. The companies and dealers/distributors profiled in the report include manufacturers & suppliers of the nanotechnology in cosmetics market in Saudi Arabia.

Segments Covered

The report on Saudi Arabia nanotechnology in cosmetics market provides a detailed analysis of segments in the market based on products, and nanomaterial.

Segmentation Based on Products

Segmentation Based on Nanomaterial

Highlights of the Report

The report provides detailed insights into:

1) Demand and supply conditions of the nanotechnology in cosmetics market

2) Factor affecting the nanotechnology in cosmetics market in the short run and the long run

3) The dynamics including drivers, restraints, opportunities, political, socioeconomic factors, and technological factors

4) Key trends and future prospects

5) Leading companies operating in the nanotechnology in cosmetics market and their competitive position in Saudi Arabia

6) The dealers/distributors profiles provide basic information of top 10 dealers & distributors operating in (Saudi Arabia) the nanotechnology in cosmetics market

7) Matrix: to position the product types

8) Market estimates up to 2028

The report answers questions such as:

1) What is the market size of the nanotechnology in cosmetics market in Saudi Arabia?

2) What are the factors that affect the growth in the nanotechnology in cosmetics market over the forecast period?

3) What is the competitive position in Saudi Arabia nanotechnology in cosmetics market?

4) What are the opportunities in Saudi Arabia nanotechnology in cosmetics market?

5) What are the modes of entering Saudi Arabia nanotechnology in cosmetics market?

Key Topics Covered:

1. Report Overview

2. Executive Summary

3. Market Overview

3.1. Introduction

3.2. Market Dynamics

3.2.1. Drivers

3.2.2. Restraints

3.2.3. Opportunities

3.2.4. Challenges

3.3. PEST-Analysis

3.4. Porter's Diamond Model for Saudi Arabia Nanotechnology in Cosmetics Market

3.5. IGR-Growth Matrix Analysis

3.6. Competitive Landscape in Saudi Arabia Nanotechnology in Cosmetics Market

4. Saudi Arabia Nanotechnology in Cosmetics Market by Products

4.1. Hair Care

4.2. Skin Care

4.3. Make-up

4.4. Sexual Well-being

4.5. Others

5. Saudi Arabia Nanotechnology in Cosmetics Market by Nanomaterial

5.1. Liposomes

5.2. Nanoemulsions

5.3. Nanocapsules

5.4. Solid Lipid Nanoparticles

5.5. Nanosilver and Nanogold

5.6. Others

6. Company Profiles

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

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Insights on the Saudi Arabia Nanotechnology in Cosmetics Industry to 2028 - by Product and Nanomaterial - ResearchAndMarkets.com - Business Wire

Sep 23, 2022(Nanowerk News) Since the initial discovery of what has become a rapidly growing family of two-dimensional layered materials called MXenes in 2011, Drexel University researchers have made steady progress in understanding the complex chemical composition and structure, as well as the physical and electrochemical properties, of these exceptionally versatile materials. More than a decade later, advanced instruments and a new approach have allowed the team to peer within the atomic layers to better understand the connection between the materials form and function.In a paper recently published in Nature Nanotechnology ("Oxycarbide MXenes and MAX phases identification using monoatomic layer-by-layer analysis with ultralow-energy secondary-ion mass spectrometry"), researchers from Drexels College of Engineering and Polands Warsaw Institute of Technology and Institute of Microelectronics and Photonics reported a new way to look at the atoms that make up MXenes and their precursor materials, MAX phases, using a technique called secondary ion mass spectrometry.In doing so, the group discovered atoms in locations where they were not expected and imperfections in the two-dimensional materials that could explain some of their unique physical properties. They also demonstrated the existence of an entirely new subfamily of MXenes, called oxycarbides, which are two-dimensional materials where up to 30% of carbon atoms are replaced by oxygen.A new technique using secondary-ion mass spectrometry has given Drexel researchers a fresh look at the two-dimensional materials they have been studying for more than a decade. (Image: Drexel University)This discovery will enable researchers to build new MXenes and other nanomaterials with tunable properties best suited for specific applications from antennas for 5G and 6G wireless communication and shields for electromagnetic interference; to filters for hydrogen production, storage and separation; to wearable kidneys for dialysis patients.Better understanding of the detailed structure and composition of two-dimensional materials will allow us to unlock their full potential, said Yury Gogotsi, PhD, Distinguished University and Bach professor in the College, who led the MXene characterization research. We now have a clearer picture of why MXenes behave the way they do and will be able to tailor their structure and therefore behaviors for important new applications.Secondary-ion mass spectrometry (SIMS) is a commonly used technique to study solid surfaces and thin films and how their chemistry changes with depth. It works by shooting a beam of charged particles at a sample, which bombards the atoms on the surface of the material and ejects them a process called sputtering. The ejected ions are detected, collected and identified based on their mass and serve as indicators of the composition of the material.While SIMS has been used to study multi-layered materials over the years, the depth resolution has been limited examining the surface of a material (several angstroms). A team led by Pawel Michalowski, PhD, from Polands Institute of Microelectronics and Photonics, made a number of improvements to the technique, including adjusting the angle and energy of the beam, how the ejected ions are measured; and cleaning the surface of the samples, which allowed them to sputter samples layer by layer. This allowed the researchers to view the sample with an atom-level resolution that had not been previously possible.The closest technique for analysis of thin layers and surfaces of MXenes is X-ray photoelectron spectroscopy, which we have been using at Drexel starting from the discovery of the first MXene, said Mark Anayee, a doctoral candidate in Gogotsis group. While XPS only gave us a look at the surface of the materials, SIMS lets us analyze the layers beneath the surface. It allows us to remove precisely one layer of atoms at a time without disturbing the ones beneath it. This can give us a much clearer picture that would not be possible with any other laboratory technique.As the team peeled back the upper layer of atoms, like an archaeologist carefully unearthing a new find, the researchers began to see the subtle features of the chemical scaffolding within the layers of materials, revealing the unexpected presence and positioning of atoms, and various defects and imperfections.We demonstrated the formation of oxygen-containing MXenes, so-called oxycarbides. This represents a new subfamily of MXenes which is a big discovery! said Gogotsi. Our results suggest that for every carbide MXene, there is an oxycarbide MXene, where oxygen replaces some carbon atoms in the lattice structure.Since MAX and MXenes represent a large family of materials, the researchers further explored more complex systems that include multiple metal elements. They made several pathbreaking observations, including the intermixing of atoms in chromium-titanium carbide MXene which were previously thought to be separated into distinct layers. And they confirmed previous findings, such as the complete separation of molybdenum atoms to outer layers and titanium atoms to the inner layer in molybdenum-titanium carbide.All of these findings are important for developing MXenes with a finely tuned structure and improved properties, according to Gogotsi.We can now control not only the total elemental composition of MXenes, but also know in which atomic layers the specific elements like carbon, oxygen, or metals are located, said Gogotsi. We know that eliminating oxygen helps to increase the environmental stability of titanium carbide MXene and increase its electronic conductivity. Now that we have a better understanding of how much additional oxygen is in the materials, we can adjust the recipe so to speak to produce MXenes that do not have it, and as a result more stable in the environment.The team also plans to explore ways to separate layers of chromium and titanium, which will help it develop MXenes with attractive magnetic properties. And now that the SIMS technique has proven to be effective, Gogotsi plans to use it in future research, including his recent $3 million U.S. Department of Energy-funded effort to explore MXenes for hydrogen storage an important step toward the development of a new sustainable energy source.In many ways, studying MXenes for the last decade has been mapping uncharted territory, said Gogotsi. With this new approach, we have better guidance on where to look for new materials and applications.

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New technique allows researchers to scrape beyond the surface of nanomaterials - Nanowerk

Sep 23, 2022(Nanowerk News) What do clouds, televisions, pharmaceuticals, and even the dirt under our feet have in common? They all have or use crystals in some way. Crystals are more than just fancy gemstones. Clouds form when water vapor condenses into ice crystals in the atmosphere. Liquid crystal displays are used in a variety of electronics, from televisions to instrument panels. Crystallization is an important step for drug discovery and purification. Crystals also make up rocks and other minerals. Their crucial role in the environment is a focus of materials science and health sciences research.Scientists have yet to fully understand how crystallization occurs, but the importance of surfaces in promoting the process has long been recognized. Research from Pacific Northwest National Laboratory (PNNL), the University of Washington (UW), and Durham University sheds new light on how crystals form at surfaces.Their results were published in Science Advances ("Hydroxide films on mica form charge-stabilized microphases that circumvent nucleation barriers").Aluminum hydroxide, depicted here in orange, undergoes fluctuations between structures before forming an ordered crystal. (Illustration by Nathan Johnson, Pacific Northwest National Laboratory)Previous studies on crystallization led scientists to form the classical nucleation theorythe predominant explanation for why crystals begin to form, or nucleate. When crystals nucleate, they begin as very small ephemeral clusters of just a few atoms. Their small size makes the clusters extremely difficult to detect. Scientists have managed to collect only a few images of such processes.New technologies are making it possible to visualize the crystallization process as never before, said PNNL Physical Sciences Division Chemist Ben Legg. He partnered with PNNL Battelle Fellow and UW Affiliate Professor James De Yoreo to do just that. With the help of Professor Kislon Voitchovsky from Durham University in England, they used a technique called atomic force microscopy to watch the nucleation of an aluminum hydroxide mineral on a mica surface in water.Mica is a common mineral, found in everything from drywall to cosmetics. It often provides a surface for other minerals to nucleate and grow. For this study, however, its most important feature was its extremely flat surface, which allowed researchers to detect the few-atom clusters as they formed on the mica.What Legg and De Yoreo observed was a crystallization pattern that was not expected from the classical theory. Instead of a rare event in which a cluster of atoms reaches a critical size and then grows across the surface, they saw thousands of fluctuating clusters that coalesced into an unexpected pattern with gaps that persisted between crystalline "islands."After careful analysis of the results, the researchers concluded that while certain aspects of the current theory held true, ultimately their system followed a nonclassical pathway. They attribute this to electrostatic forces from charges on the mica surface. Because many types of materials form charged surfaces in water, the researchers hypothesize that they observed a widespread phenomenon and are excited to look for other systems where this nonclassical process might occur.Assumptions from classical nucleation theory have far-reaching implications in disciplines ranging from materials science to climate prediction, said De Yoreo. The results from our experiments can help produce more accurate simulations of such systems.

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Atomic-scale imaging reveals a facile route to crystal formation - Nanowerk