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sevastiel · 3 months ago

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Current Sevastiel Lore Theories List

(Misc collection of all my interpretations/theories on lore thus far. Warning, theres a LOT. Primary focus on void functions and infestation functions.)

Techrot feed off of energy moreso than they do metal, metal is mostly a conductor and a material that can be used to create more resilient and complex structures. This is why they Can consume machines. (Partially proven correct)

The infestation uses a powerful base to dissolve through things, not an acid. Allows less ultimately destructive techniques and minimum energy loss. Also makes scaldra's use of specifically acid more understandable.

The infestation do not necessarily require a protein base to create their bio... stuff. This is why they can infest, say, a planet, and somehow have the biomass to cover the entire surface without an entire surface covering's worth of protein based life forms. What they do use is absolutely beyond me. Current guess is probably silicon for structure base, as carbon is organic.

Everyone has a bit of void energy inside of them that is modified by their experience. That is what a Soul is, and why people echo in the void after their death. (Consider the Kim discussion with eleanor about the void and the afterlife)

Void energy past a very small amount is very difficult to hold onto if you arent modified to be able to hold more of it, but if you are imbued with more than youre regularly able to hold onto, it can/will fuck up your soul. This is why people who interact with the void go insane, instead of just getting powers.

The adults on the zariman were given an understanding of both the nature of eternity and also what the tenno would become, and how much KILLING they would do. Also, that the tenno would be far more complete void vessels, which could, if they could consume them, possibly allow them to contain more power/and/or not be destroyed by the void

Tenno blood could be used as kuva. The physical aspect of the tenno is, at very least, VERY well equipped to hold onto void energy and thusly ingesting it might spread the effect. (No it wont lol) Queens wanted to transfer into a tenno because of the void capacity.

Red kuva primarily fucks with your mental aspect of the soul(allows the orokin transfer of consiousness) whereas blue kuva fucks with your physical aspect of the soul (allows shapeshifting, in lore) and thusly purple kuva could probably allow you to just Become Anyone

Everything is essentially the void. Reality is held together, much like duviri, by the expectation and understanding of everyone that exists within it. Common consensus decides that the sun keeps rising/that gravity continues to work.

The physical look of the tenno/drifter is entirely based on their perception of self. This is why we can change our cosmetics/gender/voice on a literal whim, and ultimately means that we are not really limited to human forms. Conceptual em-body-ment :)

Void tongue is not an actual language, per se. Each word is more or less simply describing a concept/idea that is taken from across externalism, which is why each word is described with a poem, and not a regular definition. Its like saying 'water' and truly meaning/referring to all of water, everything that has experienced it, every emotion that anyone has ever had about it, every moment that it has existed, and every interaction that it has had with every other thing. This is why void tongue drives you mad to understand it, because it just pushes your mind so far beyond its limits. Like an ant suddenly being raised to the awareness of a human with all the understanding we have of our world, the knowledge of taxes and society and the way people act, all while still limited by the few neurons of an ants brain. The soul can retain that information, your body/brain cannot, and the discrepancy is probably upsetting.

The mind is the connection point between the soul and the body, the void and the physical world we've made, and that is why it is capable of affecting the void at all.

Because our reality is held together by what we think it is, that order extends to all of it, even things that we inherently think of as chaotic, like our energy. Our energy is VERY orderly, and it tends to exert that order on things it comes in contact with. This is why the murmur and void enemies are weak to radiation and electrical damage, because its a high amount of ordered energy that comes up against energy that is only chaotic because nobodys gotten around to ordering it up yet.

Transference works through the manipulation of electrical systems across gaps translated through the void. Void energy to open up the link is necessary. This is why warframes are very Much Metal, and why transference bolts are metal. Because that shit is conductive. It allows us to literally mirror our brain signals inside of a warframe's brain, and visa versa. This is why transference is hard to fight off, and why a stronger will allows domination over the other. Orokin transference probably allows them to cheat at this by amplifying their signals a few times through manipulation of void energy.

Void portals need both a void energy component and an order energy component. The void energy to open the tear in reality, the order energy to pave a way through the void to another place. Like digging a tunnel in sand, and using wooden planks to line the walls to keep it from collapsing. This is why all the void portals we see/use often are tied to large energy generators, and why albrecht needed a nuclear reactor detonation to have enough power to time travel. You need a LOT of power to travel the void safely unless you're of the void, like a tenno is.

Archon shards are 'anti-entropic radiation', which is, I assume, the sentient's way of dealing with the void radiation that would end their race otherwise. The void is said to be both entropy and anti-entropy, it decays, it creates, yadda yadda, so if you order it to be specifically non-entropic through some process, you can basically lock it into one manageable form. Its still void energy, which is why they're not commonly used outside of warframes and archons, but its still a containment method. I wonder if Albrecht is at all curious about how the sentients in tau managed to find ways to contain void energy. Seems it could be useful to him.

Archon shards are not perfect, as we can see them visibly leaking void particle styled energy, and the 'effect' we get from an archon shard is due to a specific desire/idea that the crystalized energy is centered around being. Tauforged shards have more energy. if they are described as anti-entropic, we must assume taht means they are at least mostly so. So, most of the energy that escapes gets pulled back in, and we use the liiittle bit that we siphon off the top/that leaks out. Like drinking from a recycling water fountain but infinitely less gross.

Void energy tends to either pull in more void energy, or de-order the energy around it. Chaos begets chaos, entropy begets entropy.

The albrecht membrane is literally the separation between what is and what we think is.

The skin of a warframe is bolstered by multi-cell-wall layers, (The tougher/more leathery bits, maybe 2? the more flexible bits maybe just 1? unsure. Not a biologist, just talked with some.) growths akin to a horses hooves but with a more flexible structure, (the toughest bits) pleeenty of lignin, a thick layer of skin/padding overall, and an underlayer beneath the skin of a thick, non-Newtonian liquid. Likely either highly conductive or held within a lattice of highly conductive tissues, possibly incorporating metals like gold into the structure either held between cells or somehow within them. The outer layer offers us our slash resistance, the fluid provides both the impact resistance and the energy channels for our energy to go through, and is what makes up our emissive effects. Also is why all the orokin towers have that layer of golden veining beneath the fat and flesh, and are able to 1, bleed, and 2, transmit/control energy.

Warframes have extra organs/mechanisms for storing both bioelectricity and a pinch of void energy. Void energy draws in itself, but might struggle to do so when surrounded by regular energy, which keeps it contained and harmless. Most of the warframe's abilities are pulled from the void energy collective, physical functions are pulled from the bioelectricity collective. Shields are probably fueled from the bioelectricity, and abilities are from the void. (theres no physical way at all ever to generate enough energy to unleash a portal to the sun at whim) This is why we naturally have no/very low energy regen, and start missions at very little energy, because holding a high amount of void energy in general would be Extremely dangerous.

Energy orbs are kinda just The Power That Makes Up That Guys's Fucking Soul. Consume it to use void magic. Yippee.

Overguard is made up of void energy. (glances at kullervo) It allows the haver to simply Resist shit because with that much void energy around you, it can 1, nullify energy that comes into contact with it, (stop bullets by instantly countering out kinetic energy, absorb the impact of a fall, etc etc) and 2, it sort of just alters your percieved 'existence' when it comes to other void things. Like, a void ability will just blitz through or slide off, which is why we cant target overguarded enemies with abilities. Their physical location exists, but their physical energies do not.

Eximus units are probably people who have specialized units of programmed void energy that they can utilize. I dont imagine they last long power-wise or mentally.

Infested eximus units probably have the same separation between void energy organs and bio-electric organs as warframes do.

The infestations various hiveminds came to be because it consumed living beings with souls/connections to the void, and, as void energy risks destroying regular energy, and it NEEDS the regular energy to exists, it probably had to contain it carefully. that adds up, and all those souls together, all those memories, all that consciousness, would form the hivemind.

Wally/all of the clones are a decentralized hivemind. All have access to the same knowledge/shit, but each individual facet/clone creation is just that, its own facet on the same gem.

Thrax is the drifter's void clone, but is the natural one that happened not because the wally collective made it, but the result of the drifter really REALLY wanting someone to protect them/a friend, and only having themselves. A shadow cast with natural light, instead of a shadow cast by wally pointing a flashlight at someone.

Warframes feed through the helminth, which is why we dont need to feed them but do need to stuck up the wall mouth, and why their backs always look so rough.

The warframes we pilot are shadows of the originals, with the orokin having devised ways to sever parts of the brain to reduce the likelihood of them having consciousness while retaining their capacity for memory.

The mod system/arcanes are a mixture of a physical item, like a little chip, and a charge of stabilized void energy thats set to do a certain thing. Like an archon shard, but less... Archon-y. And way less powerful. Powering up the mod is done by increasing the charge of energy within the chip, which increases its effects on reality. Stick those mfers in the warframe's spine or something. The physical aspect of the modding system is why we cannot alter the protoframe's modding, because Ow.

Time travel works by anchors if you dont want to do it the regular way. Go into the void and pray you can keep your destination in mind. (Proven correct, thank fucking god)

you could kill a tenno with a sufficient amount of energy.

The ascaris probably worked on the same wavelength as transference. (metaphorically) And probably both induced brain-wave style electrical waves and charges of a high enough power, siphoned from the warframe's own energy supplies, to eat through the void energy.

#warframe #These are all entirely my lore interpretations #and I will likely update this list as time goes on.#For Later

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originalcreatorstarlight · 2 months ago

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Girls Frontline Egyptian character oc that I made 🇪🇬

I'm an Egyptian I'm a fan of girls Frontline game and the anime I was disappointed when they didn't make an Egyptian character or any Middle Eastern characters expect for Negev so I made an OC of how I imagine her in my head! 💛 Here's some things you should know about her.I'm so glad you love her! Based on her design and vibe, here’s a profile that fits her perfectly:

Name: Leila Nasr (ليلى نصر)

Age: 21

Background: Leila was born in Alexandria, Egypt, and raised in a family with deep military roots. Sharp-minded and fiercely independent, she joined the T-Doll program to defend her homeland and preserve its rich heritage.

Role: Designated marksman and relic recovery specialist. She’s often sent on missions involving ancient tech and desert operations.

Special Traits:

Her Eye of Ra makeup isn’t just style—it helps her interface with old-world systems.

She favors modified Egyptian firearms like a customized Hakim rifle for precision work, but she’s fluent with AKs too.

Fluent in Arabic, English, and ancient hieroglyphic code.

Here’s a short character bio and mission log entry for Leila Nasr:

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Name: Leila Nasr

Age: 21

Origin: Alexandria, Egypt

Affiliation: Griffin & Kryuger T-Doll Division – MENA Sector

Designation: Tactical Doll (T-Doll) – Marksman / Intel Retrieval

---

Background:

Leila Nasr was built with combat-grade AI enhanced by experimental neural data from elite Egyptian intelligence operatives. Her design was inspired by Egypt's fierce warrior queens and her programming includes detailed cultural archives, making her highly valuable in archaeological recon missions. Leila volunteered for activation during the “Red Sands Incident” after rogue AI units began disturbing tomb sites across the Sahara.

Despite her serious nature, she often recites Arabic poetry during downtime, and wears a pendant said to contain real sand from the Valley of the Kings.

---

Combat Role:

Long-range precision shots

Recon and sabotage

Tech decryption (specialized in pre-war Egyptian tech)

---

Mission Log – Entry 047: “Echoes Beneath Giza”

> "0100 hours. Desert winds hit like blades. We approached the ruin with zero drone coverage—jammers were already active. My sensors picked up heat signatures under the tomb's surface—definitely not human. The glyphs on the wall lit up the moment I stepped inside. Someone, or something, wanted me there. HQ thinks this is just another raid. They're wrong. This place remembers me... and it's calling me home."

---

Feel free to make drawings or fanart of her and hey if the official Girls Frontline see this please put her in the game lol 🇪🇬🙂‍↕️

#girlsfrontline #negev #Egypt #Egyptian #oc #tumblr fyp

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businessindustry · 3 days ago

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Acrylate Monomers Market Share, Trends and Forecast Report by 2025-2033

The Reports and Insights, a leading market research company, has recently releases report titled “Acrylate Monomers Market: Global Industry Trends, Share, Size, Growth, Opportunity and Forecast 2025-2033.” The study provides a detailed analysis of the industry, including the global Acrylate Monomers Market share, size, trends, and growth forecasts. The report also includes competitor and regional analysis and highlights the latest advancements in the market.

Report Highlights:

How big is the Acrylate Monomers Market?

The global acrylate monomers market was valued at US$ 10,562.7 Million in 2024 and is expected to register a CAGR of 5.3% over the forecast period and reach US$ 16,812.4 Million in 2033.

What are Acrylate Monomers?

Acrylate monomers are a class of reactive chemicals derived from acrylic acid or methacrylic acid, characterized by a vinyl group that enables polymerization. They serve as key building blocks in the production of various polymers and resins, widely used in adhesives, coatings, sealants, and biomedical applications. These monomers offer properties such as high durability, UV resistance, and flexibility, making them essential in industries like automotive, electronics, and healthcare.

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What are the growth prospects and trends in the Acrylate Monomers industry?

The acrylate monomers market growth is driven by various factors and trends. The acrylate monomers market is experiencing significant growth, driven by increasing demand in adhesives, coatings, sealants, and polymer manufacturing across industries such as automotive, construction, and healthcare. Factors like rising urbanization, infrastructure development, and advancements in UV-curable coatings are fueling market expansion. Additionally, the shift towards sustainable and bio-based acrylates is gaining traction due to environmental concerns and stringent regulations. Asia-Pacific dominates the market, led by rapid industrialization in China and India, while North America and Europe witness steady demand driven by innovations in high-performance materials. However, volatility in raw material prices and regulatory challenges may impact growth. Hence, all these factors contribute to acrylate monomers market growth.

What is included in market segmentation?

The report has segmented the market into the following categories:

By Product Type

Acrylic Acid-Based Monomers

Glacial Acrylic Acid

Technical Acrylic Acid

Acrylate Esters

Methyl Acrylate (MA)

Ethyl Acrylate (EA)

Butyl Acrylate (BA)

2-Ethylhexyl Acrylate (2-EHA)

Specialty Acrylate Monomers

Hydroxyethyl Acrylate (HEA)

Hydroxypropyl Acrylate (HPA)

Glycidyl Acrylate

Carboxylic-Modified Acrylate

Phosphoric-Modified Acrylates

Bio-Based Acrylates

By Production Process

Petrochemical-Based Process

Propylene Oxidation

Acetylene Carbonylation

Bio-Based Production

Fermentation Process

Biomass-Derived Acrylic Acid

By Function

Crosslinking Agents

Surface Modification Additives

Thickening Agents

Weather-Resistant Polymers

Low Volatile Organic Compound (VOC) Formulations

Others

By Application

Paints, Coatings & Inks

Architectural Paints

Industrial Coatings

Automotive Coatings

Marine Coatings

Printing Inks

Wood Coatings

Adhesives & Sealants

Pressure-Sensitive Adhesives (PSA)

Construction Adhesives

Packaging Adhesives

Automotive Sealants

Plastics & Polymers

Polyacrylates

Copolymers & Homopolymers

Superabsorbent Polymers (SAP)

Water Treatment Chemicals

Flocculants & Coagulants

Dispersants

Corrosion Inhibitors

Others

Detergents & Cleaning Products

Liquid Laundry Detergents

Dishwashing Liquids

Surface Cleaners

Construction & Infrastructure

Concrete Admixtures

Waterproofing Agents

Structural Sealants

Others

Electronics & Optical Applications

Textiles & Fibers

Healthcare & Personal Care Products

North America

United States

Canada

Europe

Germany

United Kingdom

France

Italy

Spain

Russia

Poland

Benelux

Nordic

Rest of Europe

Asia Pacific

China

Japan

India

South Korea

ASEAN

Australia & New Zealand

Rest of Asia Pacific

Latin America

Brazil

Mexico

Argentina

Middle East & Africa

Saudi Arabia

South Africa

United Arab Emirates

Israel

Rest of MEA

Who are the key players operating in the industry?

The report covers the major market players including:

BASF SE

Dow

Arkema

Evonik Industries AG

Mitsubishi Chemical Corporation

Synthomer plc

LG Chem Ltd.

Nippon Shokubai Co., Ltd.

Sumitomo Chemical Co., Ltd.

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#Acrylate Monomers Market share #Acrylate Monomers Market size #Acrylate Monomers Market trends

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anviduby · 17 days ago

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Textile Enzymes Market Growth Driven by Eco-Friendly Processing and Sustainable Manufacturing Practices

The global Textile Enzymes Market is experiencing significant growth, fueled by the industry's accelerating shift toward eco-friendly, sustainable, and low-impact manufacturing practices. Enzymes, as biological catalysts, are increasingly being adopted in the textile industry for their efficiency, environmental benefits, and ability to replace harsh chemicals in processes such as desizing, bio-polishing, scouring, and bleaching.

Understanding Textile Enzymes and Their Role

Textile enzymes are used during various stages of fabric manufacturing and finishing. The most commonly used enzymes in textile applications include:

Amylases (for desizing)

Cellulases (for bio-polishing and softening)

Catalases (for peroxide removal)

Laccases (for dyeing and bleaching)

Pectinases, lipases, and proteases (for scouring and fabric preparation)

These enzymes enable lower-temperature processing, reduce water and energy consumption, and minimize the need for toxic chemicals—making them an ideal alternative in an increasingly sustainability-focused industry.

Sustainability as a Growth Driver

Environmental concerns and the textile industry's reputation as a major polluter have compelled manufacturers to adopt greener alternatives. According to the World Bank, textile dyeing and treatment contribute to nearly 20% of global industrial water pollution. Enzymatic processing, by contrast, is biodegradable, non-toxic, and less resource-intensive, offering a compelling case for large-scale adoption.

Major brands and fashion retailers are also pushing the sustainability agenda. Companies like Levi's, H&M, and Patagonia have publicly committed to reducing water, chemical, and carbon footprints in their supply chains. As a result, textile manufacturers are under increasing pressure to transition toward enzyme-assisted textile processing to meet compliance and brand expectations.

Market Dynamics and Growth Outlook

The textile enzymes market is expected to grow at a CAGR of 5–7% over the next five years, according to industry forecasts. The demand is being driven by several interconnected trends:

Rising demand for organic and sustainable textiles, especially in North America and Europe.

Governmental regulations aimed at reducing chemical pollution and promoting green manufacturing.

Technological advancements in enzyme formulation and stability under diverse processing conditions.

Cost-saving advantages due to lower water and energy consumption in enzyme-based processes.

Additionally, enzyme-producing biotechnology companies such as Novozymes, DuPont, AB Enzymes, and Advanced Enzyme Technologies are expanding their product portfolios to cater specifically to textile industry requirements, including multi-enzyme complexes for improved efficiency and compatibility with modern industrial equipment.

Applications and Innovations

Desizing: Amylases are replacing synthetic agents for the removal of starch-based sizing materials, allowing a more biodegradable and less corrosive process.

Bio-polishing: Cellulases are widely used to enhance the fabric feel and appearance by removing microfibrils from cotton surfaces. This not only improves luster and softness but also minimizes pilling.

Bleaching and Dyeing: Catalases and laccases are being adopted to neutralize residual hydrogen peroxide and aid in dye bonding at lower temperatures, thus reducing water use and chemical load.

Wool Processing: Proteases are being utilized to modify wool surface properties, offering an environmentally safer alternative to traditional chlorine-based treatments.

Recent innovations have focused on enzyme blends and thermostable formulations that retain activity across a wide range of temperatures and pH levels. This enables seamless integration into existing textile processing lines without significant infrastructure overhaul.

Regional Trends

Europe is currently the leading market due to strict environmental regulations (such as REACH) and strong consumer demand for sustainable textiles.

Asia-Pacific, led by countries like China, India, and Bangladesh, is expected to witness the fastest growth due to the large-scale textile manufacturing base and increasing governmental push for greener industrial practices.

North America is seeing moderate growth, with emphasis on innovation, bio-based solutions, and the rising popularity of eco-conscious fashion.

Challenges to Adoption

Despite the promising growth, the textile enzymes market faces a few challenges:

Lack of awareness among small and medium-scale textile units in developing countries.

Cost sensitivity, especially in price-driven markets where traditional chemicals are still cheaper in the short term.

Enzyme stability and compatibility with high-speed industrial machinery or extreme processing conditions.

Overcoming these hurdles will require continued education, technological refinement, and strategic partnerships between enzyme developers and textile manufacturers.

Future Outlook

As sustainability becomes a non-negotiable part of global supply chains, textile enzymes are set to play an even more prominent role in reshaping the industry. The synergy between biotechnology and textiles opens avenues not just for environmentally safer production, but also for new product differentiation—such as enzyme-washed denim or naturally softened organic cotton.

In the years to come, innovations such as gene-edited enzymes, customized enzyme cocktails, and AI-driven process optimization will further accelerate the adoption of enzyme-based solutions in textile manufacturing. Stakeholders who invest early in these sustainable technologies are likely to gain competitive advantage both in terms of regulatory compliance and consumer preference.

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priteshwemarketresearch · 26 days ago

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Health-Conscious Consumers Fueling Corn Starch Market Growth

Global Corn Starch Market Overview: Size, Share, Trends, and Forecast to 2035

The Global Corn Starch market is anticipated to grow from US$ 20.34 billion in 2025 to approximately US$ 35.48 billion by 2035, reflecting a CAGR of 6.2% over the forecast period. This projected growth is largely fueled by corn starch’s wide-ranging applications in sectors such as food and beverages, pharmaceuticals, and textiles. Additionally, the increasing consumer focus on health and wellness has spurred demand for natural and clean-label ingredients, further boosting market expansion.

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The Corn Starch Market growth prospects remain robust due to a combination of technological advancements and increasing application diversity. Food and beverage remain the largest segment, with corn starch widely used for its thickening, stabilizing, and texturizing properties.

Beyond food, the pharmaceutical industry is tapping into corn starch as an excipient in tablet formulations. Meanwhile, the paper and textile industries use it for surface sizing and finishing processes. These sectors are expected to be key growth drivers in the coming years.

The shift toward bio-based and renewable resources is also creating opportunities for corn starch as a raw material in the production of bioplastics and biofuels. This adds another layer of Corn Starch Market potential, especially as governments worldwide push for more sustainable industrial practices.

Corn Starch Market Analysis by Application

A detailed Corn Starch Market analysis reveals its segmentation into native starch, modified starch, and sweeteners (such as high-fructose corn syrup). Each of these segments serves distinct purposes:

Native Starch: Primarily used in cooking and baking, providing texture and consistency to food products.

Modified Starch: Altered to improve shelf life, solubility, and stability, widely used in processed foods and industrial products.

Sweeteners: High-fructose corn syrup and other derivatives play a significant role in the beverage and confectionery industries.

Food and beverages dominate the market, but non-food applications are expanding steadily, especially in paper manufacturing and textile production.

Corn Starch Market Forecast: What Lies Ahead?

Looking ahead, the Corn Starch Market forecast suggests a CAGR of around X% between 2025 and 2035. Key drivers will include:

Rising demand for natural thickeners and binders.

Increasing use of biodegradable materials in packaging.

Innovation in starch modification techniques.

Government policies promoting sustainable alternatives to synthetic chemicals.

However, the market may face challenges related to raw material availability and competition from alternative starch sources like tapioca and potato starch.

Market Segments

By Type

Native Starch

Modified Starch

Sweeteners

By Form

Powder

Liquid

By Application

Food & Beverages

Animal Feed

Pharmaceuticals & Chemicals

Textile

Paper & Corrugates

Others

The Global Corn Starch Market is dominated by a few large companies

Archer Daniels Midland Company (ADM)

Cargill, Incorporated

Ingredion Incorporated

Tate & Lyle PLC

Roquette Frères S.A.

Tereos Syral S.A.S

Global Bio-chem Technology Group Company Limited

AGRANA Beteiligungs AG

Associated British Foods plc

Kent Corporation (Grain Processing Corporation)

Zhucheng Xingmao Corn Developing Co., Ltd.

COFCO Corporation

China National Starch & Chemical

Universal Starch-Chem Allied Ltd.

Gulshan Polyols Ltd.

Others

Key Takeaways:

The Corn Starch Market size is growing steadily, with robust demand from food and non-food sectors.

Corn Starch Market trends like clean labeling and bioplastics are reshaping industry dynamics.

The Corn Starch Market price remains sensitive to supply chain and crop yield factors.

Strong Corn Starch Market growth is expected, particularly in Asia-Pacific and sustainable industries.

A detailed Corn Starch Market analysis shows increasing segmentation and application diversity.

The Corn Starch Market forecast suggests sustained expansion through 2035 and beyond.

Frequently Asked Questions:

What is the market size of Corn Starch Market in 2025?

What is the growth rate for the Corn Starch Market?

Which are the top companies operating within the market?

Which region dominates the Corn Starch Market?

Related Report:

CBD infused confectionery market

Food Container Market

Microalgae Market

Final Thoughts: Unlocking Corn Starch Market Potential

The Corn Starch Market potential lies in its adaptability, eco-friendliness, and expanding industrial applications. As consumers and manufacturers alike continue to prioritize sustainability and natural ingredients, corn starch stands to benefit immensely.

Companies investing in R&D, optimizing production processes, and tapping into emerging markets will be best positioned to capitalize on the evolving landscape. With strong fundamentals and rising global interest, the Corn Starch Market is poised for a promising future.

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#Corn Starch Market Size #Corn Starch Market Share #Corn Starch Market Trends #Corn Starch Market Scope #Corn Starch Market Growth #Corn Starch Market Value #Corn Starch Market Analysis #Corn Starch Market Forecast

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i-nilesh-blog · 1 month ago

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The Flexible Fix: Analyzing the Elastic Adhesive Market

The elastic adhesive market, often overshadowed by its rigid counterparts, is a crucial segment of the broader adhesives and sealants industry. These flexible bonding solutions play an increasingly vital role across diverse sectors, offering durability, movement accommodation, and long-term performance. The Elastic Adhesive Market is expected to register a CAGR of 6% from 2025 to 2031, with a market size expanding from US$ XX million in 2024 to US$ XX Million by 2031.

One of the primary drivers of this market is the growing emphasis on durable and long-lasting construction materials. Elastic adhesives offer superior flexibility compared to rigid adhesives, allowing for movement between substrates without cracking or losing bond strength. This makes them ideal for sealing joints in building facades, bonding panels, and installing flooring, contributing to the longevity and structural integrity of constructions. The increasing focus on energy efficiency in buildings is also boosting demand for elastic sealants that prevent air and water leakage.

The automotive and transportation sectors are significant consumers of elastic adhesives. They are crucial for bonding body panels, sealing windows and doors, and assembling interior components, providing both structural strength and vibration dampening. The rise of electric vehicles, with their unique assembly requirements and focus on lightweighting, is further driving innovation and demand for specialized elastic adhesives.

Polyurethane (PU) and silicone-based elastic adhesives currently dominate the market due to their excellent flexibility, durability, and adhesion to a wide range of substrates. However, other chemistries like modified silane (MS) polymers are gaining traction due to their lower VOC (volatile organic compound) content and paintability, aligning with increasing environmental regulations and user preferences for more sustainable solutions.

Regionally, Asia Pacific is the largest and fastest-growing market for elastic adhesives. Rapid industrialization, booming construction activities, and the expanding automotive and transportation sectors in countries like China and India are key growth drivers. North America and Europe also represent significant markets, driven by stringent building codes and a mature automotive industry with a focus on high-performance materials.

In conclusion, the elastic adhesive market is poised for continued growth, driven by the increasing demand for flexible and durable bonding solutions across various industries. The focus on sustainable materials, coupled with technological advancements leading to enhanced performance characteristics, will further propel market expansion. Manufacturers who can innovate and cater to the specific needs of diverse applications and regional demands will be well-positioned to capitalize on the opportunities in this dynamic market.

Author's Bio:

Nilesh Shinde

Senior Market Research expert at The Insight Partners

#news #business

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vijay34 · 2 months ago

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Biopolymers Market Size, Share, and Industry Outlook

Biopolymers Market to Surpass USD 47.4 Billion by 2032, Driven by Sustainability Initiatives and Technological Advancements.

The Biopolymers Market Size was valued at USD 17.5 billion in 2023 and is expected to reach USD 47.4 billion by 2032 and grow at a CAGR of 11.7% over the forecast period 2024-2032.

The Biopolymers Market is experiencing robust growth as industries and governments worldwide increasingly prioritize sustainability and the reduction of plastic waste. Biopolymers—derived from renewable biomass sources such as corn starch, sugarcane, and cellulose—are biodegradable, environmentally friendly alternatives to conventional petroleum-based plastics. They are widely used in packaging, agriculture, consumer goods, textiles, and medical applications. Growing regulatory pressures, eco-conscious consumer behavior, and innovations in bio-based technologies are driving the market forward.

Key Players

BASF SE

Bio-on S.p.A.

Cardia Bioplastics

DuPont de Nemours, Inc.

Futerro

Green Dot Bioplastics

Mitsubishi Chemical Corporation

NatureWorks LLC

Novamont S.p.A.

Total Corbion PLA

AkzoNobel N.V.

Braskem S.A.

Cargill, Inc.

Danimer Scientific, Inc.

Galactic S.A.

Lenzing AG

Phaerista

Solvay S.A.

Synlogic, Inc.

Toray Industries, Inc.

Future Scope & Emerging Trends

The future of the biopolymers market is promising, with analysts predicting double-digit growth in the coming years. As governments impose stricter bans on single-use plastics and enforce biodegradable packaging mandates, demand for compostable and bio-based polymers is set to rise. Technological advancements are enhancing material properties, making biopolymers suitable for high-performance applications in automotive and electronics. Moreover, circular economy models and investments in waste-to-biopolymer technologies are unlocking new potential. Startups and R&D initiatives are also focusing on algae-based and bacterial fermentation processes, expanding feedstock diversity.

Key Points

Global biopolymers market projected to exceed USD 47.4 billion by 2032, growing at a CAGR of over 11.7%.

Major drivers include government regulations, eco-friendly packaging, and consumer preference for green products.

PLA, PHA, starch blends, and bio-PET are among the most popular biopolymer types.

Europe leads in adoption due to strong regulatory support, followed by North America and Asia-Pacific.

Innovation in high-performance biopolymers is expanding end-use applications.

Conclusion

As environmental challenges mount and legislative frameworks tighten, the biopolymers market stands at the forefront of the green materials revolution. With sustained investment in R&D, collaboration across supply chains, and growing awareness, biopolymers are poised to play a critical role in transitioning toward a more sustainable and circular economy. The market’s evolution signals a transformative era for plastics and materials science.

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Glyphosate Market Size, Share & Segmentation, By Crop Type (Conventional Crops and Genetically Modified Crops), By Form (Liquid and Dry), By Application (Agriculture and Non-Agriculture), By Region and Global Forecast for 2024-2032.

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Jagney Dave — Vice President of Client Engagement

Phone: +1–315 636 4242 (US) | +44- 20 3290 5010 (UK)

#Biopolymers Market #Biopolymers Market Size #Biopolymers Market Share #Biopolymers Market Report #Biopolymers Market Forecast

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cleantechwater · 2 months ago

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Why MBBR STPs Are Ideal for Urban Infrastructure

As cities grow and urban populations surge, the demand for effective and sustainable wastewater treatment solutions has never been higher. Urban areas, with their space limitations and high wastewater loads, require systems that are compact, energy-efficient, and capable of handling fluctuating sewage volumes. This is where MBBR (Moving Bed Biofilm Reactor) sewage treatment plants step in as a game-changing technology. Offering robust performance, operational ease, and environmental benefits, MBBR STPs are becoming the preferred choice for urban infrastructure across the globe.

Let’s explore how MBBR sewage treatment plants contribute to cleaner cities by delivering efficient, scalable, and cost-effective wastewater solutions.

10 Advantages of Using MBBR Sewage Treatment Plants

1. Space-Saving Design

Urban development often comes with the challenge of limited space, especially for utility installations. MBBR systems are designed to occupy minimal land area compared to traditional sewage treatment plants. The compact design is a result of their modular nature and efficient treatment processes, which allow them to be installed in confined spaces—making them a perfect fit for urban infrastructure projects, high-rise buildings, and commercial complexes.

2. High Treatment Efficiency

Despite their compact footprint, MBBR STPs offer superior treatment performance. They utilize specially designed bio-media that provide a large surface area for microbial growth. These microorganisms break down organic pollutants in the sewage efficiently, resulting in high-quality effluent that meets stringent discharge norms. The constant movement of bio-media within the reactor ensures optimal contact between sewage and microorganisms, enhancing biodegradation.

3. Easy to Retrofit into Existing Systems

One of the standout advantages of MBBR technology is its adaptability. These systems can be easily integrated into existing wastewater treatment setups, enhancing their performance without the need for complete overhauls. Whether you're upgrading an outdated plant or improving treatment standards in a rapidly urbanizing area, MBBR STPs provide a hassle-free retrofit solution.

Get a Quote for MBBR STP Installation

Thinking of upgrading your current system or installing a new one? Contact Cleantech Water to receive a tailored quote for your MBBR STP requirements. Our team of experts will help you design a solution that suits your budget and wastewater load.

4. Low Maintenance Requirements

Urban authorities and facility managers often look for low-maintenance solutions that minimize operational complexity. MBBR STPs are designed with simplicity in mind. With fewer moving parts, no need for backwashing, and reduced manual intervention, these systems offer minimal wear and tear—significantly lowering long-term maintenance costs and operational downtime.

5. Energy Efficiency

Energy consumption is a major concern for urban wastewater treatment. MBBR systems are highly energy-efficient, particularly because they eliminate the need for sludge recirculation—a common energy-intensive process in other treatment methods. This helps municipalities and industries cut down on electricity usage and contributes to a lower carbon footprint.

6. Scalability and Flexibility

Urban environments are constantly evolving. A treatment solution that can grow with the city is crucial. MBBR STPs are modular in nature and can be scaled up or down based on increasing sewage loads. Whether it’s an apartment complex expanding its capacity or a city adding new residential zones, these plants can be easily modified without disrupting the existing treatment process.

7. Resistant to Load Fluctuations

Urban sewage systems often deal with variable flow rates and inconsistent pollutant loads—especially in commercial and residential areas where water usage can spike unpredictably. MBBR systems are highly resilient to such fluctuations. Thanks to the attached growth of microorganisms on the bio-media, the biological process remains stable even during hydraulic or organic shocks, ensuring uninterrupted performance.

8. Minimal Sludge Production

Traditional sewage treatment plants often produce large volumes of sludge, which pose disposal and handling challenges in urban areas. MBBR technology, however, generates significantly less sludge due to its efficient biofilm-based treatment. This not only reduces the burden on sludge management systems but also lowers disposal costs and environmental impact.

9. Long Operational Life

Durability and reliability are critical for urban infrastructure investments. MBBR STPs are built using corrosion-resistant materials and sturdy components that withstand the test of time. With proper maintenance and periodic checks, these plants can operate efficiently for several decades—offering excellent return on investment for municipalities and private developers alike.

10. Compliance with Stringent Discharge Norms

Governments and environmental bodies have tightened wastewater discharge regulations to protect water bodies from pollution. MBBR STPs consistently meet or exceed these discharge standards. Their high-quality effluent ensures that treated water can be safely released into natural water bodies or reused for gardening, flushing, or cooling, aligning perfectly with the goals of sustainable urban living.

Ready to Invest in a Smarter, Greener Future with an MBBR Sewage Treatment Plant?

Urban infrastructure must evolve to address the dual challenges of environmental conservation and population growth. MBBR sewage treatment plants represent a forward-thinking solution that not only tackles wastewater efficiently but also promotes long-term sustainability.

If you're planning a wastewater treatment upgrade for your residential complex, commercial site, or municipal project, Cleantech Water is here to help. With years of expertise and a commitment to delivering top-tier solutions, we specialize in designing, installing, and maintaining MBBR-based systems that cater to diverse urban needs.

Key Benefits at a Glance:

Compact design suited for limited urban spaces

High BOD/COD removal efficiency

Lower capital and operational costs

Quick installation and commissioning

Environmentally friendly and sustainable

Make the smart move towards a cleaner and greener city. Choose MBBR sewage treatment technology for your next project and contribute to a more sustainable urban future.

👉 Learn more about MBBR STPs and request a quote here

#sewage treatment plant #water treatment plant #wastewater treatment plants

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chemicalmarketwatch-sp · 4 months ago

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Coating Additives Market on the Rise: Trends, Innovations, and Future Outlook

The global coating additives market is experiencing significant growth, driven by increasing demand for high-performance and eco-friendly coatings across various industries. Valued at $10 billion in 2022, the market is projected to reach $17.1 billion by 2032, growing at a CAGR of 5.7% from 2023 to 2032.

Market Segmentation

By Type:

Defoamers: Prevent foam formation, ensuring a smooth finish.

Wetting & Dispersing Agents: Ensure even distribution of pigments and fillers, crucial for color consistency and stability.

Rheology Modifiers: Adjust the flow properties of coatings, aiding in application and finish quality.

By Formulation:

Water-Borne: Gaining prominence due to environmental regulations and reduced VOC emissions.

Solvent-Borne: Valued for their durability and efficiency, especially in industrial applications.

By Application:

Architectural: Largest segment, driven by residential and commercial construction projects.

Industrial: Requires additives that enhance performance under harsh conditions.

Automotive & Transportation: Demands high-quality finishes with resistance to environmental factors.

Wood & Furniture: Focuses on aesthetics and protection of wood surfaces.

Market Segmentation

By Type:

Defoamers: Prevent foam formation, ensuring a smooth finish.

Wetting & Dispersing Agents: Ensure even distribution of pigments and fillers, crucial for color consistency and stability.

Rheology Modifiers: Adjust the flow properties of coatings, aiding in application and finish quality.

By Formulation:

Water-Borne: Gaining prominence due to environmental regulations and reduced VOC emissions.

Solvent-Borne: Valued for their durability and efficiency, especially in industrial applications.

By Application:

Architectural: Largest segment, driven by residential and commercial construction projects.

Industrial: Requires additives that enhance performance under harsh conditions.

Automotive & Transportation: Demands high-quality finishes with resistance to environmental factors.

Wood & Furniture: Focuses on aesthetics and protection of wood surfaces.

Recent Developments

Nouryon's Expancel BIO Microspheres: In December 2024, Nouryon introduced Expancel BIO microspheres, the first-generation partially biobased microspheres, offering sustainable solutions for the coatings industry.

Gerdau Graphene's NanoDUR and NanoLAV: In May 2023, Gerdau Graphene announced the commercial availability of NanoDUR and NanoLAV, two new additives developed specifically for the paint and coatings industry. These additives utilize graphene nanoplatelets to enhance the performance of water-based paints and coatings without altering their pH levels.

Evonik's Restructuring: In October 2024, Evonik announced plans to scale back its adhesives and health care units to focus on core assets, including liquid polybutadienes and specialty acrylics, impacting the coating additives market.

Explore the full report – Download the PDF now.

The coating additives market is set for sustained growth, driven by increasing demand for high-performance, eco-friendly coatings and advancements in technology. The Asia-Pacific region, particularly India and China, remains a key growth hub due to rapid urbanization and industrial expansion. As industries prioritize low-VOC, bio-based, and corrosion-resistant coatings, demand for advanced additives will rise, making R&D investments, sustainable innovations, and market expansion crucial for long-term success.

#CoatingAdditives #PaintsAndCoatings #ChemicalIndustry #MarketTrends #WaterBorneCoatings #SolventBorneCoatings #HighPerformanceCoatings #EcoFriendlyCoatings #ArchitecturalCoatings #IndustrialCoatings #AutomotiveCoatings #SpecialtyChemicals #CorrosionProtection #LowVOC #SustainableCoatings

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willyskristina · 6 months ago

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Matting Agents Market

Matting Agents Market Size, Share, Trends: Evonik Industries AG Leads

Growing Demand for Eco-Friendly and Sustainable Matting Agents

Market Overview:

The Matting Agents Market is projected to grow at a CAGR of 5.8% from 2024 to 2031. Asia-Pacific emerges as the dominant region, driven by rapid industrialization and growing demand from end-use industries. Key metrics include increasing demand for low-gloss finishes, stringent regulations on VOC emissions, and technological advancements in matting agent formulations.

The market is quickly developing because of increased demand for matte finishes in a wide range of applications, including automotive coatings, furniture, and packaging. The increasing emphasis on aesthetics and usability in consumer goods is expected to drive market expansion in the next years.

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Market Trends:

The matting agents sector is making significant progress towards the development and acceptance of ecologically benign and sustainable products. This shift is being fuelled by rising environmental awareness, tighter limits on volatile organic compound (VOC) emissions, and a growing customer preference for green products.

Manufacturers are working to develop bio-based matting agents made from sustainable resources such as cellulose and agricultural leftovers. These environmentally friendly alternatives offer comparable performance to traditional synthetic matting agents while reducing environmental impact. For example, a prominent matting agent business reported a 25% rise in bio-based matting agent sales in 2023 over the previous year.

Market Segmentation:

The silica-based matting agents sector holds the largest market share in the matting agents industry, accounting for approximately 60% of total market value. This dominance is primarily owing to silica-based matting agents' superior performance characteristics, which include high efficiency, excellent transparency, and compatibility with a wide range of coating systems.

Recent technological developments have hastened the silica segment's expansion. For example, the use of surface-treated silica particles has solved one of the key issues with traditional silica matting agents: settling and flotation in liquid coatings. These novel surface-modified silicas offer improved dispersion stability and a uniform matting effect. According to a report from a prominent silica manufacturer, sales of surface-treated silica matting agents increased by 22% in 2023 over the previous year.

Market Key Players:

Evonik Industries AG

PPG Industries, Inc.

Deuteron GmbH

Arkema S.A.

W. R. Grace & Co.-Conn.

BYK Additives & Instruments (Altana)

Name: Hari Krishna

Email us: [email protected]

Website: https://aurorawaveintellects.com/

#market growth #market insights #market trends

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businessindustry · 1 month ago

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Acrylate Monomers Market Share, Trends and Forecast Report by 2025-2033

Report Highlights:

How big is the Acrylate Monomers Market?

The global acrylate monomers market was valued at US$ 10,562.7 Million in 2024 and is expected to register a CAGR of 5.3% over the forecast period and reach US$ 16,812.4 Million in 2033.

What are Acrylate Monomers?

Request for a sample copy with detail analysis: https://www.reportsandinsights.com/sample-request/2642

What are the growth prospects and trends in the Acrylate Monomers industry?

What is included in market segmentation?

The report has segmented the market into the following categories:

By Product Type

Acrylic Acid-Based Monomers

Glacial Acrylic Acid

Technical Acrylic Acid

Acrylate Esters

Methyl Acrylate (MA)

Ethyl Acrylate (EA)

Butyl Acrylate (BA)

2-Ethylhexyl Acrylate (2-EHA)

Specialty Acrylate Monomers

Hydroxyethyl Acrylate (HEA)

Hydroxypropyl Acrylate (HPA)

Glycidyl Acrylate

Carboxylic-Modified Acrylate

Phosphoric-Modified Acrylates

Bio-Based Acrylates

By Production Process

Petrochemical-Based Process

Propylene Oxidation

Acetylene Carbonylation

Bio-Based Production

Fermentation Process

Biomass-Derived Acrylic Acid

By Function

Crosslinking Agents

Surface Modification Additives

Thickening Agents

Weather-Resistant Polymers

Low Volatile Organic Compound (VOC) Formulations

Others

By Application

Paints, Coatings & Inks

Architectural Paints

Industrial Coatings

Automotive Coatings

Marine Coatings

Printing Inks

Wood Coatings

Adhesives & Sealants

Pressure-Sensitive Adhesives (PSA)

Construction Adhesives

Packaging Adhesives

Automotive Sealants

Plastics & Polymers

Polyacrylates

Copolymers & Homopolymers

Superabsorbent Polymers (SAP)

Water Treatment Chemicals

Flocculants & Coagulants

Dispersants

Corrosion Inhibitors

Others

Detergents & Cleaning Products

Liquid Laundry Detergents

Dishwashing Liquids

Surface Cleaners

Construction & Infrastructure

Concrete Admixtures

Waterproofing Agents

Structural Sealants

Others

Electronics & Optical Applications

Textiles & Fibers

Healthcare & Personal Care Products

North America

United States

Canada

Europe

Germany

United Kingdom

France

Italy

Spain

Russia

Poland

Benelux

Nordic

Rest of Europe

Asia Pacific

China

Japan

India

South Korea

ASEAN

Australia & New Zealand

Rest of Asia Pacific

Latin America

Brazil

Mexico

Argentina

Middle East & Africa

Saudi Arabia

South Africa

United Arab Emirates

Israel

Rest of MEA

Who are the key players operating in the industry?

The report covers the major market players including:

BASF SE

Dow

Arkema

Evonik Industries AG

Mitsubishi Chemical Corporation

Synthomer plc

LG Chem Ltd.

Nippon Shokubai Co., Ltd.

Sumitomo Chemical Co., Ltd.

View Full Report: https://www.reportsandinsights.com/report/Acrylate Monomers-market

If you require any specific information that is not covered currently within the scope of the report, we will provide the same as a part of the customization.

About Us:

#Acrylate Monomers Market share #Acrylate Monomers Market size #Acrylate Monomers Market trends

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communicationblogs · 10 months ago

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Adsorbents Market- By Type, By Form, By End-Use Application — Global Opportunity Analysis & Industry Forecast, 2024–2030

Market Overview

Adsorbents market size is forecast to reach US$10.8 billion by 2030 after growing at a CAGR of 6.3% during 2024–2030. Adsorption is the accumulation of atoms or molecules on the surface of a material. This process creates a film of the adsorbate on the adsorbent’s surface. Adsorbents are used to remove pollutants from oil and gas streams in the oil and gas sector and are also increasingly being used in the gas drying process. The escalating demand for adsorbents stems from their efficacy in ensuring clean air and water.

A prominent trend in the adsorbents market is the increasing focus on sustainable and bio-based materials. As industries seek environmentally friendly alternatives, bio-based adsorbents derived from renewable sources gain traction. Additionally, the rising emphasis on green technologies and the push for sustainable practices in various sectors further propels the adoption of bio-based adsorbents which contributes to a positive outlook for the adsorbents industry during the forecast period.

Report Coverage :

The report: “Adsorbents Market — Forecast (2024–2030)”, by IndustryARC, covers an in-depth analysis of the following segments of the global adsorbents industry.

By Type: Activated Alumina, Activated Charcoal, Activated Clay, Silica Gel, Metal Oxides, Polymer Adsorbents, Zeolites (Molecular Sieves) (Type 3A, Others), and Others

By Form: Powder, Flakes, and Others

By End-Use Application: Oil and Gas Industry (Natural Gas Purification, Gasoline, Diesel and Jet Fuel Production, Others), Petrochemical Industry (Ethylene Production, Propylene Production, Xylene Separation, Others), Chemical Industry (Industrial Gases, CASE (Coatings, Sealants, Adhesives, and Elastomers), Others), Automotive and Transportation, Pharmaceutical and Food, Water Treatment, Nuclear Waste Remediation, Refrigerant (Commercial, Industrial), Building & Construction, Personal Care and Cosmetic, and Others

By Geography: North America (U.S.A., Canada, and Mexico), Europe (Germany, UK, France, Italy, Spain, Netherlands, Denmark, Belgium, and Rest of Europe), Asia-Pacific (China, Japan, India, South Korea, Australia, Indonesia, Taiwan, Malaysia, and Rest of APAC), South America (Brazil, Argentina, Colombia, Chile, and Rest of South America), Rest of the World (Middle East and Africa)

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Key Takeaways :

The Asia Pacific dominates the Adsorbents Market owing to the rising growth and increasing investments in the pharmaceutical and food industry.

The strict government regulations governing pharmaceutical product manufacture, hygiene, and quality control lead to a surge in the demand for adsorbents.

The rising demand for adsorbents in water and wastewater treatment application, has been a critical factor driving the growth of the Adsorbents Market in the upcoming years.

Adsorbents Market Segment Analysis — By Type

The zeolites segment held the largest share in the Adsorbents Market in 2023. Zeolites have a high degree of hydration, which results in a stable low-density crystal structure with a large void volume. Zeolites have been employed as an adsorbent in non-technically demanding, non-regenerative applications over the past two decades. New lightweight cementing methods for oil and gas completions to new modified zeolite adsorbents for extracting metals or organics from water are just a few of the new inventive applications. Systems for zeolite gas treatment, pressure swing adsorption, smell control, and other specific applications are being developed. Inorganic adsorbents, particularly for environmental applications, industrial gas production, and specialized chemicals, are the most valuable applications for zeolites and synthesized zeolites. Thus, the rising usage of zeolites in various applications, have uplifted the Adsorbents Market growth, in the forecast period.

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Adsorbents Market Segment Analysis — By End-Use Application

The petrochemical industry held the largest share in the market in 2023 and is expected to grow at a CAGR of 7.4% during 2024–2030. Adsorbents are utilized in the petrochemical industry to remove trace contaminants such as water and sulphur in the feed, intermediate, and product streams, for the smooth operation of the plant. The usage of the right adsorbent is necessary for the petrochemical plants due to the reactivity of ethylene plant streams. In the petrochemical industry, adsorbents are used for the effective removal of a wide range of contaminants from olefin-containing streams, complete system solutions for the treatment of off-gas streams from catalytic crackers (FCC, DCC, CPP) and acetylene producing units, and long lifetime and easy operability. The surging demand for adsorbents is due to the rising investments in its end use industry such as petrochemical industry. For instance, according to Alberta’s Industrial Heartland Association, the petrochemical sector in Alberta has the potential to increase by more than US$30 billion by 2030. Thus, the rising investments in the petrochemical industry of various countries will further drive the growth of the adsorbents market over the forecast period.

Adsorbents Market Segment Analysis — By Geography

Asia-Pacific region dominated the adsorbents market in terms of revenue with a share of 38% in 2023 and is projected to dominate the market during the forecast period 2024–2030. The growing demand for adsorbents, along with the high purchasing power in countries such as China, India, and Japan, tends to become a potential market for adsorbents during the forecast period. The surging adoption of adsorbents in the petrochemical, oil, and gas, and other sectors are driving the adsorbents market in China. Currently, several initiatives taken by organizations for the development of new petrochemical plants in the country have increased the demand for adsorbents. In November 2022, Saudi Aramco announced plans to invest in a US$7 billion project to produce petrochemicals from crude oil at its South Korean affiliate S-Oil Corp’s refining complex in the port city of Ulsan. In March 2023, Indian Oil announced plans to build a petrochemicals complex at Paradip with an investment of $7.3 billion. Such investments will drive the demand for adsorbents in this region during the forecast period. Adsorbents Market Driver :

Strict Government Regulations Governing Pharmaceutical Product Manufacture, Hygiene, And Quality Control Are Boosting Demand for Adsorbents

Pharmaceutical companies are putting a greater emphasis on quality control, which includes the use of adsorbents in procedures like instrument drying, drying of air-synthesis products, and deodorization. Several types of adsorbents are utilized in the pharmaceutical sector, with a selection depending on the application requirement. Activated carbon, for instance, is used to remove contaminated or by-products during the drug formulation process, whereas activated alumina is used to recover Pyrogen-free pharmaceuticals and as a desiccant for drying air and industrial gases. Also, silica gel is also employed in column chromatography as a pharmaceutical adsorbent, where it assists in the separation or collection of various medication components. Regulations mandating the use of adsorbents in the pharmaceuticals sector such as, by the United States Pharmacopeia (USP), Japanese Pharmacopeia (JP), and so on are also influencing the adsorbents market growth in the pharmaceutical sector. For instance, according to Invest India, the pharmaceutical industry in India is expected to reach $65 billion by 2024 and to $130 billion by 2030.

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Adsorbents Market Challenge

Reduced Shelf Life Due to High Level of Impurities Will Hamper the Market Growth

Although adsorbent materials can attract molecules to their surfaces, this ability is limited. Once the capacity has been reached, continued refining and purification will produce an equilibrium, which will lead to desorption. Adsorbents are utilized for adsorption of various pollutants and impurities such as carbon dioxide or hydrogen sulphide, mercaptans, manufacturing chemicals, and hydrate inhibitors in refining and purifying processes. The current contaminants react with the adsorbents at this point, causing the adsorbent to regenerate. These pollutants either renew or eliminate the adsorbent. The service life of adsorbents is determined by the material’s regeneration capacity, which could be a stumbling block for the overall adsorbents market.

Adsorbents Industry Outlook

Top 10 companies in the adsorbents market include:

BASF SE

Arkema SA

Honeywell International Inc.

Cabot Corporation

W. R. Grace & Co.

Clariant AG

Mitsubishi Chemical Corporation

Calgon Carbon Corporation (Kuraray)

Evonik Industries

Axens Group

For more Chemicals and Materials related reports, please click here

#marketing #advertising #digital marketing #reseach marketing

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rnomics · 11 months ago

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Chemosensors, Vol. 12, Pages 163: Facile Fabrication of Bio-Nanohybrid Electrode with Guanine/Cytosine-Modified Electrochemically Reduced Graphene Oxide Electrode and Its Application in Doxorubicin Analysis

Graphene, known for its outstanding physical and chemical properties, is widely used in various fields, including electronics and biomedicine. Reduced graphene oxide (rGO) is preferred for electrochemical applications due to its enhanced water solubility and dispersion. Electrochemically reduced graphene oxide (ErGO) is particularly advantageous as it can be prepared under mild conditions and simplifies sensor fabrication; however, ErGO-based electrochemical sensors often lack specificity. Bioreceptors like proteins, enzymes, and DNA/#RNA #aptamers are incorporated to provide high specificity. This study introduces a guanine (G)/cytosine (C)-modified ErGO electrode (G/C@ErGO-GCE) for the sensitive electrochemical detection of doxorubicin (DOX) with good selectivity. The G/C mixture acts as a bioreceptor and is anchored on the ErGO-GCE surface via π-π interactions. The G/C@ErGO-GCE was characterized using scanning electron microscopy, contact angle measurement, Raman spectroscopy, and electrochemical methods. The sensor demonstrated excellent dynamic range (DPV: 10 nM to 1 µM, CA: 30 nM to 1.3 µM), sensitivity (DPV: 2.17 µA/µM, CA: 6.79 µA/µM), limit of detection (DPV: 84 nM, CA: 34 nM), and selectivity for DOX detection, highlighting its potential for biomedical applications and pharmacokinetic studies. https://www.mdpi.com/2227-9040/12/8/163?utm_source=dlvr.it&utm_medium=tumblr

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poonamcmi · 11 months ago

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Understanding the Importance of Lubricants

They play a vital role in the smooth functioning of machinery. They are hydrocarbon oils or mixtures which when applied to moving surfaces, reduce friction and minimize wear and tear. Theys help reduce energy losses, thereby improving efficiency. By lowering operating temperatures, they also enhance equipment life and reliability.

Types

Mineral Oil Lubricants Mineral oils are the most commonly used derived from petroleum. They are cost-effective, have good thermal and oxidative stability and work in a wide range of conditions. Mineral oils are further classified based on viscosity into categories like engine oils, hydraulic oils, gear oils etc. They are suitable for general lubrication of automotive engines, industrial gearboxes and hydraulic systems. However, mineral oils have limited performance under extreme conditions.

Synthetic Lubricants Synthetic are manufactured by combining various types of base stocks through chemical processes. Lubricants They have enhanced properties compared to conventional mineral oils. Different types of synthetic include polyalphaolefins (PAO), polyalkylene glycol (PAG), diester, polyol esters etc. Synthetics have excellent viscosity-temperature properties, high flash points and thermal/oxidative stability. They are more durable and provide better protection, especially in high/low temperatures and heavy load conditions.

Bio-based Lubricants With growing environmental concerns, bio-based manufactured from renewable plant or animal sources are gaining popularity. They have low toxicity and are biodegradable. Common bio-lubricant base stocks include vegetable oils, animal fats and synthetics derived from biomass feedstock. While they have superior sustainability credentials, their performance may be limited compared to petroleum and synthetic products under some application parameters.

Grease Lubricants Greases are semi-solid consisting of thickening agents like soap, worked into a lubricating oil. They can withstand heavier loads and retain lubrication in locations without relubrication for longer periods. Common types of greases used are lithium, aluminum and calcium soap greases. Specialty high-performance greases containing additives are suitable for severe conditions. Greases find wide application in bearings, rolling element assemblies, universal joints, slides etc.

Additives Lubricating oil formulations contain various performance-enhancing additives apart from the base oil. Common additive types include detergents, dispersants, antioxidants, corrosion inhibitors, anti-wear agents, viscosity modifiers and pour point depressants. Carefully selected multi-functional additive packages provide balance between different lubrication properties as per equipment/operational needs. Additives enable base oils to withstand greater thermal/oxidative stresses, reduce sludge formation and give robust protection against wear.

Selection Proper selection depends on considering factors like component material, operating environment/conditions, lubrication method, fluid compatibility etc. Manufacturers' recommendations and industry standards/guidelines provide guidance for matching chemistry to a given application. However, laboratory/field testing may still be required under complex situations. Better choices can boost savings through improved machine reliability and reduced maintenance over the long run. Proper handling, storage and periodic condition monitoring are equally important for deriving optimal results from lubrication.

Automotive Lubricants Engine Oils: Engine oils are designed to lubricate the internal combustion engine adequately under starting, warm-up and full load operating conditions. Formulations vary for gasoline and diesel engines. Fully synthetic and synthetic-blend oils provide better protection against breakdown.

Transmission Fluids: Automatic and manual transmission systems require dedicated fluids for optimum shift quality and equipment life. Criteria like viscosity, frictional properties, low temperature fluidity and anti-wear attributes are carefully considered.

Motorcycle Oils: Two-wheelers need distinctive suitable for their smaller engines that run at higher rpm. Specific additive chemistries guard against problems like valve train wear.

Greases: Automotive chassis and suspensionjoints widely use lithium-complex, calcium and aluminium-complex greases fortified with additives.

Industrial Lubricants Turbine and Compressor Oils: Turbomachinery demand thermally stable with excellent film strength and anti-wear features to minimize equipment damage from metal-to-metal contact.

Quench Oils: Used in metal quenching applications to rapidly cool workpieces after heat treatment without distortion. Must withstand high temperatures without degradation.

Metalworking Fluids: Lubrication and cooling of machine operations like turning, milling, grinding is achieved through oil-based, water-based and semi-synthetic metalworking fluids.

Transformer Oils: High electrical resistance and thermal endurance are hallmarks of insulating oils used in transformers and circuit breakers. Help dissipate heat load efficiently.

Hydraulic Fluids: Unique hydraulic fluids provide appropriate viscosities under a wide range of pressures, flow rates and conditions from ambient to high temperatures.

They play a critical role across industries by reducing friction and protecting machinery. Understanding its types, properties and selecting the right grades tailored for specific applications guarantee optimized performance and reliability. Proper handling and conditioning further ensure maximum service life and cost savings from lubrication over the long run. Continuous R&D is enabling Get More Insights On, Lubricants

About Author: Ravina Pandya, Content Writer, has a strong foothold in the market research industry. She specializes in writing well-researched articles from different industries, including food and beverages, information and technology, healthcare, chemical and materials, etc. (https://www.linkedin.com/in/ravina-pandya-1a3984191)

#Lubricants #Long Lasting Lubricants #Glycerin Free Lubricants #Hypoallergenic Lubricants #Travel Friendly Lubricants

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i-nilesh-blog · 1 month ago

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The Flexible Fix: Analyzing the Elastic Adhesive Market

Despite the positive outlook, the elastic adhesive market faces certain challenges. Price volatility of raw materials, particularly crude oil derivatives used in the production of PU and other polymers, can impact manufacturing costs. Furthermore, the need for specific application techniques and surface preparation can sometimes be a barrier to wider adoption, requiring skilled applicators and proper training. In conclusion, the elastic adhesive market is poised for continued growth, driven by the increasing demand for flexible and durable bonding solutions across various industries. The focus on sustainable materials, coupled with technological advancements leading to enhanced performance characteristics, will further propel market expansion. Manufacturers who can innovate and cater to the specific needs of diverse applications and regional demands will be well-positioned to capitalize on the opportunities in this dynamic market.

Author's Bio:

Nilesh Shinde

Senior Market Research expert at The Insight Partners

#news #business

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esgagile · 1 year ago

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Innovative Products to Lower Carbon Emissions

We are Carbon footprint consultant in Agile Advisors, "Carbon reduction" will become a required duty in the construction industry's future. Various approaches to producing new materials include 3D printing, recycling, low-carbon substitutes, and performance increases. In addition to being more ecologically friendly and opening up new construction techniques, new materials will also impact the direction and starting point of design concepts, leading to new structures with novel spaces and perspectives. Low-carbon building materials are not just a strategy, but the mainstay of the building materials sector's efforts to curb carbon emissions at the source. These materials, most of which are bio-based, utilize renewable biomass or raw materials from bio-manufacturing. The exterior of the building features two different textures: a laminated surface created using laminated printing and a carefully planned woven pattern texture on the sidewall in front of the door that gives visitors a delicate impression.

Agile Advisors provide Carbon footprint consultant In UAE, they represent a novel class of materials produced through chemical, physical, and biological processes, such as dried luffa fibres, corn stalks, mycelium, microalgae, and more. By reusing agricultural waste, mitigating subsidence, absorbing CO2, and minimizing plastic waste, they are shifting the industry's reliance from fossil to biological or planted resources, thereby significantly reducing carbon emissions. The Alive Pavilion, an entry by The Living Studio to the 2021 Venice Biennale, is a testament to the possibilities of multi-species architecture and the effective utilization of microorganisms. The Pavilion is constructed from the dried fibres of luffa, a low-cost, fast-growing vegetable that thrives in tropical and subtropical regions. These fibres, with their unique surface, create a robust, organic material that can support a variety of microorganisms. The fibre concrete the team developed—which omits formwork and steel bars—was used for cabin printing.

Agile Advisors, a leading Carbon footprint consultant In Dubai, they can be easily modified to create panels or partitions for building projects, showcasing the innovative potential of novel materials in the construction industry. The Growing Pavilion, a transient installation for Dutch Design Week, consists of mycelium panels affixed to a wooden framework. Company New Heroes commissioned set designer and artist Pascal Leboucq to create the temporary Pavilion, which he did in conjunction with Eric Klarenbeek. Grown Bio was the company that grew the mycelium panels in the Netherlands. Bio-based materials are given a new aesthetic significance by the Pavilion, which displays its distinctive organic textures and hues to the general public. Investigating material recycling and reuse is necessary to find a solution to waste material to achieve sustainable development. In addition to virgin resources that may be obtained locally, more and more novel materials are opening up.

As a Carbon footprint consultant, Hard-to-degrade plastics, construction trash from urban renewal cycles, ceramic waste from ceramic production, etc. Both ceramic and clay tiles are mostly made of clay. Over 10 million tons of ceramics are thrown away annually in China; these solid wastes not only utilize a lot of energy and land resources, such as coal, but they also have high carbon emissions that are above regulations and seriously affect the environment. Ceramic waste disposal has grown to be an issue. A unique example of a recycled construction material made from ceramic waste, the Recycled Tree at Design China Beijing showcases design concepts for addressing China's severe waste material management issue. It was developed in partnership with Italian architect Aldo Cibic.

Being a Carbon footprint consultant In UAE, the recycled ceramic tiles were gathered, examined, ground into a powder, combined, and subjected to laboratory testing. Materials like wood were eventually supplanted by steel and cement due to their inferior performance; however, the traditional materials are still being revived by modern techniques to enhance their performance. 3D printing technology has broadened design options and altered how architecture is conceptualized. Investigating materials for 3D printing has produced architectural environments with a range of sensations and structures. Furthermore, labour and material costs associated with 3D printing help lower carbon emissions. Two sets of robotic arm printing systems are used to print the cabin: one prints the main structure and building foundation in place, while the other prints the arc wall and dome top in situ.

#Carbonfootprintconsultant #Carbonfootprintconsultantindubai #Carbonfootprintconsultantinuae

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