Adipic Acid Prices | Pricing | Trend | News | Database | Chart | Forecast

 Adipic Acid is an essential industrial chemical primarily used in the production of nylon 6,6, as well as in various resins, fibers, coatings, and plasticizers. It is also utilized in the food and pharmaceutical industries as a gelling agent and acidity regulator. The pricing of adipic acid has been a point of interest for various industries and businesses due to its substantial demand across multiple sectors. Over the years, adipic acid prices have been influenced by several factors, including raw material costs, global market dynamics, production levels, environmental regulations, and regional supply-demand imbalances.

A key driver in the pricing of adipic acid is the cost of raw materials. Adipic acid is produced mainly from cyclohexane, a chemical derived from crude oil. The volatility of crude oil prices often directly impacts the price of adipic acid. For instance, when crude oil prices soar, the cost of producing cyclohexane increases, driving up adipic acid prices. Conversely, when oil prices drop, adipic acid tends to become more affordable, barring any other external factors. This close correlation with oil prices makes the adipic acid market sensitive to fluctuations in the global energy market, including geopolitical tensions, supply chain disruptions, and economic shifts that affect oil prices.

Get Real Time Prices for Adipic Acid: https://www.chemanalyst.com/Pricing-data/adipic-acid-1106

In addition to raw material costs, the production capacity and operational efficiencies of manufacturers significantly influence adipic acid prices. Major producers are concentrated in regions such as North America, Europe, and Asia-Pacific, with China being one of the largest players in the market. The availability of production facilities, technological advancements in manufacturing processes, and innovations aimed at improving yield and efficiency all play crucial roles in shaping supply levels and, consequently, the pricing of adipic acid. Periods of reduced production capacity, whether due to planned maintenance shutdowns or unplanned operational challenges, can lead to reduced supply, which often results in price spikes. On the other hand, when production is robust and supply levels meet or exceed market demand, prices tend to stabilize or even decrease.

Environmental regulations are another critical factor that impacts adipic acid prices. The production of adipic acid involves the release of nitrous oxide, a potent greenhouse gas. As governments worldwide implement stricter environmental regulations and carbon emission policies, adipic acid producers are being forced to invest in cleaner technologies and adopt more sustainable production methods. These investments in green technology often lead to increased production costs, which are passed on to consumers in the form of higher adipic acid prices. In particular, regions with more stringent environmental policies, such as Europe, may experience higher adipic acid prices compared to regions with more lenient regulations. This regulatory pressure is expected to increase in the future as sustainability becomes a growing concern for industries across the globe.

Demand trends across various end-user industries also have a significant effect on adipic acid prices. The nylon 6,6 industry is the largest consumer of adipic acid, and any shifts in demand for nylon products can cause price fluctuations. For instance, the automotive and textile industries, which are major consumers of nylon, directly impact adipic acid demand. A downturn in these industries can lead to reduced demand for adipic acid, resulting in lower prices. Conversely, a booming automotive or textile market can drive up demand and subsequently increase prices. Other industries, such as food and pharmaceuticals, while smaller in terms of volume, also contribute to demand fluctuations, particularly in niche markets where adipic acid plays a specialized role.

The global supply chain dynamics also contribute to adipic acid price movements. Trade restrictions, tariffs, and transportation costs can all affect the global flow of adipic acid, creating regional price disparities. For example, shipping constraints or trade tariffs between major producing regions, such as China and the United States, can lead to higher adipic acid prices in regions dependent on imports. Similarly, logistical challenges such as port congestion or limited transportation capacity can result in delayed deliveries and temporary supply shortages, causing prices to surge in affected areas.

Seasonal variations also play a part in adipic acid pricing, though to a lesser extent. In some industries, demand for nylon or other adipic acid derivatives may be higher at specific times of the year, leading to short-term price fluctuations. For example, increased automotive production during certain seasons can lead to higher demand for nylon, which in turn drives up adipic acid prices. Likewise, maintenance cycles for production plants are often scheduled during periods of lower demand, but unexpected shutdowns during peak seasons can create supply shortages and lead to sudden price hikes.

Finally, the role of global economic conditions cannot be overlooked when analyzing adipic acid prices. Economic downturns, recessions, and fluctuations in currency exchange rates can all affect market dynamics. During periods of economic uncertainty, industries may scale back production, leading to reduced demand for adipic acid and subsequent price drops. However, during periods of economic recovery or growth, increased industrial activity can drive up demand and result in higher prices. Exchange rate fluctuations, particularly in major producing and consuming regions, can also affect adipic acid pricing, as a stronger currency may make imports more expensive, contributing to regional price increases.

In conclusion, adipic acid prices are influenced by a complex interplay of factors ranging from raw material costs and production capacity to environmental regulations, demand trends, and global supply chain dynamics. The price of adipic acid is highly susceptible to external factors such as crude oil price fluctuations, regulatory changes, and shifts in global demand. As industries continue to evolve and adopt more sustainable practices, adipic acid prices are likely to face further fluctuations, making it essential for businesses to stay informed about market trends and developments in order to navigate the challenges of this volatile market.

Get Real Time Prices for Adipic Acid: https://www.chemanalyst.com/Pricing-data/adipic-acid-1106

Contact Us:

ChemAnalyst

GmbH - S-01, 2.floor, Subbelrather Straße,

15a Cologne, 50823, Germany

Call: +49-221-6505-8833

Email: [email protected]

Website: https://www.chemanalyst.com

yall she's still around. the time between "oh hey, i can do this in a lab" and "i can do this in an industrial capacity and at a cost that's reasonable and with the variety of structural properties people want out of common plastics" is a long one, and not all things you can do in a lab are particularly easy to scale up.

In particular nopales are... not particularly known for being a "produces tons of biomass very rapidly and harvest in bulk with machinery" kind of plant. And the plastic here, according to the news articles, composts within 2-3 days when submerged in water. which is awesome, but it also means it's not ideal for holding your moist pb&j or being the wrap over a chicken breast or w/e.

Here's an excerpt from a 2023 opinion/survey piece from Dr. Sandra Pascoe Ortiz (the lady in this bbc video) and i wanna draw your attention to the fact that she is NOT saying "i have solved plastic with my nopales, and I need protection from big oil hitmen" she's saying "collectively we've made a lot of progress on this, but it's a complicated problem and there's a lot of issues we still need to solve with the science, industrial engineering, economics, politics, and social awareness"

... [some] Bioplastics may come from biological material but are chemically the same as petroleum-derived plastic, the only thing that changes is the source from which they are obtained; for example, with Bio-polyethylene terephthalate (Bio-PET), the "Bio" only indicates that its origin is vegetable. This compound is neither biodegradable nor compostable, it is considered a bioplastic only because of its origin. The environmental benefit of this type of material is that, because it comes from a plant, a certain amount of carbon dioxide is captured during the production of its raw material (during the life of those plants). In general terms, the production process of bioplastics compared to petroleum-derived plastics has less of an environmental impact in terms of the balance of greenhouse gas emissions.

It is also important to note that the fact that a bioplastic is biodegradable or compostable does not mean that it can be thrown anywhere and will just disappear. Most biodegradable or compostable bioplastic waste requires processing under controlled conditions to be incorporated back into nature: they must be composted at industrial level. For example, polylactic acid (PLA) takes 80 years in the open air to biodegrade or, if composted industrially, takes days or a few months depending on the conditions of the process.

The market for both biodegradable and non-biodegradable bioplastics is growing and these materials have been gaining ground over petroleum-based plastics (although not enough). The main biodegradable bioplastics on the market are polybutylene adipate terephthalate (PBAT), PLA, starch blends, polybutylene succinate (PBS), cellulose films and polyhydroxyalcanoates (PHAs). According to data from European Bioplastic in cooperation with the Nova-Institute from 2021, the most common applications of these materials are in flexible and rigid packaging, consumer goods, textile fibers and in agriculture, and it is projected that by 2026 the production of biodegradable bioplastics will be considerably higher than that of non-biodegradable bioplastics.

Bioplastics have several drawbacks. Some the raw materials they use are often also used for food, there is not enough production and their costs are higher than those of conventional plastics. It is often the consumer who has to absorb the price difference and is not in a position to do so, adding another reason why, so far, they have not been able to significantly displace petroleum-based plastics. Bioplastics and biodegradable plastics are part of the solution to the problem of plastic pollution, as they generally have reduced environmental impacts in their production processes and, in some cases, because it is feasible to treat their waste, but they are not the only and absolute solution; the problem of plastic pollution is more complex and is still far from being completely solved. For these materials to reach their full potential, it will be essential to have regulations to regulate their production, certifications in terms of biodegradability and proper education for buyers to choose products that help in the conservation of the environment.

Finally, it should be remembered that pollution is mainly generated by the misuse of materials and poor disposal of their waste. The real problem is the abuse of plastic materials, whether they are biodegradable or not, since they are mainly used in containers, packaging and single-use products, and most of the time they are discarded not because they are useless or their useful life has ended, but because of the convenience of using and throwing away. Certain quantities of plastics can be recycled; however, when they are mixed with other types of waste they become contaminated and when different types of plastic are not adequately separated, this recycling becomes practically impossible. Nevertheless, the recycling of some bioplastics has not yet been trialed, not because it cannot be done, but because of the small quantities of these materials compared to conventional plastics, which makes it practically unaffordable. So, instead of blaming plastic materials for existing environmental pollution, we need to look closely at how we use resources and dispose of waste. No matter how many bioplastics or "environmentally friendly" materials there are, if we do not reduce the production of these types of materials and consequently their waste, there will be no real solutions. We need to be aware of what we consume, support initiatives that promote environmental care and demand the commitment of governments to legislate and enforce laws, as well as encouraging businesses to change their materials and production proceses.

Like, not to put too fine a point on it, but if your response every time you see a news article about some tech and it doesn't immediately fundamentally transform society is "must have been suppressed by the elites and their killsquads", you WILL end up drinking the conspiracy kool-aid. And I also think it's disrespectful to scientists like Pascoe Ortiz to imagine that the science is fundamentally easy, instead of something that takes years of dedication and hard work and many false-starts and dead ends! If you're impressed by her work then,.. put some respect on her and her colleagues work!

/rant

Review : Isdin Eryfotona Actinica Ultralight Emulsion SPF 50+

What is it?

A broad-spectrum 100% mineral sunscreen with DNA Repairsomes.

Who is it for?

All skin types including sensitive.

What’s in it?

It contains DNA Repairsomes, encapsulated photolyase enzymes in a liposomal delivery system that help to boost the skin’s natural recovery process and protect skin from further damage. Another key ingredient is Vitamin E, which helps to protect against environmental damage and free radicals.

Active ingredients :

Zinc Oxide: 11% Sunscreen.

Inactive ingredients :

Water, Diethylhexyl Carbonate, Dibutyl Adipate, Cyclopentasiloxane, Dicaprylyl Carbonate, Alcohol Denat., Cyclohexasiloxane, Butylene Glycol, PEG-30 Dipolyhydroxystearate, Nylon-12, PEG-10 Dimethicone, Dimethicone, Sodium Chloride, Phenoxyethanol, Disteardimonium Hectorite, Triethoxycaprylylsilane, Tocopheryl Acetate, Glyceryl Stearate, Fragrance, Bisabolol, Disodium EDTA, Ethylhexylglycerin, Panthenol, PEG-8, Tocopherol, Lecithin, Plankton Extract, Ascorbyl Palmitate, Ascorbic Acid, Citric Acid.

How to use?

Apply liberally 15 minutes before sun exposure. During sun exposure, reapply after 40 minutes of swimming or sweating, immediately after towel drying and at least every 2 hours.

What to expect?

The sunscreen absorbs into skin almost instantly leaving a matte finish. Improvement in quality of skin health.

Pros

Contains a high % of zinc oxide

Generously sized in a 100ml bottle

Water-resistant

Free of chemical sunscreens

Prevents actinic damage

Extremely light-weight

Great price point

Loved by dermatologists

Cons

None

Conclusion

Eryfotona Actinica Ultralight Emulsion SPF 50+ helps to protect against UVA- and UVB induced sunburn, prevent sun damage and early signs of aging, support repair of already damaged skin, and decrease the risk of skin cancer if combined with other sun safety measures, such as limiting exposure during peak hours and wearing protective clothing. Eryfotona Actinica works to not only protect skin, but prevent actinic damage. It is important to target actinic keratoses (AKs) before they potentially transform to invasive squamous cell carcinoma.

A ton of dermatologists had been recommending this one and I was extremely impressed with the overall formulation and clean ingredient list. It prevents and reduces occurrence of pre-cancerous lesions via the DNA repairsome technology which won a Nobel Prize in Chemistry in 2015. I knew I had to review this one when Dr Noelle Sherber decided to stock this in her boutique.

We also spoke to Dr Dan Yarosh, one of the pioneers of DNA repair enzymes and this sunscreen was one of the products that had his seal of approval. 

It contains phytolase enzymes from algae that enhance the skin’s DNA repair when exposed to UV light: it has been shown in clinical studies to help guard against precancerous sun damage.

I’ve been trying to find 100% mineral sunscreens but most of them end up being too chalky or too heavy. This one is extremely lightweight and layers beautifully under make-up. While it goes on white initially, when it’s worked into skin it eventually becomes colorless.

If you’re looking for a powerful sunscreen you can wear on your beach vacation or just want a multi-tasking everyday sunscreen, this option comes highly recommended. In fact, it worked so well on my last vacation I decided to feature it in my Bali edit.

https://www.isdin.com/us/p/actinica-34-fl-oz/2794

アジピン酸(Adipic Acid)市場概要：現在の価格、トレンド分析、将来の予測

アジピン酸(Adipic Acid)は、主にナイロン6,6、ポリウレタン、およびさまざまな可塑剤の製造に使用される重要な化学物質です。その価格は、この重要な化学物質に依存する業界、特に自動車、繊維、包装などの分野の全体的なコスト構造に影響を与える多くの要因の影響を受けます。

アジピン酸の価格に最も影響を与えるものの1つは、原材料、特にベンゼンとシクロヘキサンのコストです。これらの石油化学誘導体はアジピン酸の製造に不可欠であるため、原油価格の変動はそれらのコストに直接影響し、結果としてアジピン酸の価格に影響します。原油価格が上昇すると、通常、アジピン酸の製造コストもそれに応じて上昇し、市場価格が上昇します。

ナイロン6,6の世界的な需要は、アジピン酸の価格を押し上げるもう1つの重要な要因です。アジピン酸はこのポリマーの生産に不可欠な成分であるため、自動車や消費財などの業界からの需要が増加すると、アジピン酸の価格が急騰する可能性があります。逆に、ナイロン 6,6 の需要が減少したり、代替材料に移行したりすると、アジピン酸の価格に下押し圧力がかか��可能性があります。

サプライ チェーンの要因も、アジピン酸の価格を決定する上で重要な役割を果たします。生産能力、工場のメンテナンス スケジュール、予期しない中断は、アジピン酸の供給に影響を与える可能性があります。たとえば、メンテナンスや技術的な問題による工場の停止により、利用可能な供給が減少し、価格が上昇する可能性があります。さらに、関税や物流上の課題を含む世界的な貿易動向は、特に輸入に依存している地域で、アジピン酸の入手可能性とコストに影響を与える可能性があります。

リアルタイムでアジピン酸(Adipic Acid)価格: https://www.analystjapan.com/Pricing-data/adipic-acid-33

環境規制は、アジピン酸市場をますます形作っています。アジピン酸の生産は、大量の温室効果ガスの排出を伴うため、主要な生産地域での環境規制の強化は、生産コストの増加につながる可能性があります。これは、価格の上昇に反映される可能性があります。さらに、持続可能性と環境に優しい生産方法への継続的な移行により、生産プロセスが変化し、アジピン酸のコスト構造と価格設定に影響を与える可能性があります。

アジピン酸市場内の競争も価格に大きな影響を与えます。大手生産者の存在と市場競争のレベルは、価格戦略に影響を与える可能性があります。たとえば、生産能力の増加や市場への新規参入により、より競争の激しい環境が生まれ、価格が下がる可能性があります。一方、業界内の統合や供給制限により、価格が上昇する可能性があります。

要約すると、アジピン酸の価格は、原材料費、ナイロン 6,6 の世界的な需要、サプライ チェーンのダイナミクス、環境規制、市場競争など、さまざまな要因の複雑な相互作用によって影響を受けます。アジピン酸に依存する業界にとって、これらの要因を理解することは、コストを管理し、市場で競争力を維持するために不可欠です。

ANALYST JAPAN

Call +1 (332) 258- 6602 1-2-3 Manpukuji, Asao-ku, Kawasaki 215-0004 Japan

Website: https://www.analystjapan.com

Email: [email protected]

PA66 prices move up

The prices of Polyamide 6-6 (PA6-6), grade imported, have moved up in the Ahmedabad market today as per the recent reports from Indian Petrochem. The sources also added that the prices have moved up to Rs 216/kg on July 22, 2024 from Rs 214 on July 20, 2024, an increase of Rs 2/kg. Polyamide 6-6 (PA6-6) or Nylon 6-6 is one of the most popular engineering thermoplastics. It is majorly used as a replacement for metal in various applications. Nylon 66 is synthesized by polycondensation of hexamethylenediamine and adipic acid. These two monomers contain 6 carbon atoms each. Indian PA66 Prices, PA66 Prices In India, Indian Prices PA66, Indianpetrochem.

The Cyclohexane Market size is expected to be worth around USD 43.4 billion by 2033, from USD 26.15 Bn in 2023, growing at a CAGR of 5.2% during the forecast period from 2023 to 2033.

The cyclohexane market encompasses the global trade and consumption of cyclohexane, a colorless, flammable liquid with a distinctive detergent-like odor. It is primarily used as a solvent in chemical manufacturing and in the production of nylon, where it acts as a precursor to adipic acid and caprolactam. The market is influenced by the demand for these end-products, fluctuations in raw material prices, and industrial advancements. Key factors driving growth include the expansion of the textile and automotive industries, where nylon's applications are prominent, as well as the ongoing development of industrial solvents and chemical intermediates.

Маrkеt Kеу Рlауеrѕ:

BASF SE

Cepsa

Chevron Phillips Chemical Company LLC

CITGO Petroleum Corporation

Reliance Industries Limited

Exxon Mobil Corporation

Idemitsu Kosan Co.,Ltd.

PTT Global Chemical Public Company Limited

Merck KGaA

Others

Click here for request a sample - https://market.us/report/cyclohexane-market/request-sample/ 

Application Analysis :                     In 2023, caprolactam was the leading application in the cyclohexane market, capturing over 43.2% of the share due to its essential role in producing nylon for products like clothing and carpets. Cyclohexane is used to produce both caprolactam and adipic acid, which are crucial for making nylon 6 and nylon 66. Although caprolactam prices initially fell by over 30% due to excess production capacity in Asia, prices began rising between 2023 and 2032, but not enough to ensure profitability. To balance supply and demand, a significant reduction in production may be necessary. End Use Analysis :                 In 2023, textiles dominated the cyclohexane market with over 37.5% of the share, reflecting its critical role in producing nylon fibers for various applications. The automotive sector also heavily relies on cyclohexane for manufacturing durable nylon components used in vehicles. Most nylon manufacturers are involved in producing both nylon resins and caprolactam, positioning themselves throughout the value chain as global demand for nylon evolves with increasing consumer awareness. Маrkеt Ѕеgmеntѕ:

By Application

Adipic acid

Caprolactam

Other Applications

By End-Use

Automotive

Paints and Coatings

Textiles

Construction

Others

Drivers: The cyclohexane market is propelled by rising demand for nylon products across industries such as textiles, automotive components, and consumer goods. The increasing use of nylon's durable and versatile qualities drives up the need for cyclohexane, essential for its production. Additionally, the automotive sector's shift towards lightweight materials boosts demand for nylon-based components, further stimulating cyclohexane market growth.

Restraints:The cyclohexane market faces significant challenges from environmental concerns and stringent regulations aimed at pollution reduction. Volatility in raw material prices and the availability of substitutes like phenol for caprolactam production also hinder market growth. These factors create obstacles in maintaining a steady growth rate and necessitate strategic adjustments by market players.

Opportunities:Opportunities in the cyclohexane market are expanding due to increasing demands from the oil and gas industry, where cyclohexane is crucial for refining processes and solvent production. The rise in automobile production, particularly with the integration of nylon-based materials, further opens prospects for cyclohexane suppliers as the demand for nylon in automotive applications grows.

Challenges:The cyclohexane market encounters challenges including environmental regulations and safety standards that limit growth. Price volatility of raw materials disrupts market stability, and competition from substitutes like phenol threatens market demand. Addressing these challenges requires adherence to regulations, managing raw material costs, and innovating to differentiate cyclohexane from alternatives.

The global demand for Adipic Acid market was valued at USD 7984.2 Million in 2023 and is expected to reach USD 12927.1 Million in 2032, growing at a CAGR of 5.50% between 2024 and 2032.Adipic acid, a white crystalline powder, is primarily used as a monomer in the production of nylon 6,6, a key component in the textile and automotive industries. With its wide-ranging applications in various sectors, the adipic acid market has experienced significant growth over the past few decades. This article delves into the current state of the adipic acid market, its growth drivers, challenges, and future prospects.

Browse the full report at https://www.credenceresearch.com/report/adipic-acid-market

Market Overview

The global adipic acid market was valued at approximately USD 5 billion in 2023 and is projected to grow at a compound annual growth rate (CAGR) of 4.5% from 2024 to 2030. This growth can be attributed to the increasing demand for nylon 6,6, the expansion of the automotive and textile industries, and the rising emphasis on sustainability.

Key Drivers

1. Automotive Industry Growth: Nylon 6,6, derived from adipic acid, is extensively used in the automotive industry for manufacturing various components such as air intake manifolds, engine covers, and radiator end tanks. The lightweight and durable nature of nylon 6,6 makes it a preferred material, driving the demand for adipic acid. The global shift towards electric vehicles (EVs) further fuels this demand, as EVs require lightweight materials to enhance energy efficiency.

2. Textile Industry Expansion: Nylon 6,6 is also a crucial material in the textile industry, used in the production of carpets, apparels, and industrial yarns. The increasing consumer demand for high-performance textiles and the growth of the fashion industry are significant factors propelling the adipic acid market.

3. Sustainability and Green Chemistry: There is a growing emphasis on sustainability and reducing carbon footprints across industries. The adipic acid market is witnessing innovations in bio-based production methods, which utilize renewable raw materials instead of traditional petrochemical sources. These environmentally friendly processes are gaining traction, aligning with global sustainability goals and attracting investments.

Challenges

Despite its promising growth, the adipic acid market faces several challenges:

1. Volatile Raw Material Prices: Adipic acid production relies heavily on petrochemical derivatives such as cyclohexane. Fluctuations in crude oil prices directly impact the cost of raw materials, affecting the overall production cost and market stability.

2. Environmental Concerns: Traditional adipic acid production methods involve the use of nitric acid, leading to the emission of nitrous oxide, a potent greenhouse gas. Stricter environmental regulations and the need to reduce greenhouse gas emissions pose significant challenges to conventional production processes. Companies are investing in research and development to discover more sustainable and eco-friendly production methods.

3. Competition from Alternatives: The development of alternative materials, such as bio-based polyamides and other synthetic fibers, poses a threat to the adipic acid market. These alternatives offer similar properties and, in some cases, better performance, leading to a potential shift in market dynamics.

Regional Insights

The Asia-Pacific region dominates the adipic acid market, accounting for the largest share in 2023. The region's rapid industrialization, expanding automotive and textile sectors, and growing population contribute to this dominance. China, in particular, is a major consumer and producer of adipic acid, driven by its robust manufacturing capabilities and increasing demand for high-performance materials.

North America and Europe also hold significant market shares, with well-established automotive and textile industries. The focus on sustainable production methods and stringent environmental regulations in these regions further drive innovation and market growth.

Future Prospects

The future of the adipic acid market looks promising, with several trends shaping its trajectory:

1. Bio-based Production Methods: Continued advancements in bio-based adipic acid production methods are expected to reduce the environmental impact and enhance sustainability. These methods leverage renewable resources and offer a greener alternative to traditional processes.

2. Technological Innovations: Ongoing research and development efforts are focused on improving production efficiency, reducing costs, and discovering novel applications for adipic acid. Innovations in catalyst technologies and process optimization are likely to drive future growth.

3. Rising Demand for High-Performance Materials: The increasing demand for lightweight, durable, and high-performance materials in various industries, including automotive, textiles, and electronics, will continue to propel the adipic acid market. The shift towards electric vehicles and sustainable practices will further augment this demand.

Key Players

Ascend Performance Materials

Asahi Kasei Corporation

BASF SE

INVISTA

LANXESS

Liaoyang Tianhua Chemical Co., Ltd

Radici Partecipazioni S.p.A.

Solvay

Sumitomo Chemical Co., Ltd.

DOMO Chemicals

Segmentation by Application

In 2023, the nylon production, six fiber application segment dominated the market, accounting for 53.1% of the total revenue. Its significant market share is driven by the expanding use of nylon 6, 6 as a metal alternative in automotive, electrical, and electronic devices, among other things. Nylon 6,6 fiber is also commonly used in technical components such as gears, nuts, bolts, bearings, powder tool casings, rivets and wheels, and rocker box covers. The properties of nylon 6,6 fiber, such as moisture and mildew resistance, high melting temperature, outstanding durability, and improved strength, are predicted to push its employment in a variety of applications in the coming years.

Polyurethane Production also has a consistent growth potential due to its use in a variety of end-use industries.

Segmentation by End-Use Industry

The automotive segment dominated the market over the projection period. The automotive industry mostly uses nylon 66, which is manufactured from adipic acid, due to its superior mechanical, temperature-resistant, and lightweight properties. Adipic acid is commonly used as a monomer in the production of polyamide 6.6 pellets and other polyamides or polymers for engineering plastics, as well as polyurethane for flexible and semi-rigid foam.

However, the food and beverage industry sector has gained significant market share.

Segmentation by Form

The powder form of Adipic Acid is in high demand in the market. Adipic acid powder is widely utilized in a variety of industries, including textiles, automobiles, and food. It is preferred for its portability, storage, and transportation. The powder form enables exact dosing, making it suited for a variety of applications. In addition, the powder form is more stable and has a longer shelf life than the liquid version.

Segmentation by Purity

Food Grade is the fastest-growing section of the Adipic Acid Market. Adipic Acid is becoming increasingly popular in the food business due to its numerous possibilities as a food ingredient. In food and beverage items, adipic acid is used to regulate acidity and increase flavor.

Segmentation by Production Process

Cyclohexane held the largest market share in 2023. Almost all commercial adipic acid is made from cyclohexane. It is commonly utilized as an intermediate chemical in a variety of processes, with around 54% of its output used to produce adipic acid for nylon-66.

However, cyclohexanone is expected to increase at the fastest CAGR of 8.5% throughout the projection period.

Segmentation by Region

North America dominated the global industry in 2023, accounting for more than 32.9% of total revenue

Asia Pacific is predicted to be the fastest-growing regional market

The rest of the world, including Latin America, the Middle East, and Africa, supplies the remaining demand for Adipic Acid.

Browse the full report at https://www.credenceresearch.com/report/adipic-acid-market

About Us:

Credence Research is committed to employee well-being and productivity. Following the COVID-19 pandemic, we have implemented a permanent work-from-home policy for all employees.

Contact:

Credence Research

Please contact us at +91 6232 49 3207

Email: [email protected]

Website: www.credenceresearch.com

Renewable Chemicals Market: Pioneering Sustainable Chemistry

Renewable chemicals are playing a growing role in the transition to a more sustainable future. Derived from biomass sources like agriculture and forestry residuals, reusable chemicals offer environmental benefits compared to petroleum-based alternatives. As production scales up, they promise to reduce dependency on fossil fuels and lower carbon emissions. Defining Renewable Chemicals Reusable chemicals are those produced from biomass rather than fossil fuel feedstocks like petroleum and natural gas. Biomass includes plant-based materials like agricultural crops and residues, as well as wood and forest products. Through various conversion processes, these feedstocks can be transformed into chemical building blocks and products similar to existing petrochemicals. Some key attributes of renewable chemicals include: Derived from recently photosynthesized biomass as opposed to fossil fuels locked away millions of years ago. Can be designed to be functionally equivalent to petrochemicals for use in the same applications. Manufactured through biological or thermochemical processes rather than fossil fuel cracking and reforming. Have the potential for reduced lifecycle greenhouse gas emissions depending on biomass source and production method utilized. Drivers of Growth in Renewable Chemical Production Several factors are propelling the increased commercialization and scaling of reusable chemicals: Environmental Sustainability

Growing societal focus on reducing carbon footprint and transitioning to low-carbon economy is driving demand for sustainable alternatives. Renewable chemicals offer reduced dependence on fossil fuels and potential for lower lifecycle emissions. Resource Availability

Concerns over peaking of petroleum production and volatility in crude oil prices is making companies seek renewable feedstock options. There is an abundance of biomass globally that can be refined into chemical building blocks. Market Pull

Major brands and retailers have set sustainability targets around transitioning to renewable materials and zero deforestation policies, pulling supply chains to adopt greener chemistries. This creates market demand signals. Government Policy Support

Regulatory incentives like tax credits in the US and EU, along with low carbon fuel standards provide impetus for investments in renewable chemicals capacity growth. Policy aims to promote climate action and energy independence. Technological Advancements

R&D breakthroughs such as new catalytic conversion processes and biotechnology tools allow for more efficient renewable chemical production pathways compared to previous generations of technology. This improves economics. Top Renewable Chemical Platforms Emerging Several core renewable chemical platforms centered around biomass sugars, oils and wastes are emerging at commercial scale across different industries: Cellulosic ethanol - Second generation biofuel produced from non-food plant fibers via conversion of cellulose and hemicellulose. Biobased succinic acid - Building block chemical made through fermentation able to replace petro-based variants. Biobased adipic acid - Nylon precursor chemical replacing one produced from fossil fuels. Renewable polyethylene - Biomass-derived bioplastic resin for packaging, consumer goods. Aromatics from lignin - Fraction of plant fiber converted into drop-in renewable benzene, toluene, xylene for fuels/chemistry. Biobased solvents/lubricants - Green alternatives to existing fossil-derived chemicals in many industrial applications. While most reusable chemicals still make up a small percentage of overall production compared to petrochemicals, early commercial successes point the way towards greater volumes and integration into existing supply chains this decade. As reusable chemicals displace petroleum-derived equivalents, their uptake promises meaningful reductions in greenhouse gas emissions over the full product life cycles. Their increasing adoption represents an encouraging transition towards more sustainable chemistry. Commercial Successes and Key Players Several renewable chemical platforms have now reached commercial scale, producing thousands of tons annually. Some of the leading companies at the forefront include: Praj Industries (cellulosic ethanol) Genomatica/Corbion (succinic acid) Archer Daniels Midland/Marquis Energy (biobased aromatics) Cargill/Dow (biobased polymers/resins) Neste (renewablediesel/jet fuel, lubricants) Others like LanzaTech, Gevo and Lygos are also progressing commercial cellulosic sugars and biochemical routes. Major oil, gas and chemical majors increasingly see renewable opportunities too - companies like Shell, Total, BASF and Eastman have made sizeable biomass-focused investments. While costs remain higher than petrochemical equivalents currently, rapidly expanding production volumes as capacities grow is expected to drive renewable chemical prices down towards parity this decade. With supportive policies, technology improvements and continued scale-up, renewable chemicals clearly demonstrate the potential as sustainable alternatives to traditional petro-based products. Their increasing adoption will be instrumental in reducing greenhouse gas emissions across multiple industries and transitioning to a low-carbon circular bioeconomy. As commercial successes continue demonstrating technological and economic viability, renewable chemicals appear poised for meaningful market growth.

Cyclohexanone Prices, Trends & Forecasts | Provided by Procurement Resource

Cyclohexanone is a colourless to pale yellow liquid that is an organic molecule with a unique and pleasing peppermint-like odour. Its chemical structure includes a six-membered ring cyclic ketone, including a carbonyl group (-CO-).

Request for Real-Time Cyclohexanone Prices: https://procurementresource.com/resource-center/cyclohexanone-price-trends/pricerequest

The molecule is extremely reactive and combustible, fiercely reacting with strong acids and oxidising agents. It readily dissolves in organic solvents like ethanol, acetone, methanol, and ether.

Key Details About the Cyclohexanone Price Trends:

Procurement Resource does an in-depth analysis of the price trend to bring forth the monthly, quarterly, half-yearly, and yearly information on the Cyclohexanone price in its latest pricing dashboard. The detailed assessment deeply explores the facts about the product, price change over the weeks, months, and years, key players, industrial uses, and drivers propelling the market and price trends.

Each price record is linked to an easy-to-use graphing device dated back to 2014, which offers a series of functionalities; customization of price currencies and units and downloading of price information as excel files that can be used offline.

The cyclohexanone price trends, including India Cyclohexanone price, USA Cyclohexanone price, pricing database, and analysis can prove valuable for procurement managers, directors, and decision-makers to build up their strongly backed-up strategic insights to attain progress and profitability in the business.

Industrial Uses Impacting Cyclohexanone Price Trends:

Cyclohexanone is mainly employed as a solvent which facilitates the production of various compounds like caprolactam, adipic acid, and hexamethylenediamine, which are all used in nylon making. As the nylon market is witnessing rapid demand due to its application in end-use industries, like textile, automotive, and packaging, it will also boost demand for cyclohexanone. The chemical also works as a solvent to produce a few medicines, insecticides, and other chemical compounds. Other factors furthering the market expansion include a rising population, lifestyle changes and the increasing demand for food and agricultural goods.

Key Players:

BASF SE

OSTCHEM

Honeywell International Inc

UBE INDUSTRIES, LTD.

News & Recent Development

29th May 2023- The cyclohexanone benchmark price reached 9320.00 RMB/ton, from the previous 9510.00 RMB/ton declining by -2.00%. This decline was caused by weak feedstock benzene prices, frail demand, lower transaction focus, and high availability of product availability.

About Us:

Procurement Resource offers in-depth research on product pricing and market insights for more than 500 chemicals, commodities, and utilities updated daily, weekly, monthly, and annually. It is a cost-effective, one-stop solution for all your market research requirements, irrespective of which part of the value chain you represent.

We have a team of highly experienced analysts who perform comprehensive research to deliver our clients the newest and most up-to-date market reports, cost models, price analysis, benchmarking, and category insights, which help in streamlining the procurement process for our clientele. Our team tracks the prices and production costs of a wide variety of goods and commodities, hence, providing you with the latest and consistent data.

To get real-time facts and insights to help our customers, we work with a varied range of procurement teams across industries. At Procurement Resource, we support our clients, with up-to-date and pioneering practices in the industry, to understand procurement methods, supply chain, and industry trends, so that they can build strategies to achieve maximum growth.

Contact Us:

Company Name: Procurement Resource Contact Person: Chris Byrd Email: [email protected] Toll-Free Number: USA & Canada – Phone no: +1 307 363 1045 | UK – Phone no: +44 7537 132103 | Asia-Pacific (APAC) – Phone no: +91 1203185500 Address: 30 North Gould Street, Sheridan, WY 82801, USA

Polybutylene Adipate Terephthalate (PBAT) Prices | Pricing | Trend | News | Database

 Polybutylene Adipate Terephthalate (PBAT) prices is an emerging biodegradable polymer that has gained significant attention in recent years due to its environmentally friendly characteristics and versatility in various applications. As industries and consumers increasingly prioritize sustainability, the demand for PBAT has surged, influencing its market dynamics and pricing trends. Understanding the factors affecting PBAT prices is crucial for businesses and stakeholders in the polymer industry.

The price of PBAT is influenced by several factors, including raw material costs, production processes, and market demand. Raw materials used in the production of PBAT, such as adipic acid, terephthalic acid, and butanediol, play a significant role in determining its cost. Fluctuations in the prices of these raw materials can directly impact the overall cost of PBAT. For instance, increases in the prices of petrochemical-based raw materials due to supply chain disruptions or geopolitical issues can lead to higher PBAT prices. Conversely, advancements in the production technology or the development of more cost-effective raw material sources can contribute to lower PBAT prices.

Get Real Time Prices for PBAT: https://www.chemanalyst.com/Pricing-data/polybutylene-adipate-terephthalate-resin-1219

Production processes also affect PBAT pricing. The complexity and scale of PBAT production involve various steps, including polymerization and blending, which require specialized equipment and technology. As manufacturers invest in advanced technologies to improve production efficiency and reduce costs, the pricing of PBAT can experience fluctuations. Innovations in production methods that enhance yield and reduce energy consumption can potentially lower production costs, thereby influencing PBAT prices in the market.

Market demand plays a pivotal role in shaping PBAT prices. As awareness of environmental issues grows, the demand for biodegradable and compostable materials like PBAT is increasing. This heightened demand can lead to price fluctuations based on supply and demand dynamics. When demand outpaces supply, prices tend to rise, reflecting the scarcity of the material. On the other hand, if supply exceeds demand, prices may decrease. The growth of industries such as packaging, agriculture, and textiles, which utilize PBAT for its biodegradable properties, contributes to the overall demand and, consequently, impacts pricing trends.

Another critical factor affecting PBAT prices is the competitive landscape within the polymer industry. As more manufacturers enter the market and production capacities expand, competition can influence pricing strategies. Competitive pressures may drive manufacturers to optimize their production processes, reduce costs, and offer more competitive prices to attract customers. Conversely, if the market remains concentrated with a few dominant players, pricing may be less volatile and more stable.

Regulatory policies and environmental regulations also play a significant role in PBAT pricing. Governments and regulatory bodies worldwide are increasingly implementing policies to promote sustainable practices and reduce plastic waste. These regulations often favor the use of biodegradable materials like PBAT, creating a favorable market environment for such polymers. However, compliance with stringent regulatory standards may increase production costs, which can, in turn, affect PBAT prices.

The global economic environment and trade conditions further impact PBAT pricing. Economic fluctuations, currency exchange rates, and international trade policies can influence the cost of raw materials, production, and transportation. For instance, changes in exchange rates can affect the cost of imported raw materials, leading to price adjustments for PBAT. Additionally, trade barriers or tariffs imposed on raw materials or finished products can impact pricing dynamics in the global market.

In conclusion, PBAT prices are influenced by a complex interplay of factors, including raw material costs, production processes, market demand, competition, regulatory policies, and global economic conditions. As the demand for sustainable and biodegradable materials continues to grow, understanding these factors is essential for businesses and stakeholders to navigate the evolving PBAT market. By staying informed about these influences, industry participants can make strategic decisions and anticipate pricing trends in the dynamic landscape of polymer production and consumption.

Get Real Time Prices for Polybutylene Adipate Terephthalate (PBAT): https://www.chemanalyst.com/Pricing-data/polybutylene-adipate-terephthalate-resin-1219

Contact Us:

ChemAnalyst

GmbH - S-01, 2.floor, Subbelrather Straße,

15a Cologne, 50823, Germany

Call: +49-221-6505-8833

Email: [email protected]

Website: https://www.chemanalyst.com

Beverage Acidulants Market Giants Spending Is Going To Boom | Tate and Lyle, Cargill, Hawkins Watts, Weifang Ensign Industry

Latest Study on Industrial Growth of Beverage Acidulants Market 2023-2028. A detailed study accumulated to offer Latest insights about acute features of the Beverage Acidulants market. The report contains different market predictions related to revenue size, production, CAGR, Consumption, gross margin, price, and other substantial factors. While emphasizing the key driving and restraining forces for this market, the report also offers a complete study of the future trends and developments of the market. It also examines the role of the leading market players involved in the industry including their corporate overview, financial summary and SWOT analysis.

Get Free Exclusive PDF Sample Copy of This Research @ https://www.advancemarketanalytics.com/sample-report/114551-global-beverage-acidulants-market?utm_source=Benzinga&utm_medium=Vinay

Major players profiled in the study are:

Cargill, Inc. (United States), Tate and Lyle (United Kingdom), Northeast Pharmaceutical Group Co. Ltd. (China), Archer Daniels Midland , Corbion N.V. (Netherlands), Hawkins Watts Limited (Australia), Parry Enterprises India Ltd. (India), FBC Industries, Inc. (United States), Weifang Ensign Industry Co., Ltd. (China)

Scope of the Report of Beverage Acidulants

Acidulants namely acetic, adipic, fumaric, citric, lactic, malic, tartaric acids, phosphoric, and glucono-delta-lactone are commonly used as food additives in processed beverages to not only impart sour taste but also to adjust the pH, enhance and modify the flavors and sweetness of sugars. Furthermore, beverage acidulants are extensively used in the beverage processing industry as preservatives, additives, and flavoring agents.

The Global Beverage Acidulants Market segments and Market Data Break Down are illuminated below:

by Type (Citric Acid, Acetic Acid, Fumaric Acid, Lactic Acid, Phosphoric Acid, Malic Acid, Tartaric Acid, Others), Application (Dairy-based Beverages, Alcoholic Beverages, Soft Drinks, Other), Nature (Synthetic, Organic), Form (Powder, Granules, Liquid), Distribution Channel (Online Stores, Supermarkets, Specialized Stores, Others)

Market Opportunities:

Growing Beverage Industries across the Developing Countries

Increasing Consumer Preference for Natural Colors

Market Drivers:

The Expansion of the Beverage Processing Industry

The Use of Beverage Acidulants Not Only Enhance Flavor But Also Increase the Shelf Life of Beverages

Change in consumer behavior and lifestyle fuelling the Market Growth

A Rise in Demand for Longer Shelf Life Products

Market Trend:

Increased Application of Citric Acidulants in the Beverages

What can be explored with the Beverage Acidulants Market Study?

Gain Market Understanding

Identify Growth Opportunities

Analyze and Measure the Global Beverage Acidulants Market by Identifying Investment across various Industry Verticals

Understand the Trends that will drive Future Changes in Beverage Acidulants

Understand the Competitive Scenarios

Track Right Markets

Identify the Right Verticals

Region Included are: North America, Europe, Asia Pacific, Oceania, South America, Middle East & Africa

Country Level Break-Up: United States, Canada, Mexico, Brazil, Argentina, Colombia, Chile, South Africa, Nigeria, Tunisia, Morocco, Germany, United Kingdom (UK), the Netherlands, Spain, Italy, Belgium, Austria, Turkey, Russia, France, Poland, Israel, United Arab Emirates, Qatar, Saudi Arabia, China, Japan, Taiwan, South Korea, Singapore, India, Australia and New Zealand etc.

Have Any Questions Regarding Global Beverage Acidulants Market Report, Ask Our Experts@ https://www.advancemarketanalytics.com/enquiry-before-buy/114551-global-beverage-acidulants-market?utm_source=Benzinga&utm_medium=Vinay

Table of Contents

Global Beverage Acidulants Market Research Report

Chapter 1 Global Beverage Acidulants Market Overview

Chapter 2 Global Economic Impact on Industry

Chapter 3 Global Market Competition by Manufacturers

Chapter 4 Global Productions, Revenue (Value) by Region

Chapter 5 Global Supplies (Production), Consumption, Export, Import by Regions

Chapter 6 Global Productions, Revenue (Value), Price Trend by Type

Chapter 7 Global Market Analysis by Application

Chapter 8 Manufacturing Cost Analysis

Chapter 9 Industrial Chain, Sourcing Strategy and Downstream Buyers

Chapter 10 Marketing Strategy Analysis, Distributors/Traders

Chapter 11 Market Effect Factors Analysis

Chapter 12 Global Beverage Acidulants Market Forecast

Finally, Beverage Acidulants Market is a valuable source of guidance for individuals and companies.

Read Detailed Index of full Research Study at @ https://www.advancemarketanalytics.com/buy-now?format=1&report=114551?utm_source=Benzinga&utm_medium=Vinay

Thanks for reading this article; you can also get individual chapter wise section or region wise report version like North America, Middle East, Africa, Europe or LATAM, Southeast Asia.

Contact Us:

Craig Francis (PR & Marketing Manager)

AMA Research & Media LLP

Unit No. 429, Parsonage Road Edison, NJ

New Jersey USA – 08837

#BeverageAcidulants

#GlobalBeverageAcidulantsMarket

#BeverageAcidulantsMarket

Concentrated Nitric Acid Market Analysis: Regulatory Compliance and Safety Measures

Concentrated nitric acid, often abbreviated as CNA, is a highly corrosive and potent chemical that plays a vital role in various industrial applications. This versatile compound is a key ingredient in the production of a wide range of products, including explosives, fertilizers, and chemicals. The concentrated nitric acid market is dynamic and ever-evolving, influenced by factors such as demand in the chemical industry, agricultural needs, and global economic conditions. In this article, we will explore the Concentrated Nitric Acid market, its applications, key players, trends, and future prospects.

Market Overview

The concentrated nitric acid market is an essential segment of the global chemical industry. This market primarily deals with the production, distribution, and utilization of concentrated nitric acid, which typically has a concentration of 68-70% nitric acid in water. This chemical compound is highly corrosive, and its handling and storage require specialized equipment and precautions.

Key Applications

Chemical Manufacturing: The chemical industry is the largest consumer of concentrated nitric acid. It is used in the production of various chemicals, including ammonium nitrate, adipic acid, and toluene diisocyanate. The demand for these chemicals, in turn, is driven by sectors such as agriculture, automotive, and construction.

Explosives: Concentrated nitric acid is a crucial component in the manufacturing of explosives, particularly ammonium nitrate-fuel oil (ANFO) and nitroglycerin. These explosives are used in mining, construction, and military applications.

Fertilizers: Agriculture is a significant driver of the concentrated nitric acid market. Nitric acid is a key component in the production of nitrogen-based fertilizers, which are essential for crop growth and food production.

Pharmaceuticals: In the pharmaceutical industry, concentrated nitric acid is used for various applications, including the synthesis of active pharmaceutical ingredients and cleaning and sterilizing equipment.

Market Trends

Environmental Regulations: Environmental concerns have led to tighter regulations on the production and handling of concentrated nitric acid. This has prompted the industry to adopt cleaner and safer technologies to minimize emissions and environmental impact.

Technological Advancements: Ongoing research and development in the field of nitric acid production have resulted in more efficient and cost-effective methods. This has led to increased production capacities and reduced costs, making nitric acid more accessible to various industries.

Shift Towards Green Chemistry: The chemical industry, including the concentrated nitric acid sector, is gradually shifting towards green and sustainable practices. Companies are exploring ways to minimize waste, reduce energy consumption, and incorporate renewable resources into the production process.

Global Economic Factors: The concentrated nitric acid market is also influenced by broader economic trends. Fluctuations in the global economy can impact demand, pricing, and investment in the industry.

Key Players

Several global and regional players dominate the concentrated nitric acid market. Some of the prominent companies include:

BASF SE: BASF is a global chemical giant with a significant presence in the concentrated nitric acid market. They produce and distribute nitric acid for various industrial applications.

CF Industries: CF Industries is a major player in the agricultural sector, producing nitrogen-based fertilizers using concentrated nitric acid as a primary raw material.

Yara International: Yara is another leading player in the fertilizers segment, with a focus on sustainable and environmentally friendly agricultural solutions.

Thermo Fisher Scientific: Thermo Fisher provides high-purity concentrated nitric acid for laboratory and analytical applications.

Future Prospects

The future of the concentrated nitric acid market looks promising, with several factors contributing to its growth:

Population Growth: The global population is on the rise, driving the demand for food and agricultural products. This, in turn, increases the demand for nitrogen-based fertilizers, sustaining the market's growth.

Industrialization and Infrastructure Development: Ongoing industrialization and infrastructure development in emerging economies are expected to boost the demand for explosives and construction materials, driving the need for concentrated nitric acid.

Sustainable Practices: The market is likely to witness a shift towards more sustainable practices, with a focus on reducing environmental impact. Green chemistry and cleaner production methods will play a significant role in shaping the industry's future.

In conclusion, the concentrated nitric acid market is a vital component of the global chemical industry, serving various sectors such as chemicals, agriculture, and explosives. As industries continue to evolve and environmental concerns drive innovation, the market is expected to adapt and thrive, meeting the demands of a changing world while maintaining safety and sustainability.

Melting point range of adipic acid

Adipic acid is an organic compound with the formula (CH2)4(COOH)2. It is a white crystalline powder that is mainly used as a precursor for the production of nylon. Adipic acid is also used as a food additive, a plasticizer, and a component of some polyurethanes. In this article, we will explore the melting point range of adipic acid and its implications for its applications.

What is the Melting Point of Adipic Acid?

The melting point of a substance is the temperature at which it changes from a solid to a liquid state. The melting point range is the interval between the onset and the completion of melting. The melting point range can indicate the purity and stability of a substance, as well as its intermolecular forces.

According to EU Method A.1 (Melting / Freezing Temperature), the melting point of adipic acid is 150.85°C. This means that adipic acid starts to melt at this temperature and becomes completely liquid when heated further. The melting point range of adipic acid is not very wide, which suggests that it is a relatively pure and stable substance.

How Does the Melting Point Affect the Properties of Adipic Acid?

The melting point of adipic acid affects its physical and chemical properties, as well as its suitability for different applications. For example, adipic acid has a high solubility in water, which increases with temperature. At 25°C, adipic acid dissolves in water at 24 g/L, while at 100°C, it dissolves at 1600 g/L. This means that adipic acid can be easily dissolved and purified by recrystallization from water.

Another example is that adipic acid has a low vapor pressure, which decreases with temperature. At 18.5°C, adipic acid has a vapor pressure of 0.097 hPa, while at 25°C, it has a vapor pressure of 0.073 mmHg. This means that adipic acid does not evaporate easily and has a low volatility. This makes adipic acid suitable for applications that require high thermal stability, such as nylon production.

What are Some Applications of Adipic Acid?

Adipic acid is mainly used as a raw material for the production of nylon 6,6, which is a synthetic polymer with high strength, elasticity, and resistance to abrasion and chemicals. Nylon 6,6 is widely used in textiles, carpets, clothing, ropes, and industrial materials.

Adipic acid is also used as a food additive (E355) to provide acidity and flavor to some beverages and foods. It can also act as a leavening agent in baked goods and a gelling agent in some desserts.

Additionally, adipic acid is used as a plasticizer to improve the flexibility and durability of some plastics, such as polyvinyl chloride (PVC). It can also be used as a component of some polyurethanes, which are versatile polymers that can form foams, coatings, adhesives, and elastomers.

Conclusion

Adipic acid is an important dicarboxylic acid that has a melting point of 150.85°C. The melting point range of adipic acid affects its solubility, volatility, and thermal stability, which in turn influence its properties and applications. Adipic acid is mainly used for nylon production, but it also has other uses in food, plastics, and polyurethanes.

If you are looking for a reliable Adipic Acid supplier(CAS124-04-9), you can visit our website www.qiboch.com. We supply high quality Adipic Acid with competitive price and fast delivery. We also provide technical support and customer service to ensure your satisfaction. Whether you need adipic acid for industrial or laboratory use, we have the right product for you, contact us today!

アジピン酸(Adipic Acid)の価格価格動向: 詳細なチャート、市場分析、将来の見通し

アジピン酸 (Adipic Acid) は、ナイロン、ポリウレタン、さまざまな可塑剤の製造、食品添加物、医薬品に広く使用されている重要な有機化合物です。アジピン酸の価格設定は、化学業界の関係者が市場の動向を理解し、情報に基づいた決定を下すために考慮しなければならないいくつかの重要な要因の影響を受けます。

アジピン酸の価格に影響を与える主な要因の 1 つは、原材料のコストと入手可能性です。アジピン酸は主に、石油由来の製品であるベンゼンから得られるシクロヘキサンから生産されます。原油価格の変動によるベンゼンとシクロヘキサンの価格変動は、アジピン酸の生産コストに直接影響します。原油価格が上昇すると、ベンゼンとシクロヘキサンのコストが上昇し、アジピン酸の価格が上昇します。逆に、原油価格が下落すると、生産コストが下がり、アジピン酸の価格競争力が高まります。

生産および精製プロセスも、アジピン酸の価格決定に重要な役割を果たします。生産施設の複雑さ、効率性、技術の進歩は、生産コストに影響を与える可能性があります。最先端の技術と最適化されたプロセスを備えた工場は、より効率的かつ低コストでアジピン酸を生産できます。一方、プロセスの効率性が低い古い施設は、生産コストが高くなる可能性があり、それがアジピン酸の価格上昇につながる可能性があります。

市場の需要と供給のダイナミクスは、アジピン酸の価格形成に不可欠です。アジピン酸は、繊維、自動車部品、産業用途で使用されるナイロン 6,6 の生産における重要な成分です。したがって、ナイロン 6,6 の需要は、アジピン酸の需要に直接影響します。産業活動が活発な時期、自動車生産の増加、消費財の需要の増加は、アジピン酸の需要を押し上げ、価格上昇につながる可能性があります。逆に、経済の減速、産業生産の減少、または特定のセクターの衰退は、需要を減らし、アジピン酸の価格に下押し圧力をかける可能性があります。

環境規制と持続可能性の取り組みは、アジピン酸の生産と価格にますます影響を与えています。排出物や特定の化学物質の使用に関する環境規制が厳しくなると、製造業者はよりクリーンな技術やコンプライアンス対策に投資するため、製造コストが上昇する可能性があります。これらのコスト増加は消費者に転嫁され、アジピン酸の価格が上昇する可能性があります。さらに、バイオベースの代替品の使用や環境に優しい生産方法の開発を促進する持続可能性イニシアチブは、従来のアジピン酸の需要に影響を与え、市場価格に影響を及ぼす可能性があります。

生産方法における技術の進歩と革新もアジピン酸の価格に影響を与える可能性があります。触媒プロセスの改善、バイオベースの生産方法の開発、化学工学の進歩により、生産効率が向上し、コストが削減されます。これらの革新を採用する企業は、より競争力のある価格を提供できますが、遅れをとっている企業は、生産コストと製品の価格が上昇する可能性があります。

リアルタイムで アジピン酸 (Adipic Acid)価格: https://www.analystjapan.com/Pricing-data/adipic-acid-33

輸送と物流のコストは、アジピン酸の全体的な価格設定に大きな影響を与えます。原材料を生産施設に輸送し、完成品をエンドユーザーに配布するコストは、燃料価格、輸送イン��ラ、地政学的安定性などの要因によって異なります。燃料価格の変動は輸送費に直接影響し、アジピン酸の価格に影響します。さらに、サプライ チェーンの混乱や輸送のボトルネックなどの物流上の課題は、供給不足や価格変動につながる可能性があります。

世界的な貿易政策と国際関係は、アジピン酸の価格形成において極めて重要な役割を果たします。貿易協定、関税、輸出入規制は、国境を越えた原材料や完成品の流れに影響を与える可能性があります。たとえば、輸入原材料やアジピン酸に対する関税は、生産コストを上昇させ、市場価格に影響を与える可能性があります。貿易紛争や主要化学品生産国に対する制裁は、サプライ チェーンを混乱させ、アジピン酸市場の価格変動を引き起こす可能性があります。

経済状況やより広範な市場動向もアジピン酸の価格に影響を与えます。インフレ、為替レート、全体的な経済成長または縮小は、生産コスト、消費者需要、市場価格に影響を与える可能性があります。インフレ圧力は、原材料、労働、輸送のコスト上昇につながり、アジピン酸の価格を上昇させる可能性があります。逆に、産業活動が活発な好景気は需要の高まりを促し、価格上昇につながる可能性があります。

ANALYST JAPAN

Call +1 (332) 258- 6602 1-2-3 Manpukuji, Asao-ku, Kawasaki 215-0004 Japan

Website: https://www.analystjapan.com

Email: [email protected]

Pure benzene | The supply and demand level in May was lower than that in April and June or is expected to rebound

In May 2023, due to the reduction of imports and shrinking demand, the daily level of supply and demand was lower than in April. June is expected to surpass May on both sides of the supply and demand, but hopes for a recovery in demand brought about by the restart of downstream devices. The monthly production of pure benzene in May 2023 is estimated at 1.577 million tons, an increase of 23,000 tons from the previous month and an increase of 327,000 tons from the same month last year. Based on the total capacity of 22.266 million tons, the capacity utilization rate was down 1.3% from April to 76.2% based on the operating rate of 8,000 hours. The maintenance loss in the month was 214,000 tons, an increase of 29,000 tons from the previous month. Maintenance losses in May are expected to be the highest of the year. In May, the pure benzene production was estimated to be 1.577 million tons, and the daily production was estimated to be 50,900 tons, lower than the daily production of 51,800 tons in April. In terms of import volume, affected by the opening of the arbitrage window between the United States and South Korea and the low price in China, imports in May were assessed at 200,000 tons or lower. On the demand side, downstream demand in May was estimated at 2.123 million tons, lower than the level of 2.129 million tons in April. The consumption of p-benzene in the downstream of the main body of pure benzene (styrene, caprolactam, phenol, aniline, adipic acid) was 2,017 million tons, an increase of 0.1 million tons from the previous month. The average daily consumption of the main downstream in May was 65,100 tons, less than the average daily consumption of 67,200 tons in April. In terms of exports, exports in May were assessed at 0.6 million tons, lower than the level in April. On the whole, the supply of pure benzene in May was slightly less than last month due to the decrease in imports, and the demand was slightly less than last month due to the decrease in main downstream and exports. Considering that there are more natural days in May than in April, the daily levels at both ends of pure benzene supply and demand in May are lower than in April. The output in June is expected to be 1.564 million tons, with a capacity base of 22.716 million tons and a capacity utilization rate of 76.5%. Daily production was estimated at 52,100 tons, up from 50,900 tons in May. The production increase mainly takes into account the construction of Jiaxing Sanjiang ethylene cracking plant and Zibo Junchen Aromatics extraction plant, and also makes corresponding correction to the effect of the reduction of partial disproportionation plant on the production of pure benzene. In terms of import volume, affected by the short-term opening of the China-South Korea window, imports in June were assessed at 250,000 tons or more. On the demand side, downstream demand in June was estimated at 2.085 million tons, lower than the level of 2.123 million tons in May. The consumption of p-benzene in the downstream of the main body of pure benzene (styrene, caprolactam, phenol, aniline, adipic acid) was 1.979 million tons, down 38,000 tons from the previous month. The average daily consumption of the main downstream in June was 6600 tons, more than the average daily consumption of 65,100 tons in May, but still lower than 67,200 tons in April. The increase in demand is mainly due to the production of Zhejiang Petrochemical's POSM new plant in late June, as well as the return of phenol overhaul equipment. In terms of exports, exports in June were estimated at 6,000 tons, flat at the level of May. In summary, the supply of pure benzene in June was more than that in May due to the production of new plants, and the demand was more than that in May due to the production of new plants downstream of the main body. Considering that the natural days in June are less than those in May, it is expected that the daily levels of both ends of pure benzene supply and demand in June are higher than those in May. Combined with the level of supply and demand from April to June, only with the current optimistic expectations, the downstream demand side is expected to recover in June compared with May, but it is expected to fail to return to the level of April. The supply side is expected to show steady growth with the end of the intensive maintenance period. In June, social supply and demand balance or tend to be tired. However, considering that imports in May were concentrated in enterprises, the amount to the reservoir area was relatively small; As well as the main refinery fixed supply direction caused by the reduction of pick-up expectations in the reservoir area, port storage or not obvious. Joyce MIT-IVY INDUSTRY Co.,Ltd. Xuzhou, Jiangsu, China Phone/WhatsApp : + 86 13805212761 Email : [email protected] http://www.mit-ivy.com Read the full article