Primary Examiner:

What is polyolefin?
A polyolefin is a type of polymer with the general formulaₙ where R is an alkyl group. They are usually derived from a small set of simple olefins. Dominant in a commercial sense are polyethylene and polypropylene. More specialized polyolefins include polyisobutylene and polymethylpentene. They are all colorless or white oils or solids. Many copolymers are known, such as polybutene, which derives from a mixture of different butene isomers. The name of each polyolefin indicates the olefin from which it is prepared; for example, polyethylene is derived from ethylene, and polymethylpentene is derived from 4-methyl-1-pentene. Polyolefins are not olefins themselves because the double bond of each olefin monomer is opened in order to form the polymer. Monomers having more than one double bond such as butadiene and isoprene yield polymers that contain double bonds and are usually not considered polyolefins. Polyolefins are the foundations of many chemical industries.

How are polyolefins made?
The major processes for polyolefins’ production using Ziegler–Natta catalysts involve polymerization in the gas phase or in slurry, including bulk liquid monomer in the case of propylene. LLDPE is also produced via a solution process operating at temperatures in the range 130–250 °C. Polyolefins are produced using refined metallocene catalysts that have a constrained transition metal (generally a Group 4B metal such as Ti, Zr, or Hf) sandwiched between one or more cyclopentadienyl ring structures to form a sterically hindered polymerization site. Polyolefins, also called polyalkenes, are the largest class of commodity thermoplastics. They are polymers of simple alkenes such as ethylene, propylene, butenes, and pentenes, and copolymers thereof. The two most important polyolefins are polyethylene (PE) and polypropylene (PP).

What was the production of polyolefins in 2000?
Polyolefin fibre production by year 2000 was over 1.45 Mt (3.18 billion lb), while the polyester total was 1.76 Mt (3.87 billion lb).

How big is the global market for polyolefins?
Presently, the total world polyolefins capacity exceeds 120 million tons per year. Polyethylene (i.e., HDPE, LDPE and LLDPE) and polypropylene cover 60 % and 40 % of the total polyolefins production, respectively. The annual world-wide polyolefins market growth in the coming years is foreseen to be 4-6%.

What are the industrial applications of polyolefin fibres?
Polyolefin fibres, in particular slit films and monofilament, are used in industrial applications to manufacture ropes, cordages, agricultural nets, and FIBCs (flexible intermediate bulk containers).

Major Manufacturers of Polyolefin and Suppliers of Polyolefin in the World

• LG Chem Ltd.
• Constab Polyolefin Additives GmbH
• Mc Tohcello (Malaysia) Sdn Bhd
• Dow Europe GmbH
• SK Chemicals
• Deutsche Infineum GmbH
• Bagla Polifilms Ltd.
• Siam Synthetic Latex Co., Ltd.
• Hoyer France
• Lubrizol France

TOP 40 POLYOLEFIN PRODUCERS (POLYPROPYLENE, POLYETHYLENE & COPOLYMERS)

• Alpek
• Arkema
• Borealis Group
• Borouge
• Braskem
• Chevron-Phillips
• CNPC
• Dow
• DuPont
• Eastman
• ENI
• ExxonMobile
• Formosa Plastics
• Hanwha
• Indorama
• Ineos
• KAP
• Kayavlon Impex
• LCY Chemical
• LG Chem
• Lyondellbasell
• Mitsubishi
• Mitsui Chemicals
• Mol Group
• Nova Chemicals
• Petkim
• Petroquim
• Polyone
• Quenos
• Reliance
• Repsol
• Sabic
• Sasol
• Saudi Polymers
• SCG Chemical
• SEPC
• Sibur
• Sinopec
• Sipchem
• SK Global Chemical
• Sumitomo
• Tosoh
• Total
• TPC
• UBE Industries
• Westlake

Pentane, Hexane and Heptane Prices, Upstream, Downstream, Analytics & Forecasts
Junyuan Petroleum Group – Dongying Liangxin Petrochemical Technology Development Limited Company | Address: No. 117, Guangqing Rd., Guangrao County, Dongying 257345 China.
Junyuan Petroleum Group is China’s largest manufacturer of blowing agents to the foam insulation markets. We have continued to grow with the development of next generation blowing agents, offering a variety of hydrocarbon products for the PIR, PUR and EPS markets, available in ISO tanks and drums. For more information, or for pricing please contact us: +86 178 1030 0898 Email: info@junyuanpetroleumgroup.com Web: www.junyuanpetroleumgroup.com.
China is the world’s largest buyer and drives prices in Asia and the global solvent trade. Our comprehensive news and pricing coverage of China and global solvent market is constantly updated by our raw material purchase, production and sales team of experts. Solvent markets can react to change quickly. It’s crucial for buyers, sellers and producers to stay alert and aware of what’s happening, both in their region and internationally. We help you stay abreast of change as it’s happening. We keep you informed of the current price and market position, so you can make the most of opportunities to trade or secure a deal.

Name in Chinese: Gas Chromatography 气相色谱图
Definition: time distribution image of separated component detection signal
Pinyin: Q ì Xi à ng s è p ǔ  tú
Name in English: chromatogram

Related Terms
⊕ chromatogram – the signal time curve obtained when the sample flows through the chromatographic column and detector, also known as the chromatographic outflow profile.
⊕ baseline — after the mobile phase is flushed and the column and mobile phase reach equilibrium, the detector measures the outflow curve for a period of time. Generally, it should be parallel to the time axis.
⊕ noise – fluctuation of baseline signal. It is usually caused by poor power contact or instantaneous overload, unstable detector, bubble in mobile phase or contamination of chromatographic column.
⊕ drift – the slow change of the baseline over time. It is mainly caused by the instability of operating conditions such as voltage, temperature, mobile phase and flow. The pollutants or stationary phase in the column will also drift after being eluted continuously.
⊕ chromatographic peak – the curve generated by the corresponding continuous signal when the group is shunted through the detector. A projection on an outflow curve. The normal chromatographic peak is similar to the symmetrical normal distribution curve (Gaussian Gauss curve). There are two kinds of asymmetric chromatographic peaks: leading peak and tailing peak. The former is rare.
⊕ tailing factor (T) — t = B / A, which is used to measure the symmetry of chromatographic peaks. Also known as symmetry factor or asymmetry factor, t should be 0.95 ~ 1.05 according to Chinese Pharmacopoeia. T1. 05 is the tailing peak.
⊕ peak bottom – the distance from the starting point of the peak on the baseline to the end point.
⊕ peak height (H) – the distance from the highest point of the peak to the bottom of the peak.
⊕ peak width (W) – the distance between the two tangents at the inflection points on both sides of the peak and the two intersections of the baseline. W=4 σ。
⊕ peak width that height (WH / 2) – peak width at half of peak height. Wh/2=2.355 σ。
⊕ standard deviation, σ）—— Half of the peak width of the normal distribution curve when x = ± 1 (inflection point). The inflection point of normal peak width is 0.607 times of peak height. The standard deviation indicates the dispersion degree of components in the process of flowing out of the chromatographic column. σ Small, small dispersion, high pole concentration, thin peak shape and high column efficiency; conversely, σ Large, fat peak shape and low column efficiency.
⊕ peak area (a) – the area surrounded by the peak and the peak bottom. A= ×σ× h=2.507 σ h=1.064Wh/2h。
signal
Tailless peak
chromatographic column
Chromatographic outflow curve

Event Details

Global Petrochemical Industry Training Course

20/04/2022-22/04/2022, Amsterdam, Netherlands

For further details contact:

NexantECA TrainingTel: +44-207-950-1600Email: contactus@nexanteca.com

Event Details

Chinaplas 2022

25/04/2022-28/04/2022, Shanghai, China

For further details contact:

Adsale Exhibition Services Ltd.Ms. Stella Yuen
Call: (852) 2516 3305Email: chinaplas@adsale.com.hkwebsite: www.chinaplasonline.com

Event Details

PaintExpo:

26/04/2022-29/04/2022, Karlsruhe, Germany

For further details contact:

FairFair GmbHMarkus Beck
Telefon +49 7022 60255 20Email: beck@fairfair.dewebsite: www.paintexpo.de/en

Event Details

NYSCC Suppliers’ Day 2022

03/05/2022-04/05/2022, New York, USA

For further details contact:

New York Society of Cosmetic ChemistsErin LaytonEmail: elayton@nyscc.orgwebsite: www.nyscc.org/suppliers-day

Event Details

World Hydrogen Projects

11/05/2022-12/05/2022, Barcelona, Spain

For further details contact:

Green Power Conferences Ltd.Jonathan Hull
Tel: +44-0-20-7099-0600Email: Jonathan.Hull@greenpowerglobal.com

Event Details

11th GPCA Plastics Conference

25/05/2022-26/05/2022, Riyadh, Saudi Arabia
The COVID-19 pandemic has reemphasized the indispensable role of plastics in our everyday life. Amongst others, medical-grade masks, gloves, PPE, various medical equipment along with several packaging applications have proved to be a lifesaver and played a vital role in protecting the health and safety of frontline workers as well as civilians during the pandemic. However, the manner in which their disposal is handled poses a serious environmental challenge. This is creating an urgent need to change our mindset from the existing linear take-make-dispose model and shift towards a closed-loop, reusability, and recycling-focused model. This requires a systemic transformation where all waste is viewed as a valuable resource and its value is captured within the economy. This can be achieved on the back of innovation through collaboration along the value chain, which was brought to the limelight during the pandemic.

On the flip side, an increased focus on recycling is both a growing threat and an opportunity to the virgin polymers industry. This is making plastic producers, refiners, waste management companies innovate new business models to develop a global economy where plastics are never wasted. Although collection and sorting remain the most challenging barriers to achieve a circular economy, advancements in advanced recycling technologies are aiming to ease the process.

For further details contact:

Gulf Petrochemicals and Chemicals AssociationMs. Jovelyn Sadoguio, Event Admin Specialist Call: +971 4 451 0666 Ext 153.Email: jovelyn@gpca.org.aewebsite: www.gpcaplastics.com

Event Details

Chemspec Europe

31/05/2022-01/06/2022, Frankfurt, Germany

For further details contact:

Mack-Brooks Exhibitions LtdTel.: +44 (0)1727 814 543
Fax: +44 (0)1727 814 401
Email: info@chemspeceurope.comwebsite: www.chemspeceurope.com

Event Details

Helsinki Chemicals Forum 2022

08/06/2022-09/06/2022, Helsinki, Finland

For further details contact:

MessukeskusMarcus Bergström
Tel: +358 44 562 4524
Email: marcus.bergstrom@messukeskus.comwebsite: helsinkicf.eu

Event Details

in-cosmetics Korea 2022

13/07/2022-15/07/2022, Seoul, Korea South

For further details contact:

Reed Exhibitions Ltd.Jihee Han
Tel: +44-0-208-439-5159Email: jihee.han@reedexpo.co.ukwebsite: www.in-cosmetics.com/korea/en-gb.html

Event Details

PCHi China 2022

18/07/2022-20/07/2022, Shanghai, China

For further details contact:

Reed Sinopharm ExhibitionsShammi Srivastava
Tel: +91 22 6771 6666 / 617
Mobile: +91 99871 42598
shammi.srivastava@reedexpo.co.ukEmail: pchi@reedsinopharm.comwebsite: www.pchi-china.com

Event Details

ACHEMA 2022

22/08/2022-26/08/2022, Frankfurt, Germany

For further details contact:

DECHEMA Ausstellungs-GmbHTel. +49 69 7564-750
Fax +49 69 7564-450Email: visitor@achema.dewebsite: www.achema.de/en

Event Details

32nd International Federation of Societies of Cosmetic Chemists (IFSCC) Congress

19/09/2022-22/09/2022, London, UK

For further details contact:

Society of Cosmetic Scientists (SCS)Tel: +44-0-15827 26661Email: gem.bektas@scs.org.ukwebsite: www.ifscc2022.com

Event Details

K 2022

19/10/2022-26/10/2022, Dusseldorf, Germany

For further details contact:

Messe Düsseldorf GmbHCall: +49 211 4560-7611Email: info@messe-duesseldorf.dewebsite: www.k-online.com

Event Details

in-cosmetics Asia 2022

01/11/2022-03/11/2022, Bangkok, Thailand

For further details contact:

Reed Exhibitions Ltd.Sarah Gibson
Tel: +60-7509-5014Email: sarah.gibson@reedexpo.co.ukwebsite: www.in-cosmetics.com/asia/en-gb.html

Event Details

Vietnam Medi-Pharm Expo

01/12/2022-03/12/2022, Hanoi, Vietnam

For further details contact:

VINEXADThai Huy An
Tel: +84-24-38255546 (Ext: 433)
Mobile: +84-904154438
Email: thaihuyan@hotmail.comEmail: thaihuyan@gmail.comwebsite: www.vinexad.com.vn/en

Event Details

12th World Surfactant Congress

05/06/2023-07/06/2023, Rome, Italy

For further details contact:

Cesio CongressChantal De Cooman, Secretary GeneralEmail: info@cesio.euwebsite: www.cesio-congress.eu

Event Details

CESIO Congress 2023

05/06/2023-07/06/2023, Rome, Italy

For further details contact:

Cesio & Co-manaIris Mathieu
Tel: +32 2 537 87 01Email: iris@co-mana.comwebsite: www.cesio-congress.eu

Event Details

Knowledge Sharing Seminar

13/04/2022-13/04/2022, Mumbai, India

For further details contact:

IPCA Maharashtra RegionAmit Parikh & Jesal Parikh
Tel: +91-22-23441937
Mobile: +91-9873354315Email: maharashtra@ipcaonline.comwebsite: www.ipcaonline.com

Event Details

ChemExpo India 2022

20/04/2022-21/04/2022, Mumbai, India

For further details contact:

Chemical Weekly Database Pvt. Ltd.Rohit Pande
Mobile: +91-98202 24550Email: Rohit@chemexpoindia.comwebsite: www.chemexpoindia.com

Event Details

ChemProTech India 2022

20/04/2022-21/04/2022, Mumbai, India

For further details contact:

ChemProTech India Expo Pvt. Ltd. & VA ExhibitionsRohit Pande
Cell: +91-98202 24550Email: Rohit@chemexpoindia.comwebsite: www.chemprotechindia.com

Event Details

ChemLogistics India 2022

20/04/2022-21/04/2022, Mumbai, India

For further details contact:

ChemProTech India Expo Pvt. Ltd. & VA ExhibitionsRohit Pande
Cell: +91-98202 24550Email: Rohit@chemexpoindia.comwebsite: www.chemlogisticsindia.com

Event Details

PharmaTech Expo & LabTech Expo

28/04/2022-30/04/2022, Chandigarh, India

For further details contact:

PharmaTechExpoManan Doshi
Tel: +91-79-40306340 / 27540493
Mobile: +91-9377235673
Email: manan@pharmatechnologyindex.comEmail: expo@pharmatechnologyindex.comwebsite: www.pharmatechexpo.com

Event Details

International Plastics Exhibition

10/06/2022-13/06/2022, Chennai, India

For further details contact:

Tamilnadu Plastics Manufacturer’s AssociationMr. Deepak Chhalani,
Cell: +91-98407 67679Email: marketing@iplas.inwebsite: www.tapma.in

Event Details

ISDC 2022: International Convention and Exhibition on Home and Personal Care Products and Ingredients

10/07/2022-12/07/2022, Goa, India

For further details contact:

Indian Home & Personal Care Industry AssociationMS. Krutika Sansare & Pankaj Dutia
Cell: +91-9029088219, +91-9819113510
Email:krutika@ihpcia.orgEmail: pankaj@ihpcia.orgwebsite: www.isdcconference.orgwebsite: www.ihpcia.org

Event Details

Plastivision India 2023

09/02/2023-13/02/2023, Mumbai, India

For further details contact:

All India Plastics Manufacturers’ Association (AIPMA)Sanjeevani Kothare
Tel: 022 6777 8846 / 48
Mobile: +91 99303 55494Email: Sanjeevani@plastivision.orgwebsite: www.plastivision.org

Pentane, Hexane and Heptane Prices, Upstream, Downstream, Analytics & Forecasts
Junyuan Petroleum Group – Dongying Liangxin Petrochemical Technology Development Limited Company | Address: No. 117, Guangqing Rd., Guangrao County, Dongying 257345 China.
Junyuan Petroleum Group is China’s largest manufacturer of blowing agents to the foam insulation markets. We have continued to grow with the development of next generation blowing agents, offering a variety of hydrocarbon products for the PIR, PUR and EPS markets, available in ISO tanks and drums. For more information, or for pricing please contact us: +86 178 1030 0898 Email: info@junyuanpetroleumgroup.com Web: www.junyuanpetroleumgroup.com.
China is the world’s largest buyer and drives prices in Asia and the global solvent trade. Our comprehensive news and pricing coverage of China and global solvent market is constantly updated by our raw material purchase, production and sales team of experts. Solvent markets can react to change quickly. It’s crucial for buyers, sellers and producers to stay alert and aware of what’s happening, both in their region and internationally. We help you stay abreast of change as it’s happening. We keep you informed of the current price and market position, so you can make the most of opportunities to trade or secure a deal.

n-Heptane is defined as the zero point of the octane rating scale. It is a lighter component in gasoline, burns more explosively, causing engine pre-ignition ( knocking) in its pure form, as opposed to octane isomers, which burn more slowly and give less knocking.

Chemical formula: C₇H₁₆

Melting point: −90.549 °C (−130.988 °F; 182.601 K)

Molar mass: 100.205 g·mol−1

Solubility in water: 0.0003% (20 °C)

n-Heptane is a colorless volatile liquid, insoluble in water, slightly soluble in methanol, and miscible in ether, chloroform, dichloromethane and other low polar solvents. It is mainly used as a standard for the determination of octane number. It can also be used as a raw material for anesthetics, solvents and organic synthesis, and the preparation of experimental reagents.
CAS No.: 142-82-5
Chinese Name: n-Heptane (正庚烷）
English Name: heptane

Numbering System
CAS No.: 142-82-5
MDL No.: MFCD00009544
EINECS No.: 205-563-8
RTECS No.: mi7700000
BRN No.: 1730763
PubChem No.: 24854818

Physical Property Data
1. Properties: colorless, transparent and volatile liquid. [1]
2. Melting point (℃): – 90.5 [2]
3. Boiling point (℃): 98.5 [3]
4. Relative density (water = 1): 0.68 [4]
5. Relative vapor density (air = 1): 3.45 [5]
6. Saturated vapor pressure (kPa): 6.36 (25 ℃) [6]
7. Combustion heat (kJ / mol): – 4806.6 [7]
8. Critical temperature (℃): 266 [8]
9. Critical pressure (MPA): 2.74 [9]
10. Octanol / water partition coefficient: 4.66 [10]
11. Flash point (℃): – 4 (CC)- 1（OC）[11]
12. Ignition temperature (℃): 215 [12]
13. Upper explosion limit (%): 6.7 [13]
14. Lower explosive limit (%): 1.05 [14]
15. Solubility: insoluble in water, soluble in ethanol and carbon tetrachloride, miscible in ether, chloroform, acetone and benzene. [15]
Viscosity of liquid: 409.0 MPa (s): 40
17. Ignition point (º C): 233
18. Heat of dissolution (kJ / mol): 14.059
19. Aniline point (º C): 70.6
20. Thermal conductivity (25 º C, liquid) / [w / (m · K)]: 122.25 × 10-3
21. Heat of formation (25 º C, liquid) / (kJ · mol): -224.54
22. Specific heat capacity (0 º C, constant pressure) / [kJ / (kg · K)]: 2.233
23. Critical density (g · cm-3): 0.234
24. Critical volume (cm3 · mol-1): 428
25. Critical compression factor: 0.261
26. Eccentricity factor: 0.351
27. Lennard Jones parameter (a): 6.7638
28. Lennard Jones parameter (k): 337.78
29. Solubility parameter (J · cm-3) 0.5:15.208
30. Van der Waals area (cm2 · mol-1): 1.099 × one thousand and ten
31. Van der Waals volume (cm3 · mol-1): 78.490
32. Standard combustion heat (enthalpy) of gas phase (kJ · mol-1): -4153.57
33. Gas phase standard claimed heat (enthalpy) (kJ · mol-1): -187.15
34. Standard entropy of gas phase (J · mol-1 · k-1): 428.1
35. Standard free energy of formation in gas phase (kJ · mol-1): 8.3
36. Gas phase standard hot melt (J · mol-1 · k-1): 165.2
37. Liquid phase standard combustion heat (enthalpy) (kJ · mol-1): -4817.00
38. Standard declared heat (enthalpy) of liquid phase (kJ · mol-1): -224.22
39. Standard entropy of liquid phase (J · mol-1 · k-1): 328.57
40. Standard free energy of formation in liquid phase (kJ · mol-1): 1.23
Standard molten phase (J · mol · 1-224)

Our production laboratory of high purity n-Heptane

n-HEPTANE,99%

Chemical Synonyms:	Normal Heptane	Item:	JPG0043561
Formula:	CH3(CH2)5CH3	Molecular weight:	100.21
Purity:	99%+	CAS:	142-82-5
Application Date:	For use in Liquid Chromatography,Spectrophotometry and Organic Residue Analysis,Packaged under Nitrogen.

Properties
Melting point:	-91℃	Viscosity 20 ℃:
Boiling point:	98℃	Merck Index 13th Edition:	13,4679
Density:	0.684 at 25℃ （g/ml）	Flash point:	-1℃
Dielectric Constant:	1.92 at 20℃	Hazardous Material Identification System（HMIS）:	1*-3-0
Eluting value:		Recommended storage code:	RED
Refractive Index:	1.387 （n20°/D）	International Maritime Organization Hazard Class Code:	3,UN1206,PG II

Specifications

Assay (by GC-FID) (as n-Heptane) ≥99.0% (Heptane isomers and methylcyclohexane） ≥99.5% Color ≤10 APHA GC-ECD Responsive residue(single peak) (as Heptachlorepoxide) ≤1 ppt Fluorescence at emission maximum for Impurities (as Quinine sulfate) ≤1 ppm Residue after evaporation ≤1 ppm Water (by KF coulometry) ≤0.02% Optical absorbance at 197 nm ≤1.00 AU 210 nm ≤0.40 AU 225 nm ≤0.10 AU 254 nm ≤0.01 AU 280 nm ≤0.01 AU

PACKAGING
Product Number:	JPG005611	Unit Size:	MT	Packaging Type:	137kg Steel Drum 16MT ISO Tank

Junyuan Petroleum Group is the largest manufacturer specializing in the production of n-Heptane in China. It has undertaken many large-scale global n-Heptane demand projects and has many successful applications of n-Heptane customers. It provides an important basis for the scientific decision-making of global n-Heptane purchasers, suppliers, importers, chemical enterprises and pharmaceutical enterprises.

*Upstream Raw materials of n-Heptane

Cis-1,3-dimethylcyclopentane

Structure, properties, spectra, suppliers and links for: CIS-1,3-DIMETHYLCYCLOPENTANE, 2532-58-3.

• Boiling Point: 97.2±7.0 °C at 760 mmHg
• Enthalpy of Vaporization: 30.4±0.0 kJ/mol

• Density: 0.8±0.1 g/cm 3
• Vapour Pressure: 48.2±0.1 mmHg 

3-hexylpentane

3-Ethylpentane. Molecular Formula C. 7. H. 16. Average mass 100.202 Da. Monoisotopic mass 100.125198 Da. ChemSpider ID 11551.

• Boiling Point: 92.3±7.0 °C at 760 mmHg
• Enthalpy of Vaporization: 31.1±0.0 kJ/mol

• Density: 0.7±0.1 g/cm 3
• Vapour Pressure: 58.8±0.1

N-alkane

Pure n–alkanes are flame-sealed in glass ampoules or capillaries, or crimp-sealed in glass vials. Some n–alkanes are stored as a drop of solidified wax at the end of a glass stick inside of a crimp-sealed glass vial. 

Methyl cyclohexane

Methylcyclohexane appears as a clear colorless liquid with a petroleum-like odor. Flash point 25°F. Less dense than water and insoluble in water. Vapors heavier than air. Computed by LexiChem 2.6.6 (PubChem release 2019.06.18)

Molecular Formula: C7H14 or C6H11CH3

PubChem CID: 7962

Raffinate oil

In chemical separation terminology, the raffinate (from French raffiner, to refine) is a product which has had a component or components removed. The product having the removed materials is referred to as the extract. For example, in solvent extraction, the raffinate is the liquid stream which remains after solutes from the original liquid are removed through contact with an immiscible liquid. In metallurgy, raffinating refers to a process in which impurities are removed from liquid material.

*Downstream Products of n-Heptane

Downstream

Petroleum Industry

The oil and gas industry is usually divided into three major sectors: upstream, midstream, and downstream. The downstream sector is the refining of petroleum crude oil and the processing and purifying of raw natural gas, as well as the marketing and distribution of products derived from crude oil and natural gas. The downstream sector reaches consumers through products such as gasoline or petrol, kerosene, jet fuel, diesel oil, heating oil, fuel oils, lubricants, waxes, asphalt, natural gas, and liquefied petroleum gas (LPG) as well as naphtha and hundreds of petrochemicals.

4-bromo-1-bromomethyl-2-p-chlorophenyl-5-trifluoromethylpyrrole-3-nitrile

IUPAC Standard InChI: InChI=1S/C10H13Br/c1-7-4-9(3)10(6-11)5-8(7)2/h4-5H,6H2,1-3H3 Copy IUPAC Standard InChIKey: ZHGUKHABIUDZDU-UHFFFAOYSA-N 

2-p-chlorophenyl-1-methyl-5-trifluoromethylpyrrole-3-nitrile

4-Bromo-2-(4-chlorophenyl)-1-methyl-5-(trifluoromethyl)pyrrole-3-carbonitrile | C13H7BrClF3N2 | CID 183558 – structure, chemical names, physical and chemical properties, classification, patents, literature, biological activities, safety/hazards/toxicity information, supplier lists, and more.

• Molecular Formula: C13H7BrClF3N2
• PubChem CID: 183558

8-aminoisoquinoline

Synonyms: Isoquinolin-8-ylamine CAS No.: 23687-27-6 Molecular Formula: C9H8N2 Molecular Weight: 144.18 MDL No.: MFCD00179553 Storage Temperature: Store at 0-8°C

3-isopropyl phenylboric acid

(3-((2-Isopropyl-5-methylphenoxy)methyl)phenyl)boronic acid. CAS Number: 1072951-74-6. Catalog Number: 1P003J80. MDL Number: MFCD22200781

Titanium trichloride / dialkyl aluminum chloride TiCl ^ {3 ^} / air ^ {3 ^} Cl

Titanium(III) chloride-aluminum chloride TiCl3:AlCl3 3:1; CAS Number: 12003-13-3; EC Number: 234-421-8; Synonyms: Aluminum titanium chloride; Linear Formula: (TiCl3)3 · AlCl3;

Sodium 5-nitro-2-pyrimidinol

 2–Pyrimidinol, 5–nitro-(CAS 3264-10-6)In-stock or Backordered impurities,Bulk custom synthesis,Formular C4H3N3O3,MW 141.0849 bulk manufacturing

2,4,6-trichloropyrimidine-5-amine

Name:5-Amino-2,4,6-trichloropyrimidine,CAS:91322-00-8.Properties:Molecular Fomula:C4H2Cl3N3,Molar Mass:198.438,Density:1.74g/cm 3,Boling Point:260.047°C at 760 mmHg,Flashing Point:111.073°C,Vapor Presure:0.013mmHg at 25°C,Refractive Index:1.645,MSDS,Hazard,Safety.

CAS: 91322-00-8

InChI: =1/C4H2Cl3N3/c5-2-1(8)3(6)10-4(7)9-2/h8H2

Name: 5-Amino-2,4,6-trichloropyrimidine

Synonyms: 2,4,6-trichloropyrimidin-5-amine

Tetrahydropyranone

Building Blocks Tetrahydropyranone Tetrahydropyranone Category. Building Blocks Others. CAS NO. 29943-42-8. Structure.

Ziegler catalyst

Ziegler–Natta catalyst
A Ziegler–Natta catalyst, named after Karl Ziegler and Giulio Natta, is a catalyst used in the synthesis of polymers of 1-alkenes. Two broad classes of Ziegler–Natta catalysts are employed, distinguished by their solubility
People also search for: Metallocene · Polyethylene · Polymerization · Radical Polymerization · Tacticity · High-density Polyethylene · Catalysis · Coordination Polymerization · Chain-growth Polymerization · Methylaluminoxane · Polyacetylene · Low-density Polyethylene · Copolymer · Wilkinson’s catalyst · Alkene

Methyl 2,6-dichloropyrimidine-4-formate

Methyl 2,6-dichloropyrimidine-4-carboxylate; CAS Number: 6299-85-0;

Fenpropathrin

Fenpropathrin

Pyrethroid Insecticide

Fenpropathrin, or fenopropathrin, is a widely used pyrethroid insecticide in agriculture and household. Fenpropathrin is an ingestion and contact synthetic pyrethroid. Its mode of action is similar to other natural and synthetic pyrethroids where in they interfere with the kinetics of voltage gated sodium channels causing paralysis and death of the pest. Fenpropathrin was the first of the light-stable synthetic pyrethroids to be synthesized in 1971, but it was not commercialized until 1980. Like other pyrethroids with an α-cyano group, fenpropathrin also belongs to the termed type II pyrethroids. Type II pyrethroids are a more potent toxicant than type I in depolarizing insect nerves. Application rates of fenpropathrin in agriculture according to US environmental protection agency varies by crop but is not to exceed 0.4 lb ai/acre.

2-chloro-5-fluoropyridine

2-Chloro-5-fluoropyridine 0.95; CAS Number: 31301-51-6; Linear Formula: C5H3ClFN;

5-amino-2-chloropyrimidine

5-Amino-2-chloropyridine was used in the synthesis of [2H5]2-amino-l-methyl-6-phenylimidazo [4,5-b]pyridine. It is used in identification and evaluation of molecularly imprinted polymers for the selective removal of potentially genotoxic aminopyridine impurities from pharmaceuticals.

benzenesulfenyl chloride

Benzenesulfonyl chloride is an organosulfur compound with the formula C₆H₅SO₂Cl. It is a colourless viscous oil that dissolves in organic solvents, but reacts with compounds containing reactive N-H and O-H bonds. It is mainly used to prepare sulfonamides and sulfonate esters by reactions with amines and alcohols, respectively. The closely related compound toluenesulfonyl chloride is often preferred analogue because it is a solid at room temperature and easier to handle.
Density: 1.38 g/cm³
Chemical formula: C₆H₅ClO₂S

Tert butyl Dimethylsilyl trifluoromethanesulfonate

Trifluoromethanesulfonate

Triflate, also known by the systematic name trifluoromethanesulfonate, is a functional group with the formula CF₃SO₃−. The triflate group is often represented by −OTf, as opposed to −Tf (triflyl). For example, n-butyl triflate can be written as CH₃CH₂CH₂CH₂OTf.

2-amino-4,6-dichloro-5-formamido pyrimidine

The N- (2-Amino-4,6-Dichloro-5-Pyrimidinyl)Formamide, with the CAS registry number 171887-03-9, is also known as N- (2-Amino-4,6-dichloropyrimidin-5-yl)formamide; 2-Amino-4,6-dichloro-5-formamidopyrimidine.

4-formyl-15-crown-5

15-Crown-5

Crown Ether

15-Crown-5 is a crown ether with the formula₅. It is a cyclic pentamer of ethylene oxide that forms complex with various cations, including sodium and potassium, however, it is complementary to Na⁺ and thus has a higher selectivity for Na⁺ ions.
Density: 1.11 g/cm³

1-Nonanol

1-Nonanol

Straight Chain Fatty Alcohol

1-Nonanol/ˈnoʊnənɒl/ is a straight chain fatty alcohol with nine carbon atoms and the molecular formula CH₈OH. It is a colorless oily liquid with a citrus odor similar to citronella oil. Nonanol occurs naturally in orange oil. The primary use of nonanol is in the manufacture of artificial lemon oil. Various esters of nonanol, such as nonyl acetate, are used in perfumery and flavors.
Density: 0.83 g/cm³
Chemical formula: C9H20O
Average Molar mass: 144.26 g/mol
People also search for: 1-Decanol · 1-Octanol · 1-Heptanol · 1-Hexanol · 1-Pentanol · Octanol · Nonanal · n-Butanol · Dodecanol · Propyl alcohol · Butanol · 2-Nonanol · Methanol · Undecanol · 2-Ethylhexanol

2-p-chlorophenyl-4-bromo-1-methyl-5-trifluoromethylpyrrole-3-nitrile

4-Bromo-2-(4-chlorophenyl)-1-methyl-5-(trifluoromethyl)pyrrole-3-carbonitrile | C13H7BrClF3N2 | CID 183558 – structure

• Molecular Formula: C13H7BrClF3N2
• PubChem CID: 183558

2 – (aminomethyl) cyclopropane-1-carboxylic acid

(+)-cis-2-Aminomethylcyclopropane carboxylic acid

(+)-cis-2-Aminomethylcyclopropane carboxylic acid ((+)-CAMP) is an agonist for the GABAA-rho receptor.
Average Molar mass: 115.13 g/mol
Chemical formula: C5NH9O2
Density: 1.27 g/cm³
People also search for: gabapentin · ciprofloxacin · Creatine · Amino acid · pregabalin · Carnitine · 5-Hydroxytryptophan · gamma-Aminobutyric acid · Citrulline · b-Alanine · Essential amino acid · latanoprost · tranexamic acid · Levodopa · prasugrel

Fenvalerate

Fenvalerate

Synthetic Pyrethroid Insecticide

Fenvalerate is a synthetic pyrethroid insecticide. It is a mixture of four optical isomers which have different insecticidal activities. The 2-S alpha configuration, known as esfenvalerate, is the most insecticidally active isomer. Fenvalerate consists of about 23% of this isomer.
Average Molar mass: 419.90 g/mol
Boiling point: 1,002°F (538.90°C)
Density: 1.17 g/cm³
Chemical formula: C25H22ClNO3

2-chloro-5-nitropyrimidine

2-Chloro-5-nitropyrimidine. 10320-42-0. 2-Chloro-5-nitro-pyrimidine. Pyrimidine, 2–chloro–5-nitro-MFCD04117995

• Molecular Formula: C4H2ClN3O2

• PubChem CID: 82544

1-methyl-1h-imidazole-2-carboxylic acid

This chemical’s molecular formula is C 5 H 6 N 2 O 2 and molecular weight is 126.11. Its systematic name is called 1-methyl-1H-imidazole-2-carboxylic acid. This chemical is white crystalline solid which can be used as a useful synthetic intermediate for solid phase synthesis of polyamides containing imidazole.

Diuretic acid

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Diuretic

Class of Drugs
A diuretic is any substance that promotes diuresis, the increased production of urine. This includes forced diuresis. A diuretic tablet is sometimes colloquially called a water tablet. There are several categories of diuretics. All diuretics increase the excretion of water from the body, through the kidneys. There exist several classes of diuretic, and each works in a distinct way. Alternatively, an antidiuretic, such as vasopressin, is an agent or drug which reduces the excretion of water in urine.
May treat: Heart Failure · Hypertension · Diabetes Insipidus · Nephritis · Nephrotic Syndrome · Glomerulonephritis · Persistent truncus arteriosus · Cardiovascular disease · Myocarditis · Metabolic syndrome · Acute tubular necrosis · Ménière’s disease · Atrial septal defect · Inflammatory heart disease

4,6-dimethylpyrimidine-5-carboxylic acid

Product Name： 4,6-Dimethylpyrimidine-5-carboxylic acid CAS ： 157335-93-8

Tetrabenzyl pyrophosphate

Tetrabenzyl pyrophosphate is a phosphorylating agent used to prepare prodrugs, which increase bioavailability, meaning that the drugs can be administered as injectables rather than tablets. These drugs are used in the treatment of viruses, cancer, and anti-emetics, such as fosaprepitant.

2-hydroxy-4,6-diaminopyrimidine

CAS: 56830-58-1 MDL: MFCD00082893 Synonyms: 2,5-Diamino-6–hydroxy–4(1H)-pyrimidinone Hydrochloride, 2,5-Diaminopyrimidine–4,6-diol Hydrochloride

6,5-trichloro-pyrimidine

Chemical & Physical Properties

Density	1.6±0.1 g/cm3
Boiling Point	212.7±20.0 °C at 760 mmHg
Melting Point	23-25 °C(lit.)
Molecular Formula	C4HCl3N2
Molecular Weight	183.423
Flash Point	102.5±7.4 °C
Exact Mass	181.920532
PSA	25.78000
LogP	1.96
Vapour Pressure	0.2±0.4 mmHg at 25°C
Index of Refraction	1.579
Storage condition	Refrigerator

Taking n-heptane as the model compound of alkanes in light straight run naphtha, the cracking reaction of n-heptane on HZSM-5 catalyst was studied and compared with the cracking reaction of 1-heptene. The effects of hydrothermal treatment and carrier properties on the cracking reaction were investigated The results show that the content of small molecular alkanes such as hydrogen, methane and ethane in n-heptane cracking products is much higher than that in 1-heptane cracking. It is speculated that it is mainly caused by the unique single molecular cracking path of alkanes, and the content of low-carbon olefins such as propylene and butene in liquefied gas (LPG) is low; After hydrothermal treatment, the amount of acid decreased sharply, and the relative content of strong B acid decreased, resulting in significant reduction of catalyst activity, reduction of hydrogen transfer reaction and significant increase of olefin degree in cracking gas At the same time, the molar ratio of C3 / C4 in the product decreased, which reduced the probability of inferring the single molecular path in the cracking reaction The carrier also has a great influence on the cracking reaction behavior of n-heptane. The presence of Lewis acid in the carrier can promote the conversion of n-heptane and increase the proportion of BIMOLECULAR CRACKING path in the initial reaction Generally speaking, compared with olefin molecules, alkanes have lower reaction activity and olefin selectivity, so they are not an ideal raw material for catalytic cracking on molecular sieve catalysts to produce low-carbon olefinsRemoving impurities from the heptane stream by contacting the heptane stream with an acidic catalyst, wherein the contact reduces the concentration of one or more near boiling impurities, one or more olefins, or both. Impurities are isomerized into substances with low octane number or boiling point not close to the boiling point of n-heptane through contact with acidic catalyst, which helps to separate impurities by distillation. Near boiling point impurities may include compounds such as cis-1,2-dimethylcyclopentane and methylcyclohexane, or compounds with boiling points in the range of about 96.5 to about 100.5 degrees Celsius at a standard pressure of 760 Torr, including compounds such as cis-1,2-dimethylcyclopentane and methylcyclohexane. The concentrations of cis-1,2-dimethylcyclopentane and methylcyclohexane can be reduced by at least 25% and 10% by weight, respectively. The olefin concentration measured by bromine index can be reduced by at least about 25% (by weight).

1. After nickel catalyzed hydrogenation, a small amount of normal olefins are saturated and converted into normal alkanes, and the iodine value is reduced to less than 0.1g iodine / 100g. Finally, standard n-Heptane with purity of 99.9% was obtained by distillation. Industrial grade n-Heptane can also be purified by concentrated sulfuric acid washing and methanol azeotropic distillation.
2. Hydrocarbon fraction of petroleum. It can contain n-Heptane, dimethylcyclopentane, 3-ethylpentane, methylcyclohexane and 3-methylcyclohexane.

Light naphtha isomerization oil does not contain sulfur, aromatics, olefins and other substances. It is one of the blending components of clean gasoline with high octane number. Normal C5 and C6 isomerization in light naphtha is easy and has realized industrial production, while long-chain alkane isomerization represented by n-heptane is difficult. Once a breakthrough is made, it will bring great technological progress to the production of high octane number gasoline. Ptwo3 / ZrO2 Catalyst has the advantages of good thermal stability, strong acidity, simple preparation method, reusable and good isomerization performance. It has become a research hotspot of n-heptane isomerization catalyst. In this paper, Pt / WO3 / ZrO2 Catalyst was further modified by Cr and other metals to improve the performance of the catalyst in n-heptane isomerization. The main conclusions are as follows: (1) Pt / WO3 / ZrO2 Catalyst Modified by rare earth metals such as PR, CE, La and Rb and transition metals such as Cr, Co, Zn and Fe was prepared by impregnation method. The modified catalyst was characterized by XRD, NH3-TPD, bet, H2-TPR and SEM, Combined with the fixed bed reactor, the catalytic performance of the catalyst for n-heptane isomerization was analyzed and evaluated. The results show that among the above metal modified catalysts, Cr2O3 Pt / WO3 / ZrO2 Catalyst has large specific surface area and strong acidity, and shows better catalytic activity in n-heptane isomerization. (2) The effects of WO3 content, Cr content, calcination temperature and calcination time on the isomerization of n-heptane over Cr2O3 Pt / WO3 / ZrO2 Catalyst were investigated. The results showed that the isomerization performance of the catalyst was better when the load of WO3 was 18wt%, the content of Cr was 1.0wt%, the calcination temperature was 800 ℃ and the calcination time was 3H. At this time, the yield of isoheptane was about 73% and the conversion of n-heptane was about 82%. (3) The effects of reaction pressure, reaction temperature, molar ratio of hydrogen to hydrocarbon and space velocity reaction conditions on n-heptane isomerization over Cr2O3 Pt / WO3 / ZrO2 Catalyst were investigated. The results show that the catalytic performance is the best when the reaction pressure is 1.0MPa, the reaction temperature is 220 ℃, the molar ratio of hydrogen to hydrocarbon is 9 and the space velocity is 1.05 ~ 1.4h-1. The yield of n-heptane is about 75%. (4) The stability of Cr2O3 Pt / WO3 / ZrO2 Catalyst was investigated, and Cr2O3 Pt / WO3 / ZrO2 Catalyst was applied to the isomerization of light naphtha raw materials. The results showed that Cr2O3 Pt / WO3 / ZrO2 Catalyst did not inactivate after 500 hours of n-heptane isomerization, and the catalyst was stable; Cr2O3 Pt / WO3 / ZrO2 Catalyst has good isomerization performance in actual naphtha raw materials, and the octane number of chromatography is increased by about 28 units.

Container ship CMA CGM RABELAIS while en route from Tanjung Pelepas to Nhava Sheva India, suffered explosion, followed by fire, in western Malacca Strait between Andaman islands and Banda Aceh Sumatra at around 1230 UTC Apr 6. The went NUC, adrift, AIS off since the time of explosion.
Container ship CMA CGM RABELAIS, IMO 9406635, dwt 83317, capacity 6540 TEU, built 2010, flag Malta.

Breaking News! A container ship loaded with Chinese goods exploded and caught fire! Port Klang fire: 22 containers burned and 38 damaged.

On April 6, a container ship exploded and caught fire! Full load of Chinese goods has been attached to Qingdao / Shanghai / Ningbo / Nansha port.
On April 4, the fire in Basang port: 22 containers were burned and 38 were damaged.
Pay attention to cargo damage and shipping delay!

A container ship loaded with Chinese goods exploded and caught fire!

At around 1230 UTC time on April 6, a 6570teu container ship named “CMA CGM Rabelais” exploded in the west of the Strait of Malacca between the Andaman Islands and Banda Aceh, Sumatra, followed by a fire.

At the time of the incident, the container ship “CMA CGM Rabelais” was sailing from Tanjung pelepas to Nhava Sheva, India. According to foreign media reports, the ship’s AIS has been closed and has been drifting since the explosion. The specific cause of the accident is not known.

“CMA CGM Rabelais” was deployed on the AS1 (Asia subcontaint express 1) route of Shanghai / India and Pakistan of APL. At the time of the incident, it was carrying out the “0ff5hw1ma” voyage, involving multiple shipping companies including anl, APL, CMA CGM, CNC, COSCO Shipping, gold star line, OOCL and Zim.

Container ship “CMA CGM Rabelais”: IMO 9406635, deadweight ton 83317, transport capacity 6570teu, built in 2010, flying the flag of Malta.
Starting from Asia, the ship docked at Qingdao port on March 20-22, Shanghai port on March 26, Ningbo port on March 27-28 and Nansha port on March 31, and then arrived at Singapore port and sailed to Nhava Sheva.



Freight forwarders and cargo owners, please pay attention to the notice of the shipping company in time to understand the damage of container goods and the shipping date.

Data chart of “CMA CGM Rabelais” Ship

Ship Information:
CMA CGM RABELAIS (IMO: 9406635) is a Container Ship registered and sailing under the flag of Malta.  Her gross tonnage is 72884 and deadweight is 83317.  CMA CGM RABELAIS was built in 2010.  CMA CGM RABELAIS length overall (LOA) is 299.93 m, beam is 40.06 m. Her container capacity is 6570 TEU.  The ship is operated by DANAOS SHIPPING CO LTD.

Port Klang fire: 22 containers burned and 38 damaged

Breaking! A fire broke out in Bassin West Port. It took firefighters 11 hours to control the fire, which burned dozens of containers and goods.

Su bamalian, general manager of basheng port authority, said on the 5th that the fire broke out at 4:15 p.m. on the 4th. The Fire Department tried to rescue and took full control of the fire at about 3 a.m. on the 5th. The accident did not cause casualties, and the authorities are currently investigating the cause of the fire.

According to the announcement issued by the basheng port authority on the 5th, the fire occurred at block 07j Bay 0506, 0506 Bay, basheng West Port at 4:15 p.m. on the 4th, burning 22 containers in total; In addition, 38 containers were damaged. These containers are used to store “ordinary goods”, namely dry general purpose, and do not involve any dangerous goods. “Except that the fire area was blocked for investigation, the unloading machinery in the port was not affected. Now all loading and unloading transportation work is carried out as usual.”

Snow state fire bureau director Noah Zhan said earlier that the initial fire was eight containers, which were divided into two rows, overlapping and juxtaposing up and down. The West port authorities tried to move the remaining containers away to avoid being affected.

Preliminary investigation showed that the goods in the container on fire included auto parts, audio equipment, cotton fabrics, baby walker, lubricating oil, lines and roof support system.