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If you work in petroleum dye manufacturing, speciality chemical synthesis, or industrial surfactant production, you have almost certainly come across Para Dodecyl Aniline — even if you know it better as PDA, 4-dodecylaniline, or simply “dodecyl aniline.” It is one of those essential building-block chemicals that rarely gets the spotlight, but without it, an entire category of high-performance petroleum dyes and industrial surfactants simply would not exist.

In this guide, we will break down exactly what Para Dodecyl Aniline is, why its unique molecular structure matters, where it is used across industries, and what to look for when sourcing it. Whether you are a dye chemist formulating petroleum colourants, a procurement specialist evaluating intermediate suppliers, or a researcher exploring alkylated aniline derivatives, this article is for you.

What Exactly Is Para Dodecyl Aniline?

Para Dodecyl Aniline (CAS No. 104-42-7) is an organic compound with the molecular formula C₁₈H₃₁N and a molecular weight of 261.45 g/mol. Structurally, it is an aniline molecule — a benzene ring with an amino (-NH₂) group — where a 12-carbon (dodecyl) straight-chain alkyl group has been substituted at the para position (the 4th carbon of the ring).

This dual nature is what makes Para Dodecyl Aniline so industrially valuable. The aniline “head” is reactive — it can undergo diazotisation, coupling reactions, and other classic aromatic amine chemistry. Meanwhile, the long dodecyl “tail” is hydrophobic, imparting excellent oil solubility and surfactant-like properties to any molecule that incorporates it. In chemical terms, PDA is an amphiphilic molecule: one end is polar, the other is non-polar.

This amphiphilic architecture is precisely why Para Dodecyl Aniline is the intermediate of choice for manufacturing modern liquid petroleum solvent dyes. When PDA is used as a coupling component in azo dye synthesis, the resulting dye inherits the long alkyl chain — giving it dramatically higher solubility in fuels, oils, and organic solvents compared to dyes made from unsubstituted aniline.

Key Chemical Properties of Para Dodecyl Aniline (CAS 104-42-7)

Here is a quick-reference summary of PDA’s essential chemical and physical properties:

Property	Details
Chemical Name	4-Dodecylaniline (Para Dodecyl Aniline)
CAS Number	104-42-7
Molecular Formula	C₁₈H₃₁N
Molecular Weight	261.45 g/mol
EC Number	203-201-3
Chemical Class	Alkylated aromatic amine
Appearance	White to off-white waxy solid or low-melting solid
Boiling Point	220–221°C at 15 mmHg
Solubility	Insoluble in water; soluble in ethanol, toluene, xylene, hydrocarbons
Purity (Industrial Grade)	≥97%
Key Functional Groups	Primary amine (-NH₂), dodecyl alkyl chain (-C₁₂H₂₅)
Reactivity	Readily diazotised; undergoes coupling, acylation, and alkylation

The combination of reactive amine functionality with a long hydrophobic chain is what makes Para Dodecyl Aniline uniquely suited for applications where both chemical reactivity and oil solubility are required in the end product.

Primary Applications of Para Dodecyl Aniline

1. Petroleum Solvent Dye Manufacturing (The Core Application)

This is where Para Dodecyl Aniline has its biggest industrial impact. Modern petroleum dyes — the liquid solvent dyes used to colour fuels, lubricants, and oils worldwide — are predominantly azo dyes synthesised by diazotising an aromatic amine and coupling it with a naphthol or phenol. When Para Dodecyl Aniline is used as the amine component, the resulting dye carries the long C12 alkyl chain, which gives it exceptional solubility in hydrocarbon solvents.

This is the fundamental reason why today’s liquid petroleum dyes (such as Solvent Red 164, Solvent Yellow 107, and various custom fuel dye blends) can be supplied as concentrated liquid solutions rather than dry powders. The alkyl chain contributed by PDA eliminates the crystallisation and low-solubility problems that plagued earlier-generation petroleum dyes.

2. Surfactant Synthesis

The amphiphilic structure of Para Dodecyl Aniline makes it a valuable starting material for synthesising speciality surfactants. These include sodium 4-dodecylphenylazosulfonate and other anionic or non-ionic surfactants used in industrial cleaning, emulsification, and oilfield chemistry.

3. Corrosion Inhibitor Intermediates

Long-chain alkylated anilines, including PDA, are used in the formulation of corrosion inhibitors for the oil and gas industry. The amine group adsorbs onto metal surfaces, forming a protective film, while the long alkyl chain provides a hydrophobic barrier against corrosive media.

4. Research and Materials Science

In academic and industrial R&D, Para Dodecyl Aniline is used as a building block for liquid crystals, conductive polymers, functionalised nanotubes, and other advanced materials where a long-chain aromatic amine is required.

Application Overview Table

Application Sector	Specific Use	Role of PDA
Petroleum Dye Manufacturing	Azo dye synthesis for fuel/oil colouring	Coupling component; alkyl chain provides fuel solubility
Surfactant Production	Sodium 4-dodecylphenylazosulfonate, etc.	Amphiphilic precursor for surface-active agents
Corrosion Inhibitors	Metal protection in oilfield and industrial systems	Amine adsorbs to metal; alkyl chain forms hydrophobic barrier
Materials Science / R&D	Liquid crystals, conductive polymers, nanotube functionalisation	Long-chain aromatic amine building block
Speciality Chemical Synthesis	Custom intermediates, agrochemicals, pharma precursors	Versatile alkylated aniline for diverse chemistry

Para Dodecyl Aniline vs. Other Alkylated Anilines

PDA is not the only alkylated aniline used in industry. Here is how it compares with related compounds:

Parameter	Para Dodecyl Aniline (PDA)	Aniline (Unsubstituted)	4-Nonylphenol	Para Phenylenediamine (PPD)
CAS Number	104-42-7	62-53-3	104-40-5	106-50-3
Molecular Formula	C₁₈H₃₁N	C₆H₇N	C₁₅H₂₄O	C₆H₈N₂
Alkyl Chain	C12 (dodecyl)	None	C9 (nonyl)	None
Oil Solubility	Excellent	Poor	Excellent	Poor
Primary Industrial Use	Dye intermediate, surfactants	Polyurethane, dyes, rubber	Surfactants, antioxidants	Hair dye, rubber antioxidant
Role in Dye Chemistry	Coupling component for oil-soluble azo dyes	Diazotisation base for water-soluble dyes	Coupling component	Oxidation dye base

The key differentiator for Para Dodecyl Aniline is its C12 chain length — long enough to ensure excellent hydrocarbon solubility in the end product, yet short enough to maintain good chemical reactivity at the amine group. This balance is what makes PDA the preferred intermediate for petroleum-grade dye synthesis.

Case Study: Improving Fuel Dye Solubility by Switching to a PDA-Based Dye Intermediate

Background: A mid-size liquid petroleum dye manufacturer in South Asia was experiencing persistent solubility issues with their red fuel dye product. Their existing formulation used a shorter-chain alkylated aniline as the coupling intermediate, which resulted in dyes that would occasionally crystallise out of solution during cold-weather storage (≤ 5°C) and leave deposits in customers’ dosing equipment.

The Problem: Three key customers — all fuel depot operators — reported dye precipitation during winter months, leading to clogged injection lines and inconsistent fuel colouring. The manufacturer risked losing these contracts if they could not deliver a cold-stable product.

The Solution: The R&D team reformulated their red azo dye using Para Dodecyl Aniline (CAS 104-42-7) as the coupling intermediate instead of the shorter-chain variant. The longer C12 alkyl chain from PDA produced a dye with significantly higher solubility in the high-flash solvent base, even at low temperatures.

Results:

Metric	Before (Short-Chain Intermediate)	After (PDA-Based Intermediate)
Cold-Weather Stability (5°C)	Crystallisation after 2–3 weeks	Clear and stable for 6+ months
Maximum Solids in Xylene	~35%	>55%
Customer Complaints (Quarterly)	5–7	0
Dye Injection Clogging Incidents	8 per winter season	0
Raw Material Cost Impact	Baseline	~6% increase (offset by fewer returns)
Customer Retention	At risk (3 accounts)	All 3 accounts retained and expanded

Key Takeaway: The slightly higher cost of Para Dodecyl Aniline as a raw material was more than offset by the elimination of product returns, customer complaints, and reputational risk. This case demonstrates why PDA has become the industry-standard intermediate for modern petroleum dye manufacturing.

What to Look for When Sourcing Para Dodecyl Aniline

Not all PDA is equal. Since the product is synthesised via Friedel-Crafts alkylation of aniline with dodecene, the quality of the final product depends heavily on reaction selectivity and purification. Here is what matters:

Purity (≥97%): Lower-purity PDA contains isomeric by-products and unreacted starting materials that can reduce the performance of downstream dyes and intermediates. Insist on batch-specific certificates of analysis.

Para-selectivity: The dodecyl group must be predominantly in the para position for optimal dye synthesis. Ortho-substituted by-products can cause undesirable colour shifts or reduced solubility.

Consistent colour and form: High-quality PDA should be a white to off-white solid. Significant discolouration (brown or dark yellow) may indicate oxidation or impurities.

Reliable supply chain: PDA is used in continuous production processes. Inconsistent supply or variable quality can disrupt manufacturing schedules downstream.

ISO certification: Manufacturers holding ISO 9001:2015, ISO 14001:2015, and ISO 45001:2018 certifications demonstrate commitment to quality, environmental responsibility, and safety.

Anar Chemicals LLP (anarchem.com) is an established manufacturer of dyes, intermediates, and speciality chemicals with over four decades of experience. They are ISO 9001:2015, ISO 14001:2015 & ISO 45001:2018 certified and operate dedicated multipurpose plants for dye intermediates. Explore their Products page or learn more about their Infrastructure to understand their manufacturing capabilities.

Frequently Asked Questions About Para Dodecyl Aniline

Q: What is Para Dodecyl Aniline?

Para Dodecyl Aniline (4-dodecylaniline, CAS 104-42-7) is an organic chemical intermediate consisting of an aniline molecule with a 12-carbon (dodecyl) alkyl chain attached at the para position. It is used as a key building block in the synthesis of petroleum solvent dyes, surfactants, corrosion inhibitors, and speciality chemicals.

Q: What is the CAS number for Para Dodecyl Aniline?

The CAS number for Para Dodecyl Aniline is 104-42-7. It is also known as 4-dodecylaniline, p-dodecylaniline, or PDA.

Q: Why is Para Dodecyl Aniline important for petroleum dye manufacturing?

Para Dodecyl Aniline is used as a coupling component in the synthesis of azo-based petroleum solvent dyes. Its long dodecyl chain dramatically improves the solubility of the resulting dye in fuels, oils, and other hydrocarbon solvents — which is the critical performance requirement for modern liquid petroleum dyes.

Q: What is the molecular formula of Para Dodecyl Aniline?

The molecular formula is C₁₈H₃₁N, with a molecular weight of 261.45 g/mol.

Q: Is Para Dodecyl Aniline soluble in water?

No. Due to its long hydrophobic alkyl chain, Para Dodecyl Aniline is practically insoluble in water. It is, however, soluble in organic solvents such as ethanol, toluene, xylene, and various hydrocarbon solvents.

Q: What purity levels are available for Para Dodecyl Aniline?

Industrial-grade Para Dodecyl Aniline is typically available at 97% purity or higher. For speciality synthesis applications, higher-purity grades may be sourced on request from experienced manufacturers.

Q: Where can I buy high-quality Para Dodecyl Aniline?

Para Dodecyl Aniline is available from speciality chemical manufacturers such as Anar Chemicals LLP (anarchem.com), an ISO 9001:2015, ISO 14001:2015 & ISO 45001:2018 certified company with over 40 years of experience in dyes, intermediates, and speciality chemicals.

Q: How should Para Dodecyl Aniline be handled and stored?

Like most aromatic amines, Para Dodecyl Aniline should be handled with standard chemical safety precautions — protective gloves, eye protection, and adequate ventilation. Store in tightly sealed containers in a cool, dry place away from oxidising agents. Always consult the manufacturer’s SDS for specific guidelines.

When you see a distinctively blue-tinted fuel at a depot, or a lubricant that carries a deep blue colour right out of the drum, there is a very good chance Blue 79 is responsible. Solvent Blue 79 (CAS No. 64553-79-3) is one of the most widely used blue petroleum dyes in the world — an anthraquinone-based colourant that was specifically engineered for exceptional solubility in fuels, oils, and organic solvents.

In this guide, we will cover everything you need to know about Blue 79: its chemistry and origins, why it replaced older blue dyes, where it is used today, and what to look for when sourcing it. If you are involved in fuel blending, lubricant manufacturing, or industrial dye procurement, this article is written with you in mind.

What Exactly Is Blue 79?

Blue 79, officially designated C.I. Solvent Blue 79, is a synthetic anthraquinone dye with the CAS number 64553-79-3. Its core chemical description is 9,10-anthracenedione, 1,4-diamino-, with N, N-mixed 2-ethylhexyl, methyl, and pentyl derivatives.

Here is the key backstory: Blue 79 was originally developed by BASF as a high-solubility form of Solvent Blue 35 (also known as Oil Blue 35 or 1,4-bis(butylamino)anthraquinone). The older Solvent Blue 35 works well as a blue colourant, but in powder form it dissolves only up to about 2% in xylene — far too low for efficient industrial use. By adding longer, branched alkyl side chains to the anthraquinone molecule, BASF created Blue 79, which can form stable liquid solutions at concentrations exceeding 60% solids in xylene, remaining stable even down to -20°C.

This dramatic improvement in solubility was a game-changer. It meant refineries could work with a ready-to-use liquid dye instead of handling hazardous powders — safer, faster, and far more consistent in application.

Key Chemical Properties of Blue 79 (CAS 64553-79-3)

The table below provides a quick-reference overview of the essential properties of Blue 79:

Property	Details
C.I. Name	Solvent Blue 79
CAS Number	64553-79-3
Chemical Class	Anthraquinone (1,4-diaminoanthraquinone derivative)
Base Chromophore	Same as Solvent Blue 35
Hue	Reddish Blue
Solubility	Oil-soluble; >60% in xylene; fully miscible in fuels
Physical Form	Liquid (in solvent)
Common Solvents	High-flash (HF) solvents, Xylene (XY)
Recommended Dosage	10–20 ppm in petroleum products
Shelf Life	~2 years (stored at 5–40°C, sealed containers)
Key Advantage	Dramatically higher solubility vs. Solvent Blue 35 powder
Commercial Names	Sudan Blue 673 (BASF), Sudan Blue B, Automate Blue ER, Dyeguard Blue 79

These properties make Blue 79 the default choice for any petroleum or industrial application requiring a reliable, high-performance blue dye in liquid form.

Primary Applications of Blue 79

1. Fuel and Petroleum Colour-Coding

The dominant application for Blue 79 is colouring petroleum fuels. Refineries worldwide use it to colour-code specific fuel grades — distinguishing different octane levels of gasoline, various diesel sulphur grades, aviation fuels, kerosene, and gas oil. In some jurisdictions, blue-dyed diesel is specifically designated for governmental and institutional vehicles, making it easy to detect fuel theft or misuse.

Blue 79 is also a key ingredient in green fuel dye formulations. Because green is produced by combining a blue dye with a yellow dye (typically Solvent Yellow 107), Blue 79 is used alongside yellow dyes to achieve the precise green shade required by certain national fuel-marking regulations.

2. Lubricants, Hydraulic Fluids, and Industrial Oils

Transmission fluids, gear oils, hydraulic oils, and cutting fluids are often coloured blue for brand differentiation and product identification. Blue 79 provides a clean, vivid blue that remains stable over long storage periods and does not degrade under the thermal conditions typical of working machinery.

3. Wax, Candle, and Speciality Product Colouring

Blue 79 dissolves cleanly in paraffin and other wax systems, making it a reliable option for candle manufacturers who need a deep, consistent blue without sediment or wick-clogging issues.

4. Printing Inks and Coatings

In oil-based ink systems, Blue 79 delivers strong tinting strength and rapid dispersion. Its anthraquinone structure also provides inherently better lightfastness compared to azo-based dyes, which is an advantage for certain ink and coating applications exposed to sunlight.

Application Overview Table

Application Sector	Specific Use	Why Blue 79 Is Preferred
Fuel & Petroleum	Gasoline, diesel, kerosene, aviation fuel	Exceptional solubility, consistent hue, liquid-to-liquid handling
Green Fuel Dyes	Mixed with Solvent Yellow 107 for green shades	Precise colour control, stable blend
Lubricants & Fluids	Transmission fluid, hydraulic oil, gear oil	Thermal stability, no residue, vivid colour
Wax & Candles	Paraffin, soy wax, gel wax colouring	Clean dissolution, no wick clogging
Printing Inks	Oil-based ink formulations	Strong tinting, good lightfastness

Blue 79 vs. Other Common Blue Solvent Dyes

How does Blue 79 compare with other blue dyes used in the petroleum and industrial sectors? Here is a side-by-side look:

Parameter	Blue 79	Solvent Blue 35	Solvent Blue 98	Solvent Blue 97
CAS Number	64553-79-3	17354-14-2	74499-36-8	32724-62-2
Chemical Class	Anthraquinone (alkylated)	Anthraquinone (base)	Anthraquinone	Anthraquinone
Physical Form	Liquid	Powder	Liquid	Powder
Solubility in Xylene	>60%	~2%	High	Moderate
Primary Use	Fuel & oil colouring	Fuel, wax, inks, stains	Fuel & oil colouring	Plastics (PS, PET, PC, ABS)
Hue	Reddish blue	Blue	Blue	Greenish blue
Lightfastness	Good	Good	Good	Very good (7–8)
Handling Safety	Liquid — lower risk	Powder — dust hazard	Liquid — lower risk	Powder — dust hazard

The core advantage of Blue 79 over the original Solvent Blue 35 comes down to practicality: the liquid form eliminates powder-handling hazards, ensures instant dispersion, and allows for far more accurate dosing in automated injection systems.

Case Study: Improving Fuel Depot Safety and Efficiency with Blue 79

Background: A national oil marketing company operating a network of fuel storage depots across the Middle East was experiencing recurring issues with their blue fuel dye programme. Their existing setup relied on Solvent Blue 35 in powder form, which required manual weighing and pre-dissolution in small batches of xylene before injection into fuel storage tanks. The process was slow, generated significant dye dust exposure for workers, and produced inconsistent colour from batch to batch.

The Problem: Depot workers were raising health and safety concerns about repeated exposure to powdered anthraquinone dye dust. Quality audits revealed that colour intensity varied by up to 35% between tanks that had been dyed using the powder process, and three batches in a single quarter had been rejected for insufficient blue tinting.

The Solution: The company transitioned to a pre-formulated Solvent Blue 79 (CAS 64553-79-3) liquid concentrate supplied in high-flash solvent base. The liquid was delivered in sealed drums, eliminating all powder handling. It was injected directly into the fuel flow using the existing proportional dosing systems at each depot, calibrated to deliver 15 ppm of Blue 79.

Results:

Metric	Before (Blue 35 Powder)	After (Blue 79 Liquid)
Colour Consistency	±35% variation	±4% variation
Batch Rejection Rate	~8% per quarter	0% (12 months post-switch)
Worker Dust Exposure Incidents	6 per year	0
Dye Dissolution Time	45–60 min per batch	Instant (pre-dissolved)
Annual Dye Handling Cost	Baseline	~22% reduction
HSE Audit Findings (Dye-Related)	3 in 12 months	0 in 12 months

Key Takeaway: The switch from powdered Solvent Blue 35 to liquid Blue 79 did not just improve colour consistency — it fundamentally improved workplace safety and operational efficiency. This is exactly the kind of gain that the shift from powder to liquid petroleum dyes was designed to achieve, and it is why Blue 79 has become the industry standard for blue fuel colouring.

What to Look for When Sourcing Blue 79

Because Blue 79 is a mixture of alkylated anthraquinone derivatives (not a single pure compound), product quality and performance can vary between manufacturers. Here are the criteria that matter most:

Zero insolubles: The liquid dye should be completely free of undissolved particles. Even trace insolubles can accumulate in fuel injection lines, dosing pumps, and storage tank filters.

Full miscibility: Blue 79 must dissolve instantly and completely in the target fuel or oil, producing a clear, homogeneous blue with no haziness.

Colour strength consistency: Batch-to-batch colour strength should be verified spectrophotometrically. A reliable manufacturer will provide a certificate of analysis confirming dye content and colour strength for every production batch.

Low-temperature stability: The liquid formulation should remain clear and stable at temperatures down to at least -20°C, without crystallisation or phase separation.

ISO certification: Look for manufacturers with ISO 9001:2015, ISO 14001:2015, and ISO 45001:2018 certifications as evidence of quality, environmental, and safety management.

Anar Chemicals LLP (anarchem.com) manufactures Blue 79 in both high-flash and xylene solvent bases, backed by over four decades of experience in dyes and speciality chemicals. They are an ISO 9001:2015, ISO 14001:2015 & ISO 45001:2018 certified facility, supplying petroleum dye solutions to refineries and fuel companies globally. You can explore their complete Liquid Petroleum or Fuel Dyes range on their website.

Frequently Asked Questions About Blue 79

Q: What is Blue 79 used for?

Blue 79 (Solvent Blue 79, CAS 64553-79-3) is primarily used for colouring petroleum fuels, lubricants, and industrial oils to enable visual identification and grade differentiation. It is also used in wax, candle, and ink formulations that require a stable blue hue in non-aqueous systems.

Q: What is the CAS number for Blue 79?

Solvent Blue 79 is listed under CAS number 64553-79-3. This is the standard CAS registration for the alkylated 1,4-diaminoanthraquinone derivative used in petroleum dye formulations.

Q: How is Blue 79 different from Solvent Blue 35?

Blue 79 is the high-solubility, alkylated form of Solvent Blue 35. Both share the same anthraquinone chromophore and produce similar blue hues, but Blue 79 has longer alkyl side chains that dramatically improve its solubility in fuels and organic solvents. Solvent Blue 35 in powder form dissolves only up to about 2% in xylene, while Blue 79 can form stable solutions at concentrations above 60%.

Q: What is the typical dosage for Blue 79 in fuel?

Blue 79 is typically used at 10 to 20 ppm in petroleum products, though the exact dosage depends on the target shade intensity and the specific fuel or oil being coloured.

Q: Does Blue 79 affect fuel performance?

No. Solvent Blue 79 is chemically inert in hydrocarbon systems at the concentrations used. It does not alter combustion characteristics, octane or cetane ratings, or engine performance.

Q: Why do refineries use blue fuel dyes?

Blue fuel dyes serve multiple purposes: differentiating fuel grades during storage and transport, identifying governmental or institutional-use fuel to prevent theft, and meeting country-specific regulatory requirements for fuel colour-coding.

Q: Where can I buy high-quality Blue 79?

Blue 79 is available from speciality petroleum dye manufacturers such as Anar Chemicals LLP (anarchem.com), an ISO 9001:2015, ISO 14001:2015 & ISO 45001:2018 certified company with over 40 years of experience. They produce Blue 79 in both high-flash and xylene solvent bases.

Q: How should Blue 79 be stored?

Store in tightly sealed containers, away from direct sunlight, at temperatures between 5°C and 40°C. Under proper conditions, the shelf life is approximately 2 years from the date of manufacture.

If you have ever wondered what gives certain petroleum products their distinctive yellow tint — or how refineries tell one fuel grade from another at a glance — there is a good chance Yellow 107 is part of the answer. Solvent Yellow 107 (CAS No. 67990-27-6) is a workhorse dye in the global petroleum industry, quietly doing its job in fuel tanks, lubricant drums, and wax processing lines around the world.

In this guide, we will walk through everything you need to know about Yellow 107 — from its chemical makeup and performance characteristics to its real-world applications and how it compares with other yellow solvent dyes. Whether you are a fuel blender, a procurement specialist, or someone researching dye options for an industrial project, this article has you covered.

What Exactly Is Yellow 107?

Yellow 107, officially designated C.I. Solvent Yellow 107 (Colour Index No. 21140), is a synthetic double-azo dye with the CAS number 67990-27-6. Its molecular formula is C₄₄H₅₈N₄O₂, and it has a molecular weight of 674.96 g/mol. The dye is manufactured by double diazotisation of 3,3′-dimethylbenzidine, followed by coupling with 4-nonylphenol.

In appearance, Yellow 107 produces a warm, reddish-yellow hue and is fully oil-soluble — meaning it dissolves in hydrocarbon-based solvents, petroleum products, and non-polar media without any cloudiness or residue. It is commercially available in liquid form, typically formulated in high-flash solvents, xylene or toluene solvent systems.

What makes Yellow 107 particularly useful is its combination of strong tinting strength, excellent solubility across a range of petroleum products, and good thermal stability. It does not affect the functional properties of the fuels or oils it colours, which is exactly what the industry demands.

Key Chemical Properties of Yellow 107 (CAS 67990-27-6)

Here is a quick-reference summary of the essential chemical and physical properties of Yellow 107:

Property	Details
C.I. Name	Solvent Yellow 107
C.I. Number	21140
CAS Number	67990-27-6
Chemical Class	Diazo (Double Azo)
Molecular Formula	C₄₄H₅₈N₄O₂
Molecular Weight	674.96 g/mol
Hue	Reddish Yellow
Solubility	Oil-soluble; fully miscible in petroleum products
Physical Form	Liquid (in solvent)
Common Solvents	High-flash (HF), Xylene (XY), Toluene
Recommended Dosage	10–20 ppm
Shelf Life	2 years (stored at 5–40°C in closed containers)
Synthesis	3,3′-Dimethylbenzidine diazotisation + 4-nonylphenol coupling

These characteristics make Yellow 107 a reliable choice for any application that needs a stable, vivid yellow colourant in a non-aqueous, hydrocarbon-based system.

Primary Applications of Yellow 107

1. Fuel and Petroleum Product Colour-Coding

The single biggest application for Yellow 107 is in the petroleum industry. Refineries and fuel distributors use it to colour-code different grades and types of fuel — distinguishing leaded from unleaded gasoline, high-octane from low-octane fuel, or different sulphur-level diesel grades. This colour differentiation is not just cosmetic; it is a critical safety and compliance measure that prevents dangerous mix-ups during storage, transportation, and dispensing.

Different countries mandate specific dye colours and concentrations for various fuel types. Yellow 107 is widely used across Asia, Africa, and the Middle East for these fuel identification programmes, and it is one of the key yellow dyes approved for petroleum colouring in India and several other markets.

2. Lubricants, Greases, and Industrial Oils

Manufacturers of transmission fluids, hydraulic oils, gear oils, and industrial lubricants use Yellow 107 to impart a consistent, recognisable colour to their products. This helps end-users identify the product type at a glance and also serves as a brand differentiator in a competitive market.

3. Wax, Candle, and Speciality Product Colouring

Yellow 107 dissolves cleanly in paraffin and other wax bases, making it a popular choice for candle and wax product manufacturers who need a bright, stable yellow. Its high solubility means no sediment, no clogging of wicks, and no uneven colour distribution.

4. Printing Inks and Coatings

In oil-based printing ink formulations, Yellow 107 provides strong tinting strength and fast dispersion, allowing for uniform colour output even at low concentrations.

Application Overview Table

Application Sector	Specific Use	Why Yellow 107 Is Preferred
Fuel & Petroleum	Gasoline, diesel, kerosene, gas oil	Full miscibility, regulatory approval, consistent hue
Lubricants & Fluids	Transmission fluid, hydraulic oil, gear oil	No residue, stable colour, brand differentiation
Wax & Candles	Paraffin, soy, and gel wax colouring	Clean dissolution, bright finish, no wick clogging
Printing Inks	Oil-based ink formulations	Strong tinting strength, fast dispersion
Industrial Oils	Cutting oils, mineral oils, heat transfer oils	Thermal stability, inert at working temperatures

Yellow 107 vs. Other Common Yellow Solvent Dyes

There are several yellow solvent dyes available on the market. How does Yellow 107 stack up? Here is a side-by-side comparison with three commonly encountered alternatives:

Parameter	Yellow 107	Yellow 124	Yellow 14	Yellow 56
CAS Number	67990-27-6	34432-92-3	842-07-9	2481-94-9
Chemical Class	Double Azo	Azo	Mono Azo	Azo
Primary Use	Fuel/oil colour-coding	EU Euromarker (fiscal)	Wax, shoe polish, oils	Heating oil, fuel marking
Hue	Reddish yellow	Yellow (near-colourless at low ppm)	Orange-yellow	Yellow
Solubility in Fuel	Excellent	Good	Moderate	Good
Tinting Strength	High	Low (marker, not visual dye)	Moderate	Moderate
Dosage (Fuel)	10–20 ppm	6–9 mg/L (EU mandated)	Varies	Varies
Regulatory Role	Visual colour-coding	Fiscal marker (EU)	General industrial	General fuel dye

The key takeaway: Yellow 107 is designed for strong visual colouring of petroleum products, whereas Yellow 124 serves as a near-invisible fiscal marker. They play entirely different roles and are often used alongside each other in fuel marking programmes.

Case Study: Standardising Fuel Colour-Coding for an Indian Petroleum Distributor

Background: A mid-size petroleum distributor operating across western India was facing recurring issues with fuel identification at their depot network. Different terminals were using dyes sourced from multiple local suppliers, leading to noticeable colour inconsistencies between batches of the same fuel grade. During a regulatory inspection, auditors flagged that the yellow tinting in their branded kerosene varied significantly across three depots — some batches appeared pale straw-coloured, while others were a deep amber.

The Problem: The inconsistency created confusion among depot workers and raised concerns about possible adulteration. The distributor needed a single, reliable yellow dye solution that would deliver uniform colour across all locations without requiring changes to their existing blending infrastructure.

The Solution: The distributor consolidated their yellow dye supply with a single ISO-certified manufacturer producing Yellow 107 (CAS 67990-27-6) in a high-flash solvent base. The new formulation was pre-calibrated for a standard dosage of 15 ppm, delivered in ready-to-use liquid form that could be injected directly into fuel lines without pre-dilution.

Results:

Metric	Before (Multiple Suppliers)	After (Single Yellow 107 Source)
Colour Consistency (visual)	Significant variation across depots	Uniform across all 7 depots
Batch Rejection Rate	~12%	<1%
Supplier Count	4 different dye vendors	1 ISO-certified manufacturer
Dosage Standardisation	Varied (8–25 ppm)	Fixed at 15 ppm
Annual Dye Cost	Baseline	~14% reduction (volume pricing)
Regulatory Audit Flags	2 in 12 months	0 in 12 months

Key Takeaway: Consolidating to a single, quality-assured Yellow 107 supply eliminated the batch-to-batch variation that had been causing compliance headaches. The experience underscores a principle that holds true across the petroleum dye industry: consistency of supply matters just as much as the chemical itself.

What to Look for When Sourcing Yellow 107

Because Yellow 107 is a commercial dye and not a single pure compound (the alkylation and coupling process produces a mixture of related structures), quality can vary significantly between manufacturers. Here are the factors that matter most:

Impurity-free formulation: The product should be completely free of insoluble particles. Even trace amounts of insoluble matter can accumulate in fuel injection systems and storage tanks over time.

Full miscibility: Yellow 107 must dissolve completely in the target fuel or oil product, producing a clear, homogeneous colour with no haziness or phase separation.

Batch-to-batch consistency: Look for manufacturers who perform spectrophotometric quality checks on every production batch to ensure consistent colour strength and hue.

Flexible solvent bases: Depending on your application, you may need Yellow 107 in a high-flash solvent, xylene, or toluene base. A capable manufacturer will offer all three options.

ISO certification: Manufacturers holding ISO 9001:2015, ISO 14001:2015, and ISO 45001:2018 certifications are demonstrating commitment to quality, environmental compliance, and safety.

Anar Chemicals LLP (anarchem.com) is an established manufacturer that ticks all of these boxes — ISO 9001:2015, ISO 14001:2015 & ISO 45001:2018 certified, with over four decades of experience in dyes and speciality chemicals. They produce Yellow 107 in high-flash, xylene, and toluene solvent bases and supply to petroleum companies across the globe. Explore their full Liquid Petroleum or Fuel Dyes product range for more details.

Frequently Asked Questions About Yellow 107

Q: What is Yellow 107 used for?

Yellow 107 (Solvent Yellow 107, CAS 67990-27-6) is primarily used for colouring and differentiating petroleum products such as fuels, lubricants, and industrial oils. It is also used in wax colouring, candle manufacturing, printing inks, and certain plastic formulations.

Q: What is the CAS number for Yellow 107?

The CAS number for Solvent Yellow 107 is 67990-27-6. Its Colour Index number is C.I. 21140.

Q: Is Yellow 107 the same as Solvent Yellow 124?

No. Yellow 107 (CAS 67990-27-6) and Solvent Yellow 124 (CAS 34432-92-3) are chemically different dyes with distinct structures and applications. Solvent Yellow 124 was used as the EU Euromarker for tax-exempt fuel identification, while Yellow 107 is primarily used for visual fuel colour-coding and industrial colouring. They serve complementary but separate roles.

Q: What is the typical dosage for Yellow 107 in fuel?

Yellow 107 is generally used at a dosage of 10 to 20 parts per million (ppm) in petroleum products, depending on the desired shade intensity and the specific product being coloured.

Q: Does Yellow 107 affect fuel performance or engine operation?

No. Solvent Yellow 107 is chemically inert in hydrocarbon systems at the concentrations used for colouring. It does not alter combustion characteristics, octane or cetane ratings, or the mechanical performance of engines.

Q: How should Yellow 107 be stored?

Yellow 107 should be stored in tightly closed containers, away from direct sunlight, at temperatures between 5°C and 40°C. Under these conditions, the product has a shelf life of approximately 2 years from the date of manufacture.

Q: Where can I buy high-quality Yellow 107?

Yellow 107 is available from speciality chemical manufacturers such as Anar Chemicals LLP (anarchem.com), an ISO-certified company with over four decades of experience in petroleum dyes and speciality chemicals. They produce Yellow 107 in high-flash, xylene, and toluene solvent bases.

Q: Is Yellow 107 safe to handle?

Like most industrial solvent dyes, Yellow 107 should be handled with standard precautions — protective gloves, eye protection, and adequate ventilation. Always consult the manufacturer’s Safety Data Sheet (SDS/MSDS) for product-specific safety information.