Technical articles

Starting from Dimethicone: An Analysis of the Structure, Properties, and Formulation Selection of Personal Care Silicones

1 Core Value of Silicone Fluids: Regulating Surface and Interfacial Behavior

 

In personal care formulations, silicone fluids are commonly used in skin care, hair care, sun care, color cosmetics, and cleansing products. They are mainly used to improve application properties such as spreading, lubrication, smoothness, water resistance, gloss, and conditioning. These effects arise from the ability of silicone fluids to regulate surface and interfacial behavior. The surfaces and interfaces discussed here mainly include the skin surface, hair surface, powder surface, oil-water interface, and air-liquid interface. Structure determines surface/interfacial behavior; surface/interfacial behavior determines product performance; and the desired performance determines product selection.

 

Dimethyl silicone oil is commonly known in English as Dimethicone. Chemically, it is usually polydimethylsiloxane, abbreviated as PDMS. It is a basic, typical, and widely used type of silicone fluid, and also serves as a prototype for understanding water-soluble or water-dispersible silicones, amino silicones, high-viscosity silicones, and silicone emulsions. The functions of conventional dimethicone can be summarized in the following four aspects:

 

Fundamental Function

Application Performance

Lower surface tension and higher spreading tendency

Helps reduce application resistance, making products easier to spread and distribute

Lower surface friction

Makes skin feel smoother and hair easier to comb

Forms a thin layer with low surface energy

Improves water resistance, anti-frizz performance, and a non-sticky feel

Adjusts performance through viscosity and structural modification

Covers effects ranging from light spreading to long-lasting conditioning, and from oil-soluble to water-dispersible behavior

 

2 Dimethicone: A Basic Prototype of Personal Care Silicones

 

2.1 Dimethicone is a typical basic silicone fluid

Common silicone-based raw materials used in personal care include dimethicone, amino-terminated polydimethylsiloxane, polyether-modified dimethicone, hydroxyl-terminated polydimethylsiloxane, cyclic methyl siloxanes, and silicone emulsions. They differ in name, appearance, and application direction, but they are all closely related to siloxane structures. Among them, dimethicone is an important basic prototype for understanding linear silicones, modified silicones, and silicone emulsions.

 

Dimethicone is usually a colorless, transparent liquid with a wide viscosity range. It can range from a low-viscosity, free-flowing liquid to a high-viscosity silicone fluid with lower flowability. Differences in viscosity lead to differences in spreadability, lubricity, film feel, and surface retention.

 

Low-viscosity dimethicone usually offers a light feel, easy spreading, and low heaviness, making it suitable for formulations that require improved extensibility and a fresh sensory feel. Medium- to high-viscosity dimethicone usually provides a more noticeable lubricating feel, silky touch, and surface retention, making it suitable for products that need enhanced smoothness, conditioning, and long-lasting sensory effects.

 

2.2 Dimethicone is different from ordinary oils

Dimethicone is different from vegetable oils, mineral oils, and ester oils. Ordinary oils are mostly based on carbon-chain structures, while dimethicone is based on a siloxane chain. Its typical structure can be described as:

Flexible Si–O–Si siloxane backbone + methyl groups arranged on the outside

 

3 Structure of Dimethicone

 

3.1 The Si–O–Si backbone provides flexibility and spreadability

The main chain of dimethicone is formed by repeating Si–O–Si bonds. The siloxane chain has good flexibility, and its molecular segments can move easily. When dimethicone comes into contact with the surface of skin, hair, or powders, it can more easily spread into a thin layer.

 

This spreading ability is an important reason why dimethicone improves the feel of application. In skin care lotions, primers, sunscreens, and color cosmetics, dimethicone is commonly used to reduce application resistance, make products easier to spread, and help the formulation distribute more evenly on the skin or powder surface.

 

3.2 Methyl side groups provide low surface energy and hydrophobicity

The methyl groups on the outside of dimethicone molecules make the surface relatively non-polar. Water has low wettability on the siloxane thin layer formed by dimethicone. When dimethicone is distributed on the surface of skin, hair, or a formulation film, it can reduce the extent to which these surfaces are wetted by water, thereby helping reduce frizz caused by humidity and improving the hydrophobic performance of the formulation film.

 

Structural Source

Effect

Personal Care Performance

Exposed methyl side groups

Reduces surface energy

Provides a smooth touch and reduces roughness or drag

Methyl side groups form a non-polar surface

Reduces water wetting on the surface

Helps form a hydrophobic surface layer, reducing humidity-induced frizz and water-related disruption of the film

Relatively weak intermolecular interactions

Reduces friction

Improves smoothness and combability, and reduces pulling

 

The “smooth feel” of dimethicone results from the combined effect of low surface energy and a low-friction thin layer.

 

3.3 Molecular weight and viscosity influence lightness, film feel, and durability

Even when all are dimethicone products, their sensory profiles may differ significantly. The main reasons are differences in molecular weight and viscosity; some extremely low-viscosity linear siloxanes or cyclic siloxanes may also be volatile. At the same time, sensory performance is also affected by dosage, formulation system, and combination with other ingredients.

 

Viscosity Feature

Application Performance

Suitable Application Direction

Low viscosity

Good flowability, faster spreading, relatively light feel

Skin care, primers, sunscreens, sensory modification in color cosmetics

Medium viscosity

Balanced lubricity, silky feel, and surface retention

Creams, hair conditioners, body care

High viscosity

Stronger surface retention, more noticeable silky feel, and longer-lasting conditioning

Hair care, hair masks, long-lasting smoothing products

 

Low-viscosity dimethicone usually helps improve spreadability and reduce heaviness, making it suitable for formulations that require a light, smooth, and easy-to-apply feel. Medium- to high-viscosity dimethicone or high-molecular-weight polysiloxanes usually have stronger surface retention and can be used in products that require enhanced lubricity, smoothness, gloss, and long-lasting conditioning.

 

The application value of dimethicone should be evaluated comprehensively based on molecular weight, viscosity, volatility, dosage, dispersion state, formulation system, and target performance.

 

3.4 Structural modification brings different functions

The basic structure of dimethicone can be further modified. Common modification approaches include introducing polyether segments, amino groups, hydroxyl end groups, or preparing it as an emulsion dispersion. After modification, the hydrophilicity, dispersibility, deposition behavior, and film-forming properties of silicone fluids can all change.

 

Modification Direction

Structural Change

Performance Change

Polyether modification

Introduction of PEG or PPG hydrophilic segments

Improves water-phase compatibility, wettability, and emulsifying properties

Amino modification

Introduction of amino functional groups

Enhances suitability for hair surface conditioning

Hydroxyl termination or increased molecular weight

Changes the end-group structure, or increases molecular weight/viscosity

Enhances surface retention, film feel, gloss, and long-lasting smoothness; hydroxyl termination can also provide certain end-group reactivity

Emulsified dispersion

Disperses oil-based silicone fluid in water

Facilitates incorporation into aqueous phases or cleansing products

 

4 From Structure to Function: How Spreading, Lubrication, Hydrophobicity, and Conditioning Are Produced

 

4.1 Low surface tension improves spreading

During product application, whether a product can spread quickly depends on its wetting and spreading ability on the surface of skin, hair, or powders. Dimethicone usually has low surface tension and a high tendency to spread, which helps reduce application resistance and helps the formulation form a more uniform distribution on the surface of skin, hair, or powders.

 

In skin care and sun care products, this effect is reflected in smoother application, better extensibility, reduced drag during spreading, improved powder dispersion, and a more even makeup finish.

 

4.2 A low-friction thin layer brings smoothness and easier combing

Rough skin feel, tangled hair, and high combing resistance are all essentially related to surface friction. Dimethicone can form a low-friction thin layer on the surface, thereby reducing resistance between surfaces.

 

Silicone fluids mainly improve the friction, alignment, and sensory feel of the hair surface. They are not equivalent to truly repairing the internal structure of hair. When damaged hair has lifted cuticles and increased porosity, silicone fluids can improve combability and softness through surface coverage and lubrication. This belongs to surface conditioning.

 

4.3 A low-surface-energy thin layer improves water resistance and anti-frizz performance

The methyl groups on the outside of dimethicone make it hydrophobic. After it forms a continuous or partially continuous low-surface-energy thin layer on the skin or hair surface, it can reduce water wetting on that surface. This effect appears differently in different product types:

 

Product Type

Functional Performance

Sunscreens and color cosmetics

Improves spreading, film uniformity, and film hydrophobicity, and can help enhance water resistance

Hair care products

Reduces the influence of humidity on the hair surface and helps reduce frizz

Skin care products

Reduces stickiness and forms a smooth protective surface feel

Body care products

Improves after-feel and surface lubricity

 

Hydrophobicity does not mean complete occlusion. Dimethicone forms a flexible, low-friction, hydrophobic surface layer. The strength of this layer depends on silicone viscosity, dosage, formulation structure, and whether it is combined with other film formers.

 

5 Why Water-Soluble or Water-Dispersible Silicones Exist

 

5.1 Conventional dimethicone is usually insoluble in water

Conventional dimethicone has non-polar methyl side groups as its main outer surface and is generally hydrophobic, so it is usually insoluble in water. It can be dispersed in water through emulsifiers and emulsification processes, but this state is emulsification or dispersion, not molecular-level water solubility.

 

In transparent aqueous products, shampoos, shower gels, sprays, gels, and similar systems, conventional dimethicone cannot simply be added directly. Direct addition may cause turbidity, phase separation, floating oil, or reduced stability.

 

5.2 Polyether modification is a common route to water-phase compatibility or water dispersibility

A common way to obtain water-phase compatibility, water dispersibility, or a certain degree of water solubility is to introduce hydrophilic polyether segments into the siloxane structure. The polyether segment may be a polyethylene glycol segment, or a combined polyethylene glycol/polypropylene glycol segment. The siloxane segment mainly provides smoothness, lubrication, low surface tension, and a silicone sensory feel; the polyether segment mainly improves hydrophilicity, water-phase compatibility, wettability, and emulsifying properties.

 

Molecular Segment

Main Function

Siloxane segment

Provides smoothness, lubrication, low surface tension, and a silicone sensory feel

Polyether segment

Improves hydrophilicity, water-phase compatibility, wettability, and emulsifying properties

Polyethylene glycol segment

Improves hydrophilicity and water-phase compatibility

Polyethylene glycol/polypropylene glycol segment

Adjusts hydrophilic-lipophilic balance, compatibility, wettability, and emulsifying performance

 

This type of structure allows silicone fluids to go beyond the behavior of conventional oil-based silicones and gives them the opportunity to function in aqueous phases, surfactant systems, or certain transparent/semi-transparent systems. The specific transparency and stability still depend on the polyether ratio, siloxane chain length, dosage, and formulation system.

 

5.3 Differences between water-soluble or water-dispersible silicones and oil-based silicones

There is no absolute superiority or inferiority between water-soluble or water-dispersible silicones and oil-based silicones. Their differences mainly come from molecular structure and the application system. Oil-based dimethicone is mainly based on a hydrophobic siloxane structure and is primarily used to provide spreading, lubrication, smoothness, surface hydrophobicity, and long-lasting thin-layer conditioning. Water-soluble or water-dispersible silicones introduce hydrophilic segments into the siloxane structure and are mainly used to improve water-phase compatibility, wettability, emulsification assistance, and light conditioning effects.

 

Type

Structural Features

Main Functions

Common Application Directions

Oil-based dimethicone

Mainly based on a hydrophobic siloxane structure

Spreading, lubrication, smoothness, surface hydrophobicity, thin-layer conditioning

Creams, sunscreens, color cosmetics, hair conditioners, hair masks

Water-soluble or water-dispersible silicone

Hydrophilic segments introduced into the siloxane structure

Water-phase compatibility, wetting, emulsification assistance, light conditioning

Shampoos, shower gels, gels, sprays, transparent or semi-transparent systems

 

6 Differences among Silicones Are Essentially Structural Differences

 

The performance differences among common silicone-based raw materials used in personal care mainly come from differences in siloxane structure, modifying groups, molecular weight, viscosity, and dispersion form. When evaluating silicone products, it is important to distinguish them based on structural characteristics and application systems.

 

Type

Typical Names

Structural Features

Main Functions

Oil-based dimethicone

Dimethicone, polydimethylsiloxane

Mainly based on unmodified siloxane chains, with methyl groups as the main side groups

Spreading, lubrication, smoothness, reduced surface friction, formation of a hydrophobic surface layer

Water-phase-compatible or water-dispersible silicone

Polyether-modified dimethicone, PEG/PPG-modified dimethicone, dimethicone copolyol, etc.

A certain proportion of polyether hydrophilic segments introduced into the siloxane chain

Improves water-phase compatibility or dispersibility, and improves wetting, emulsification assistance, foam feel, and light conditioning effects

Amino silicone

Amino-terminated polydimethylsiloxane, amino-modified silicone

Amino functional groups introduced into the siloxane chain

Improves hair surface conditioning, wet combing, dry combing, smoothness, gloss, and anti-frizz performance

High-molecular-weight silicone / hydroxyl silicone

Hydroxyl-terminated polydimethylsiloxane, high-molecular-weight polydimethylsiloxane

Higher molecular weight, or mainly hydroxyl-terminated siloxane structure

Provides a smooth feel, gloss, surface film feel, and relatively long-lasting conditioning

Silicone emulsion

Dimethicone emulsion, amino silicone emulsion

Oil-based silicone fluid dispersed in an aqueous phase as an emulsion

Improves ease of incorporation and dispersion stability of silicones in aqueous or cleansing systems

 

7 How to Select Silicones Based on Product Needs

 

Silicone selection should focus on three core questions: whether the formulation system is compatible, whether the target effect is matched, and whether the product form is suitable for incorporation.

 

7.1 Selection based on formulation system

Different silicones have different compatibility in aqueous phases, oil phases, emulsion systems, and surfactant systems. Conventional dimethicone is hydrophobic and is suitable for oil phases or emulsion systems. Polyether-modified silicones contain hydrophilic segments and are suitable for aqueous phases or surfactant systems. Silicone emulsions are convenient for dispersion in aqueous systems.

 

Formulation System

Selection Direction

Core Reason

Oil phase or anhydrous system

Dimethicone, low-viscosity silicone fluid, volatile silicone

Good compatibility with oil-phase systems; can improve spreading and smoothness

Creams, sunscreens, color cosmetics

Dimethicone, hydroxyl-terminated polydimethylsiloxane, silicone elastomers, film-forming siloxanes

Helps improve spreading, powder dispersion, silky feel, and film uniformity

Shampoos, shower gels

Polyether-modified silicone, silicone emulsion, amino silicone emulsion

Helps dispersion in surfactant systems and improves wetting, post-rinse smoothness, and conditioning feel

Transparent gels, sprays

Verified compatible water-phase-compatible or water-dispersible silicones

Helps improve water-phase compatibility or dispersion stability, and reduces the risk of floating oil or phase separation; transparent systems require additional verification of transparency and long-term stability

Hair conditioners, hair masks

Dimethicone, amino silicone, hydroxyl-terminated polydimethylsiloxane, silicone emulsion

Helps improve lubrication, smoothness, gloss, and anti-frizz performance on the hair surface

 

7.2 Selection based on target effect

For the same target words such as “smoothness” or “lightness,” the structural sources behind them may be different. Low-viscosity silicone fluids mainly improve spreading and a light sensory feel. High-viscosity or high-molecular-weight siloxanes mainly enhance surface retention and long-lasting smoothness. Polyether-modified silicones mainly address water-phase compatibility and light conditioning. Amino silicones are mainly used for hair surface conditioning.

 

Target Effect

Selection Direction

Key Function

Rapid spreading and reduced heaviness

Low-viscosity dimethicone, volatile silicone

Reduces application resistance and improves extensibility

Silky, non-sticky skin feel

Low- to medium-viscosity dimethicone, silicone elastomer

Reduces surface friction and improves skin feel

Hair smoothness and reduced tangling

Amino silicone, dimethicone emulsion, silicone emulsion

Forms a conditioning thin layer on the hair surface

Gloss and long-lasting conditioning

High-viscosity dimethicone, hydroxyl-terminated polydimethylsiloxane

Enhances surface retention, gloss, and long-lasting smoothness

Introducing a silky feel into aqueous systems

Polyether-modified dimethicone

Improves compatibility in aqueous or surfactant systems

Transparent, semi-transparent, or low-residue cleansing products

Verified compatible polyether-modified silicone or water-dispersible silicone

Improves water-phase compatibility, wetting, and light conditioning effects

 

7.3 Five key indicators for selection

To determine whether a silicone product is suitable, the following five indicators should be considered.

 

Indicator

Significance

Name and structural type

Determines whether it is basic dimethicone, polyether-modified silicone, amino silicone, hydroxyl silicone, or silicone emulsion

Viscosity

Determines spreading speed, lightness/heaviness, film feel, and conditioning durability

Modifying group

Determines water-phase compatibility, suitability for hair conditioning, wettability, and emulsification assistance

Appearance form

Determines whether it is an oily liquid, emulsion, gel-like material, or water-dispersible product, which affects the method of incorporation and dispersion stability

Target performance

Determines whether the issue to be solved is spreading, smoothness, water resistance, gloss, conditioning, low residue, or system compatibility

 

8 Classification Table of Representative Siloxane Products Related to Dimethicone

 

Table 1. Basic Dimethylsiloxanes and High-Molecular-Weight Silicone Fluids

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or Purity

Product Features and Applications

Hydroxyl-terminated polydimethylsiloxane

70131-67-8

P433356

Poly(dimethylsiloxane), hydroxy terminated (PDMS)

Viscosity 3500 cSt

Hydroxyl-terminated high-viscosity polysiloxane; used for research on high-molecular-weight silicone fluid structure, end-group reactions, surface thin layers, hair smoothness, and long-lasting conditioning

High-viscosity dimethicone

63148-62-9

S104754

Dimethicone PMX-200

Viscosity ~60000 mPa·s, neat (25 °C)

High-viscosity linear dimethicone; used for research on the influence of viscosity on spreading, lubrication, film feel, surface friction, and hair conditioning

Trimethylsiloxy-terminated polydimethylsiloxane

9016-00-6

P195721

Polydimethylsiloxane, trimethylsiloxy terminated

Average M.W. 115,000

High-molecular-weight terminated polydimethylsiloxane; used for research on molecular weight, chain flexibility, low-friction thin layers, and long-lasting smoothness

 

Table 2. Volatile, Cyclic, Linear, and Modified Siloxanes

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or Purity

Product Features and Applications

Low-molecular-weight linear siloxane

107-46-0

H105443

Hexamethyldisiloxane (HMDSO)

≥99%

Low-molecular-weight linear siloxane; used for research on low-viscosity siloxane volatility, surface wetting, siloxane structural units, and vapor deposition

Low-molecular-weight linear siloxane

141-62-8

D470304

Decamethyltetrasiloxane

97%

Linear methyl siloxane; used for comparative research on oligomeric siloxane chain length, volatility, spreadability, and lightweight silicone fluid structures

Cyclic volatile siloxane

556-67-2

O160041

Octamethylcyclotetrasiloxane (D4)

≥98% (GC)

Cyclic methyl siloxane; used for research on cyclic siloxane structure, volatility, residual detection, polysiloxane synthesis, and quality analysis

Cyclic volatile siloxane

541-02-6

D135850

Decamethylcyclopentasiloxane

≥99% (GC)

Cyclic methyl siloxane; used for research on lightweight silicone fluids, volatile carriers, spreadability, skin feel modification, and cyclic siloxane detection

Cyclic volatile siloxane

540-97-6

D154405

Dodecamethylcyclohexasiloxane

≥97% (GC)

Cyclic methyl siloxane; used for research on volatile siloxane composition analysis, low-surface-tension materials, and silicone residue detection

Cyclic siloxane mixture

69430-24-6

C194626

Cyclopolydimethylsiloxane

≥98%

Cyclic polydimethylsiloxane mixture; used for research on lightweight silicone fluid systems, volatile carriers, spreadability, and personal care silicone formulation

Phenyl-modified siloxane

2116-84-9

H157206

1,1,1,5,5,5-Hexamethyl-3-phenyl-3-(trimethylsiloxy)trisiloxane

≥97%

Phenyl-substituted branched siloxane; used for research on the influence of phenyl modification on refractive index, gloss, spreadability, hair shine, and color cosmetic systems

Alkyl-modified siloxane

17955-88-3

H694937

1,1,1,3,5,5,5-Heptamethyl-3-octyltrisiloxane

≥97%

Octyl-modified trisiloxane; used for research on oil-phase compatibility, powder wetting, lightweight skin feel, and color cosmetic dispersion of alkyl-modified siloxanes

Branched methyl siloxane

17928-28-8

M305217

Methyltris(trimethylsiloxy)silane

≥97%

Branched methyl siloxane; used for research on low-viscosity silicone fluid structure, rapid spreading, volatile carriers, surface tension, and lightweight sensory feel

 

Note: The above are representative Aladdin products related to scientific research, testing, and formulation research. They are not equivalent to recommendations for cosmetic finished-product raw materials. The CAS numbers, naming, and regulatory status of polysiloxane raw materials may vary depending on structure, specification, and application region. For D4, D5, D6, and mixtures containing cyclic siloxanes, if they are involved in cosmetic applications or export-related applications, applicable regulations, residue limits, SDS, and COA information should be carefully checked.

 

References

 

[1] Wacker Chemie AG. BELSIL® DM 5 Product Information. Dimethicone / Polydimethylsiloxane silicone fluid product data.

 

[2] Dow Inc. XIAMETER™ PMX-200 Silicone Fluid, 50–1,000 cSt Technical Data Sheet. Dimethicone / Polydimethylsiloxane fluid data.

 

[3] Momentive Performance Materials. Silsoft™ 860 Fluid Technical Data Sheet. Dimethicone copolyol product data.

 

[4] SpecialChem. PEG-12 Dimethicone INCI Ingredient Profile. Functions: surface tension depressant, hair conditioning agent, skin conditioning agent, wetting agent, emulsifier, foam builder.

 

[5] Cosmetic Ingredient Review Expert Panel. Amended Safety Assessment of Dimethicone, Methicone, and Substituted-Methicone Polymers as Used in Cosmetics. Cosmetic Ingredient Review, 2022.

 

[6] SpecialChem. Amodimethicone INCI Ingredient Profile. Hair conditioning, detangling, frizz reduction, shine and manageability applications.

 

[7] Dow Inc. DOWSIL™ 969 Emulsion Product Information. Amine functional silicone polymer emulsion for hair care applications.

 

[8] SpecialChem. Dimethiconol INCI Ingredient Profile. Skin conditioning, emollient and film-forming silicone ingredient data.

 

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Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

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Cite this article

Aladdin Scientific. "Starting from Dimethicone: An Analysis of the Structure, Properties, and Formulation Selection of Personal Care Silicones" Aladdin Knowledge Base, updated 1 jul 2026. https://www.aladdinsci.com/us_es/faqs/starting-from-dimethicone-an-analysis-of-the-structure-en.html
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