A Panoramic Guide to Surfactants: Definitions & Mechanisms, Key Metrics, Application Scenarios, and Selection Navigation (Tables 1–3)
A Panoramic Guide to Surfactants: Definitions & Mechanisms, Key Metrics, Application Scenarios, and Selection Navigation (Tables 1–3)
1) What is a surfactant?
A surfactant (surfactant / surface-active agent) refers to a class of substances that reduce the surface tension of the solution/continuous phase in which they are dissolved, and/or reduce the interfacial tension with another phase. Therefore, they preferentially adsorb at gas–liquid or liquid–liquid / liquid–solid interfaces. Substances that are only slightly soluble but can spontaneously spread at the surface and likewise reduce surface tension may also be called surfactants.
A simple way to understand it: a surfactant is like a molecule that automatically “runs to the boundary to stand guard.” One end “likes” water, while the other end “likes” oil/air—so it is especially good at making things that are originally incompatible more willing to come into contact.
2) What do surfactants do?
The most fundamental role of surfactants is:
Reduce surface/interfacial tension → easier spreading, wetting, emulsification, dispersion, foaming, or defoaming.
Break the mechanism into three steps:
- First, “occupy” the interface: molecules preferentially adsorb at interfaces such as water–air, water–oil, and water–solid (the interface is “rearranged”).
- Lower the “cost” of forming an interface: surface/interfacial tension decreases, so water spreads more readily, and oil droplets are easier to break up and remain stably dispersed.
- At sufficient concentration, they “self-assemble”: when the surfactant concentration reaches a certain level, aggregates such as micelles (micelles/aggregates) form. Their hydrophobic core can encapsulate oily soil/hydrophobic molecules and carry them away. This threshold is the CMC (critical micelle concentration). CMC is not a constant—it is strongly affected by temperature, salinity/electrolytes, cosolvents, etc.
Note: More foam ≠ stronger cleaning. Cleaning performance depends more on wetting, emulsification/solubilization, and detachment of soil from surfaces; foam is mainly an observable “appearance.”
3) How are surface-active substances classified?
A. Classification by “hydrophilic headgroup charge”
Category | Typical characteristics | Common use examples |
Anionic | Strong detergency and foaming; skin irritation is relatively more common | Main surfactant in laundry detergents/dishwashing liquids; shampoos |
Cationic | Easily adsorbs to negatively charged surfaces/fibers; often used for antimicrobial or conditioning/softening | Hair conditioners; disinfection/antibacterial formulations; fabric softeners |
Amphoteric / zwitterionic | Mild, hard-water tolerant, good compatibility with other surfactants | Mild personal care; baby/sensitive-skin systems |
Nonionic | Strong emulsification/solubilization; relatively less sensitive to electrolytes (depending on structure) | Emulsions; food/pharmaceutical excipients; industrial cleaning |
Notes:
- Amphoteric: charge state changes with pH (can be cationic or anionic).
- Zwitterionic: carries both positive and negative charges on the same molecule; overall electrically neutral (often remains zwitterionic over a wide pH range).
B. Classification by source or “greenness”
- b1 Petrochemical synthetic surfactants: stable performance and controllable cost, but biodegradability and ecotoxicity should be considered.
- b2 Natural/biological surfactants (biosurfactants): e.g., glycolipids, lipopeptides, etc., often highlighted for renewability and environmental friendliness; however, cost, batch-to-batch consistency, and regulatory pathways may be more complex (product-dependent).
4) What are the “key metrics” for surfactants?
Metric | What it answers | Why it matters | Common methods / standards |
Surface tension / interfacial tension (γ) | “How low can it reduce the tension?” | Impacts wetting, spreading, emulsification, and cleaning efficiency | du Noüy ring and Wilhelmy plate methods are commonly used; ASTM D1331 covers related measurement methods |
CMC (critical micelle concentration) | “At what concentration do micelles start to form?” | Determines the turning point for solubilization/detergency; above the CMC, adding more surfactant typically no longer significantly lowers surface tension (cost-effectiveness) | Inflection point of the surface-tension–concentration curve, etc.; CMC is a core physicochemical parameter |
HLB (hydrophilic–lipophilic balance) | “More hydrophilic or more lipophilic?” | Quick screening for whether it is better suited to O/W vs W/O emulsification and solubilization | HLB 0–20 is a commonly used scale; classic rule of thumb: low HLB → W/O, high HLB → O/W (the Griffin system is widely cited) |
Krafft point (common for ionic surfactants) | “Will it fail to dissolve or stop working at low temperature?” | Below this temperature, solubility is insufficient and micelles are difficult to form → performance drops | Definitions and the solubility/CMC relationship are commonly used to evaluate ionic surfactants |
Cloud point (common for EO-type nonionics) | “Will it become cloudy and phase-separate upon heating?” | Affects high-temperature cleaning, formulation stability, and phase behavior | ISO 1065 mainly targets cloud-point determination for ethoxylated (EO-derived) nonionic surfactants |
Biodegradability / ecotoxicity | “What happens after discharge into the environment?” | Determines regulatory compliance and environmental risk; many cleaning systems prioritize these assessments | OECD 301 is a commonly used screening framework for ready biodegradability; eco-label schemes for cleaning products often differentiate surfactants by biodegradability and aquatic toxicity |
Additional note on HLB: HLB is most useful as an empirical starting point for nonionic emulsifiers/monomeric surfactants. For mixed surfactants, polymeric emulsifiers, or strongly ionic systems, HLB is only a rough starting point—phase behavior, droplet size, and stability must be verified experimentally.
5) What capabilities do surfactants provide, and where are they used?
A practical table of “engineering capabilities” created by converting ‘tension reduction’ into function:
Engineering capability | What “interfacial problem” it solves | Typical application scenarios | Common surfactant types / selection tips |
Wetting | Lowers liquid–gas / liquid–solid interfacial tension so liquids spread and penetrate pores/rough surfaces | Coating, cleaning, pesticide spraying, substrate pre-wetting | Low surface tension / fast-adsorbing types; silicone surfactants wet strongly but require attention to formulation compatibility |
Emulsification | Lowers oil–water interfacial tension and forms an interfacial film to prevent droplet coalescence; stability also depends on interfacial film strength/rheology and electrostatic/steric repulsion | Cosmetic emulsions, food emulsification, drug/fragrance emulsification | Nonionics are common (HLB approach: high HLB → O/W, low HLB → W/O); often blended with co-emulsifiers |
Dispersion | Helps solid particles “wet + deagglomerate,” and prevents re-agglomeration via electrostatic/steric stabilization; also depends on ζ-potential/steric layer, ionic strength, and shear history | Pigments, ceramic slurries, nanomaterials, carbon black/filler dispersion | Anionic/nonionic/polymeric dispersants are common; key is particle size, ionic strength, and shear conditions |
Solubilization | Above CMC, micelles encapsulate hydrophobes in the hydrophobic core, greatly increasing apparent solubility | Fragrance solubilization, solubilizing hydrophobic actives, lab membrane solubilization/lysis | Pay attention to CMC and micelle structure |
Detergency | Wetting + emulsification/solubilization + lifting soil off surfaces and keeping it suspended to prevent redeposition | Laundry, dishwashing, industrial degreasing | Anionics: strong cleaning + foaming; amphoteric/nonionic: reduce irritation and improve hard-water tolerance |
Foaming / foam stabilization | Forms an elastic film at the gas–liquid interface to delay foam collapse (sometimes foam suppression is needed instead) | Personal-care foaming, firefighting foam, foamed materials; fermentation/coating often requires foam control | Strong foaming ≠ strong detergency; industrial processes often need low foam or a defoamer |
Antistatic / conditioning | Cationics adsorb onto negatively charged surfaces (fibers/hair/skin), reducing friction and static and improving feel | Fabric softening, hair-conditioning, antistatic finishing | Typically quaternary-ammonium cationic surfactants; watch compatibility with anionic systems (can “fight” and lose efficacy) |
6) Advantages and risk points of surfactants
Table A | Advantages of surfactants
Advantage | Detailed description | Notes |
High efficiency | Small dosages can markedly change interfacial properties; many properties show clear turning points/slope changes as concentration approaches CMC. | Solubilization usually requires ≥ CMC; detergency is not fully equivalent to micellization |
Multi-functionality | The same class of molecules can work across different interfacial processes: wetting, emulsification, dispersion, solubilization, foaming/defoaming, etc. | Emphasizes a “toolbox for interfacial processes” |
Strong tunability | By tuning headgroup, chain length, EO number, branching/aromatic rings, ion pairing, etc., one can emphasize strong cleaning, mildness, low foam, salt tolerance, and other priorities | Performance trade-offs exist |
Table B | Risk points and mitigation
Risk point | Typical mechanism/manifestation | Notes | Common mitigation |
Skin irritation / barrier disruption | May cause dryness, stinging, and barrier damage risks via protein denaturation and disruption/extraction of stratum-corneum lipids; anionics (e.g., SLS) are often considered “harsher.” Cationic quaternary ammonium surfactants may also be more irritating/stronger membrane-active (especially for skin/mucosa), though they are more often used for conditioning/antimicrobial effects than as high-dose primary cleaners. | “Related to surfactant type, but more strongly influenced by concentration, pH, contact time, and the overall formulation system.” | Blend with amphoteric/nonionic; reduce active level; add oils/humectants/lipid replenishment; shorten contact time for rinse-off products |
Large variation in environmental burden | Biodegradability and aquatic toxicity vary greatly with structure; eco-labels/regulations often control based on biodegradability and aquatic-toxicity metrics. | “OECD 301 is a ready-biodegradability screen; assessment must also consider products and use scenarios.” “Biodegradable” depends on structure and environmental conditions. | Prioritize OECD 301 screening; combine aquatic-toxicity assessment and frameworks such as total formulation CDV, etc. |
Formulation compatibility / stability issues | Hard-water Ca²⁺/Mg²⁺ can precipitate some anionic surfactants; salt/electrolytes and temperature shift CMC, phase behavior, and cloud point/turbidity, causing phase separation, abnormal viscosity, foam runaway, etc. | “Environmental changes = changes in interfaces and aggregation states—this is a common root cause of failure.” | Choose hard-water-tolerant systems or add chelators; control salinity/temperature windows; adjust nonionic EO number/HLB; use blends to improve phase behavior |
7) Surfactant Selection Guide and Representative Product Tables
Selection Navigation
Dimension (ask yourself first) | Typical scenarios / keywords | Which table to check first | Selection logic | Representative products |
Cell lysis / protein extraction (preserve activity when possible, or routine lysis) | “Lysis buffer, RIPA, co-IP, WB/ELISA wash, permeabilization, membrane-protein solubilization” | Table 1 | Detergents for bio/protein/membrane research | Table 1 focuses on lab-favorite detergent systems (nonionic / amphoteric / bile salts / glycosides), spanning a practical “mild → strong” gradient that maps well to biochemical workflows. | Triton™ X-100 / NP-40 type; CHAPS/CHAPSO; sodium cholate/sodium deoxycholate; DDM/maltosides; SDS (strongly denaturing) |
Membrane-protein structural work / reconstitution (cryo-EM, X-ray, NMR) | “Membrane-protein stability, micelles, detergent exchange & reconstitution, low background/high purity, structural biology” | Table 1 | Detergents for bio/protein/membrane research | Membrane proteins are sensitive to detergent mildness, purity, and stabilizing behavior; in Table 1, glycosides/maltosides/zwitterionic detergents are often used as a primary screening set. | DDM (n-dodecyl-β-D-maltoside); 1-O-decyl-β-D-maltoside; DPC; CHAPS/CHAPSO; OGP |
Denaturing electrophoresis sample prep | “SDS-PAGE, full denaturation, sharper bands” | Table 1 | Denaturing electrophoresis typically requires a strong anionic detergent to impart charge and unfold proteins; Table 1 includes the canonical option. | Sodium dodecyl sulfate (SDS) |
Endotoxin removal / temperature-controlled phase separation enrichment | “Triton X-114 phase separation, cloud point, endotoxin, phase-partition enrichment” | Table 1 | These applications rely on specific detergent physicochemical properties (cloud point/phase separation) and are closer to biochemical process operations. | Triton™ X-114 |
Emulsification / solubilization / formulation development (cosmetics, cleaning, pharma solubilization) | “HLB, O/W or W/O, clear solubilization, essential oils/fragrances, microemulsions, emulsion stability” | Table 2 | Formulation emulsifiers/solubilizers & mild cleansing systems | Table 2 centers on “formulation engineering” surfactants—Tween/Span/PEG-40 HCO/Poloxamer, etc.—suited to emulsion and solubilization system design. | Tween® 20/80; Span® 20/60/80; PEG-40 hydrogenated castor oil; Kolliphor® P 407; AOT (microemulsions/reverse micelles) |
Mild cleansing / foaming systems (low-irritation blending) | “Mild, low irritation, foaming/foam stability, facial cleanser/shampoo, irritation reduction by blending” | Table 2 | Table 2 includes common mild routes: amino-acid surfactants, betaines, APG, SLES/SLSA, etc.—ideal for a “primary surfactant + co-surfactant” framework. | Cocamidopropyl betaine; sodium lauroyl glutamate; dodecyl glucoside; SLES; SLSA; sodium lauroyl isethionate |
Materials synthesis / surface modification / templated nanomaterials | “Mesoporous templates, nanoparticle surface modification, phase transfer, cationic modification” | Table 3 | Cationic surfactants/antimicrobial preservatives/analytical standards (priority) + check Table 2 if needed | These uses often rely on cationic quaternary ammonium salts (templating/adsorption/phase transfer). If emulsification/solubilization is needed, return to Table 2 for formulation surfactants. | CTAB; DTAB; HTAC; (for phase transfer/emulsification, blend with Tween/Span as needed) |
Antimicrobial / preservative / disinfection-related (formulations or methods) | “Quats, antimicrobial, disinfection, preservative challenge test” | Table 3 | Table 3 compiles typical cationic antimicrobial systems and pharmacopeial/solution-form products—good for direct screening along the antimicrobial route. | Benzalkonium chloride; cetylpyridinium chloride (Ph. Eur.); DDAC |
Analytical methods / QC / standards (not for formulation dosing) | “Standard solution, calibration, environmental analysis, titration” | Table 3 | Table 3 includes standards and titrants—more suitable for QC/method development than as bulk formulation ingredients. | PFOA analytical standard; SDBS standard solution; benzethonium chloride titrant |
Only know “milder vs stronger,” not sure what to pick | “Mild, activity-preserving, strong detergency, blending” | Start with Table 1 (biochem) or Table 2 (formulation), then return to Table 3 when charge/antimicrobial/templating is needed | First choose the table by application field, then within the table screen progressively: nonionic/amphoteric → strong anionic detergency → cationic special uses for maximum efficiency. | Biochem: DDM/CHAPS → Triton → SDS; Formulation: APG/CAPB/amino-acid → SLES/AOS; Special: CTAB/BAC/DDAC |
Table 1 | Common Detergents for Bio/Protein/Membrane Research
(Lysis, membrane-protein solubilization, bile salts / zwitterionics / glycoside systems)
Category | CAS No. | Aladdin Cat. No. | Name | Spec / Purity | Key features & applications |
Nonionic | PEG alkyl ether | 9002-92-0 | Polyethylene glycol monododecyl ether | For membrane research | Mild nonionic detergent/solubilizer; used for membrane studies, membrane-protein solubilization and reconstitution; relatively less denaturing. | |
Anionic | Sulfate (strong detergency/denaturing) | 151-21-3 | Sodium dodecyl sulfate (SDS) | For electrophoresis, anionic | Classic strong anionic detergent; for SDS-PAGE denaturing sample prep and thorough protein solubilization; strongly disrupts protein structure, not suitable for activity-preserving extraction. | |
Nonionic | Alkyl aryl poly(oxyethylene) ether (Triton-type) | 9002-93-1 | Triton X-100 (Triton™ X-100) | For electrophoresis | Classic nonionic lysis agent; cell lysis, mild membrane-protein solubilization, tissue/membrane permeabilization; often used to reduce background in immunoassays (detergent choice may need screening for certain membrane proteins). | |
Nonionic | Alkyl aryl poly(oxyethylene) ether (Triton-type) | 9036-19-5 | Triton™ X-114 | Reagent grade | Nonionic detergent with cloud-point phase separation; used for temperature-controlled phase partition enrichment of membrane proteins and removal of LPS/endotoxin; suitable for workflows requiring thermal phase separation. | |
Nonionic | Alkylphenol ethoxylate (NP-40 type) | 9016-45-9 | Nonylphenol ethoxylate (Tergitol NP-40) | Isomer mixture, white flakes | NP-40-type nonionic lysis detergent; for cell lysis, protein solubilization, and immunoassay washing; alkylphenol ethoxylates require extra attention to environmental/compliance considerations (more common in research settings). | |
Anionic | Amino-acid surfactant (sarcosinate) | 137-16-6 | Sodium N-lauroyl sarcosinate | Detergent for cell lysis | Relatively mild anionic surfactant; for cell lysis/protein extraction, cleaning, and irritation reduction in formulations; often chosen as a “milder than SDS” option. | |
Anionic | Bile salt | 302-95-4 | Sodium deoxycholate | For manufacturing of diagnostic kits and reagents | Bile-salt detergent; common in RIPA lysis systems to solubilize membrane proteins/lipoproteins; milder for some proteins but sensitive to salt/temperature/pH (formulation optimization needed). | |
Anionic | Bile salt | 361-09-1 | Sodium cholate | Moligand™, ≥98% | Bile-salt detergent; used for solubilizing membrane-protein/lipid systems and building mixed micelles; common in liposome/membrane-mimetic systems; ≥98% supports better reproducibility. | |
Anionic | Taurocholate | 145-42-6 | Sodium taurocholate | ≥95% | More hydrophilic bile salt; used for membrane-protein solubilization and lipid/cholesterol micelle construction; often used as a “more physiologically relevant bile-salt” model. | |
Zwitterionic | CHAPS (bile-acid-based sulfobetaine) | 75621-03-3 | 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) | Ultra-pure grade | Classic zwitterionic detergent; mild and more activity-friendly; widely used for membrane-protein solubilization, IEF, and protein complex studies; “ultra-pure” suits high-sensitivity experiments. | |
Zwitterionic | CHAPSO (more hydrophilic CHAPS-type) | 82473-24-3 | CHAPSO | UltraBio™, ultra-pure | Mild zwitterionic detergent (CHAPSO-type); more hydrophilic; used to solubilize/stabilize membrane proteins/complexes and reduce aggregation; suitable when purity/low background is critical. | |
Zwitterionic | Phosphocholine (DPC) | 29557-51-5 | n-Dodecylphosphocholine (DPC) | ≥99% | Zwitterionic detergent; commonly used for membrane-protein micelles, NMR/structural screening, and functional maintenance; ≥99% is suitable for impurity/background-sensitive studies. | |
Nonionic | Glycoside (alkyl glucoside, short-chain OG) | 29836-26-8 | n-Octyl-β-D-glucopyranoside (OGP) | For protein analysis, ≥98% | Mild glycoside detergent; used for membrane-protein solubilization/refolding and structural work; relatively easy to dialyze/remove (higher CMC, helpful for downstream reconstitution). | |
Nonionic | Glycoside (APG, decyl glucoside) | 58846-77-8 | Decyl glucopyranoside | Biochemical reagent | Mild, low-irritation sugar-based surfactant; used for gentle membrane-protein solubilization and stabilization of enzyme/protein systems; also common in personal-care/cleaning as a mild primary/co-surfactant. | |
Nonionic | Maltoside (DDM) | 69227-93-6 | n-Dodecyl-β-D-maltoside (DDM) | UltraBio™, ultra-pure, ≥98% | One of the “gold-standard” mild detergents for membrane proteins; often preserves structure/activity well; widely used in structural biology (cryo-EM/X-ray) and functional studies; ultra-pure grade improves reproducibility and lowers background. | |
Nonionic | Maltoside (decyl maltoside) | 82494-09-5 | 1-O-Decyl-β-D-maltoside | ≥97% | Mild nonionic detergent (shorter chain → easier removal/higher CMC); used for membrane-protein solubilization and reconstitution; suitable when rapid detergent exchange/removal is needed downstream. | |
Amphoteric / zwitterionic | Amine oxide | 1643-20-5 | Dodecyldimethylamine oxide | BioReagent, ≥99%(NT), ≥99.0% (NT) | Amine-oxide surfactant (relatively mild, good compatibility); used for membrane-protein solubilization, cleaning, and formulation foaming/foam stabilization; can be blended with anionics to improve detergency while moderating irritation. | |
Natural surfactant | Saponin (Digitonin) | 11024-24-1 | Digitonin | 50% | Classic mild saponin detergent; cholesterol-affine; used for selective plasma-membrane permeabilization, solubilization of cholesterol-rich membrane domains, and preserving protein-complex architecture as much as possible. |
Table 2 | Formulation Emulsification/Solubilization & Mild Cleansing Systems
(HLB tuning, solubilization, foaming, and mild routes)
Category | CAS No. | Aladdin Cat. No. | Name | Spec / Purity | Key features & applications |
Nonionic | Polysorbate (Tween) | 9005-65-6 | Tween® 80 | Viscous liquid, preservative-free, low peroxide; low carbonyl | High-HLB solubilizer/emulsifier; commonly used for solubilization and stabilization in protein/vaccine/biologics formulations; “low peroxide/low carbonyl” is preferred for oxidation-sensitive systems. | |
Nonionic | Polysorbate (Tween) | 9005-64-5 | Tween® 20 (TWEEN® 20) | Viscous liquid | High-HLB solubilization/wetting; often added to ELISA/Western wash buffers to reduce nonspecific adsorption; also used for gentle solubilization of membrane-associated components. | |
Nonionic | Sorbitan fatty-acid ester (Span) | 1338-43-8 | Span 80 | Viscosity 1000–2000 mPa·s (20 °C) | Low-HLB W/O emulsifier; suited for oil-phase systems and inverse emulsions/microemulsions; often blended with Tween 80 to tune HLB for O/W ↔ W/O switching and stability. | |
Nonionic | Sorbitan fatty-acid ester (Span) | 1338-39-2 | Span® 20 | For synthesis | Low-HLB W/O emulsifier/co-emulsifier; often blended with Tween 20 to tune HLB; used for synthesis, oil-phase dispersion, and emulsion stabilization. | |
Nonionic | Sorbitan fatty-acid ester (Span) | 1338-41-6 | Span 60 | Nonionic surfactant | Low-HLB W/O emulsifier; more oriented toward thickening/structuring and emulsion stability; common in creams/ointments and oil-rich systems; can be blended with Tween to tune HLB. | |
Nonionic | Block copolymer (Poloxamer/Pluronic) | 9003-11-6 | K434429 | Kolliphor® P 407 | Ethylene oxide 71.5–74.9% | Poloxamer 407 (PEO–PPO–PEO) solubilizer/stabilizer; used for hydrophobic drug solubilization, protein stabilization, and cell-culture additives; also common in thermoresponsive gel/sustained-release research. |
Anionic | Sulfosuccinate (Docusate/AOT) | 577-11-7 | Sodium dioctyl sulfosuccinate (AOT) | PharmPure™, USP | Has both pharmacopeial grade and surfactant functionality; used in microemulsions/reverse micelles (reverse-micellar solvation), dispersion, and interfacial studies; USP grade is better for pharma-related R&D/QC. | |
Amphoteric | Betaine (CAPB) | 61789-40-0 | Cocamidopropyl betaine | Active content 28%–32% in water | Classic mild amphoteric surfactant; often used as a co-surfactant to boost foam/stability, reduce irritation, and improve skin feel; compatible with anionic surfactants—good for cleansing/personal-care formulation development. | |
Anionic | Amino-acid surfactant (glutamate) | 29923-31-7 | Sodium lauroyl glutamate | ≥95% | Amino-acid-based mild anionic surfactant; used for mild cleansing, foaming, and sensory optimization; suitable for “low irritation + blendable” formulation routes and comparative screening. | |
Anionic | Sulfoacetate (SLSA) | 1847-58-1 | Sodium lauryl sulfoacetate | ≥97% | Relatively mild anionic foaming surfactant; used in personal-care/cleaning formulations with fine foam; also usable for basic interfacial/micelle research. | |
Anionic | Isethionate (Sodium lauryl isethionate) | 7381-01-3 | Sodium lauroyl isethionate | ≥95% | Mild anionic surfactant (common in syndet facial cleansers/soap-free systems); fine foam and relatively lower irritation; suitable for mild-cleansing formulation and system benchmarking. | |
Anionic | Alpha-olefin sulfonate (AOS) | 68439-57-6 | Sodium alpha-olefin sulfonate | ≥92% | High detergency and hard-water tolerance; widely used in laundry/cleaning and industrial cleaning; suitable for systems demanding strong foam and cleaning performance. | |
Nonionic | Glycoside (APG, dodecyl glucoside) | 110615-47-9 | Dodecyl glucoside | ≥40% | APG-type mild nonionic surfactant (solution/assay form); used for mild cleansing, solubilization, and irritation reduction in formulations; also usable for gentle solubilization screening in membrane-related systems. | |
Anionic | Ether sulfate (SLES) | 9004-82-4 | Sodium laureth sulfate | ≥25% | Classic anionic primary foaming surfactant (SLES); used in shampoos/body washes/cleaning systems; balances foam and cleaning; blending with amphoterics can reduce irritation and stabilize foam. | |
Nonionic | PEG-40 hydrogenated castor oil (PEG-40 HCO) | 61788-85-0 | PEG-40 hydrogenated castor oil | — | Strong solubilizing nonionic surfactant; used for solubilizing fragrances/essential oils/lipophilic actives and for clear formulations and microemulsions; good when “clear appearance + high solubilization capacity” is needed. |
Table 3 | Cationic Surfactants / Antimicrobial Preservatives / Analytical Standards
(Quaternary ammonium systems + standards/titrants)
Category | CAS No. | Aladdin Cat. No. | Name | Spec / Purity | Key features & applications |
Cationic | Quaternary ammonium (pyridinium salt) | 6004-24-6 | Cetylpyridinium chloride monohydrate | European Pharmacopoeia (Ph. Eur.) | Antimicrobial quaternary ammonium (CPC); used in oral-care/antimicrobial research and formulations; also used as a cationic surfactant for interfacial control and adsorption studies. | |
Cationic | Quaternary ammonium (CTAB type) | 57-09-0 | H108986 | Cetyltrimethylammonium bromide (CTAB) | Ion-pair chromatography grade, ≥99% | Strong cationic surfactant; widely used as a template in materials synthesis (e.g., mesoporous silica), nanoparticle synthesis and surface modification; also used as an ion-pair/chromatography additive and in phase-transfer systems. |
Cationic | Quaternary ammonium (DTAB type) | 1119-94-4 | Dodecyltrimethylammonium bromide (DTAB) | BioReagent Plus, ≥99% | Cationic detergent; used for micelle/interfacial charge control, materials–biomacromolecule interaction studies; can also solubilize certain membrane systems (shorter chain than CTAB). | |
Cationic | Double-chain quaternary ammonium (DDAC) | 7173-51-5 | Didecyldimethylammonium chloride (DDAC) | ≥95% | Strong cationic surfactant/biocide; used in disinfection, antimicrobial surface treatments, and phase-transfer emulsification; double long chains enhance adsorption and antimicrobial performance. | |
Cationic | Quaternary ammonium (CTAC solution) | 112-02-7 | Cetyltrimethylammonium chloride solution (HTAC) | 25 wt.% in H₂O | Cationic surfactant solution (CTAC/HTAC); used for phase transfer, emulsification, and surface modification (cationization of particles/fibers/films); aqueous solution is convenient for direct dosing. | |
Cationic | Quaternary ammonium (disinfection/preservation, BAC) | 8001-54-5 | A304666 | Benzalkonium chloride | 80% ethanol solution | Broad-spectrum antimicrobial quaternary ammonium; used in disinfection, preservation, and surface-treatment research; ethanol solution form is convenient for preparation and antimicrobial/method development experiments. |
Cationic | Quaternary ammonium (analytical titrant) | 121-54-0 | H128347 | Benzethonium chloride analytical titrant | Analytical titrant, 0.04 M | Commonly used for surfactant-related QC and two-phase titration (e.g., determining anionic surfactant content); suitable for method development and QC experiments. |
Fluorinated surfactant | PFAS (analytical standard) | 335-67-1 | Perfluorooctanoic acid (PFOA) | Analytical standard, for environmental analysis | Typical PFAS (fluorinated surfactant/pollutant) analytical standard; used for PFAS method development, QC, and quantification in environmental samples. | |
Anionic | Aryl sulfonate (SDBS standard) | 25155-30-0 | Sodium dodecylbenzenesulfonate standard solution (SDBS) | Analytical standard, 1000 µg/mL in water | Standard solution of an anionic aryl-sulfonate surfactant; used for environmental/method quantification, instrument calibration, and QC; also a reference in surfactant behavior/micelle studies. |
Note: The above are representative Aladdin products. For more specifications, please refer to the product list at the end of this article, or search the Aladdin website by product name/CAS number.
Aladdin: https://www.aladdinsci.com/
