Sodium Metasilicate in Cleaning Applications: Hydration-Form Differences, Mechanisms of Action, and Selection Logic
Sodium Metasilicate in Cleaning Applications: Hydration-Form Differences, Mechanisms of Action, and Selection Logic
1 The Nature of Sodium Metasilicate: Not Simply a Strong Alkali, but an Alkaline Silicate
Sodium metasilicate is a commonly used inorganic alkaline builder in household cleaning, industrial cleaning, metal cleaning, and powdered detergent systems. Its basic chemical composition is Na₂SiO₃, and it can form different hydrates. This article focuses on three forms: anhydrous sodium metasilicate, sodium metasilicate pentahydrate, and sodium metasilicate nonahydrate. Among them, anhydrous sodium metasilicate and sodium metasilicate pentahydrate are more commonly used in cleaning and detergent systems, while sodium metasilicate nonahydrate should be used with reference to the product specification and verified active content.
After sodium metasilicate enters water, it provides a strongly alkaline environment on the one hand and introduces silicate species on the other. Therefore, its role in cleaning systems is not limited to increasing the pH value. It also contributes to oil removal, detergency building, dispersion, anti-redeposition, and metal corrosion inhibition.
2 Hydration-Form and Active-Content Differences Among Anhydrous, Pentahydrate, and Nonahydrate Sodium Metasilicate
2.1 Basic Composition of the Three Product Forms
The core difference among anhydrous, pentahydrate, and nonahydrate sodium metasilicate lies in their different hydration states, that is, the different amounts of water of crystallization contained in the crystal. Water of crystallization is not simply external moisture; it is part of the crystal structure. It directly affects the molecular weight, active content, dissolution behavior, storage stability, and dosage conversion of the product.
Product Type | Molecular Formula | Relative Molecular Mass | Water of Crystallization Content | Calculated Anhydrous Na₂SiO₃ Content | Main Interpretation |
Anhydrous sodium metasilicate | Na₂SiO₃ | approx. 122.06 | 0 | 100% | Highest active content; provides the greatest alkalinity and silicate contribution per unit mass |
Sodium metasilicate pentahydrate | Na₂SiO₃·5H₂O | approx. 212.14 | approx. 42.5% | approx. 57.5% | Balanced active content, solubility, and handling properties; widely used in cleaning systems |
Sodium metasilicate nonahydrate | Na₂SiO₃·9H₂O | approx. 284.20 | approx. 57.1% | approx. 43.0% | Lower active content than the pentahydrate; dosage should be converted based on active content |
The data in the table are theoretical values calculated from the molecular formulas of pure substances. For actual industrial products, indicators in the product certificate of analysis, such as sodium oxide, silicon dioxide, water-insoluble matter, loss on ignition, particle size, and moisture, should be used as the basis.
2.2 Influence of Active-Content Differences on Formulation
When comparing different hydrates, the appropriate approach is to evaluate how much effective Na₂SiO₃, Na₂O, and SiO₂ is provided per unit mass of product.
For example, from the perspective of theoretical effective Na₂SiO₃ content:
Target Effective Amount | Required Anhydrous Sodium Metasilicate | Required Sodium Metasilicate Pentahydrate | Required Sodium Metasilicate Nonahydrate |
To provide approx. 1 kg of anhydrous Na₂SiO₃ | approx. 1.00 kg | approx. 1.74 kg | approx. 2.33 kg |
If 1 kg of anhydrous sodium metasilicate is directly replaced with 1 kg of sodium metasilicate pentahydrate, the actual effective Na₂SiO₃ content is only about 57.5%. If it is replaced with 1 kg of sodium metasilicate nonahydrate, the actual effective Na₂SiO₃ content is only about 43.0%. In detergent, machine dishwashing powder, metal cleaner, and similar systems, this will affect the pH value, alkali reserve, oil-removal performance, soil-dispersion ability, and product cost.
2.3 Performance Differences Caused by Water of Crystallization
Water of crystallization changes not only the active content but also the physical behavior of the product. Anhydrous sodium metasilicate has a high active content and is suitable for highly concentrated powders or moisture-sensitive formulations. However, issues such as moisture absorption, caking, localized high alkalinity, and heat release during dissolution require careful control.
Because sodium metasilicate pentahydrate contains water of crystallization, its effective content per unit mass is lower than that of the anhydrous product. However, it is generally more balanced in terms of solubility, ease of dosing, and formulation compatibility. Sodium metasilicate nonahydrate has an even lower active content and is suitable for systems with specific dissolution or handling requirements.
2.4 Na₂O and SiO₂ Are Conventional Composition Expressions in the Silicate Industry
The chemical formula of sodium metasilicate can be written as:
Na₂SiO₃
However, in industrial products such as silicates, water glass, and sodium metasilicate, compositions are commonly expressed in oxide form:
Na₂SiO₃ = Na₂O · SiO₂
Here, Na₂O and SiO₂ represent the composition of sodium metasilicate converted into “sodium oxide content” and “silicon dioxide content.”
Expression | Meaning |
Na₂SiO₃ | Chemical formula expression, indicating that the substance is sodium metasilicate |
Na₂O | Calculated alkaline oxide component, used to represent the alkaline contribution |
SiO₂ | Calculated siliceous oxide component, used to represent the silicate contribution |
Na₂O + SiO₂ | Can be understood as important components of the effective solids in sodium metasilicate |
SiO₂/Na₂O or Na₂O/SiO₂ molar ratio or composition ratio | Indicates the relative proportion of siliceous and alkaline components in a silicate system |
It should be noted that Na₂O and SiO₂ are oxide-equivalent expressions used in the silicate industry. They do not mean that free Na₂O or free SiO₂ actually exists in the product.
3 Basis of Action After Sodium Metasilicate Enters Water
3.1 Strong Alkalinity Is the Starting Point of Cleaning Action
After dissolving in water, sodium metasilicate forms a strongly alkaline environment. A higher pH helps reduce the adhesion between oily soils and the substrate, promotes the neutralization of fatty acid soils, and, under appropriate temperature, alkalinity, and contact time, promotes partial hydrolysis or saponification of oils and fats. This makes some oily soils easier to emulsify, disperse, and detach from surfaces. In laundry powders, machine dishwashing powders, hard-surface cleaners, and metal degreasers, the alkalinity provided by sodium metasilicate is an important basis for its oil-removal performance.
3.2 Silicate Species Distinguish It from Caustic Soda
The silicate species formed after sodium metasilicate dissolves in water can participate in soil dispersion, particle suspension, mitigation of hard-water effects, and metal surface protection. This is the key feature that distinguishes sodium metasilicate from caustic soda. Caustic soda mainly relies on strong alkalinity to rapidly increase the system pH, making it suitable for strong degreasing and saponification. Sodium metasilicate, in addition to increasing pH, can also improve the overall interaction of the cleaning system with soils, hard-water ions, and metal surfaces.
4 Cleaning Mechanisms of Sodium Metasilicate
4.1 Oil Removal: High pH Promotes Oil Detachment and Saponification
Oily soils in household and institutional cleaning typically include animal and vegetable oils, sebum, food oil residues, industrial oils, and mixed organic soils. The strongly alkaline environment provided by sodium metasilicate can promote hydrolysis or saponification of oils and fats, converting some oily soils into substances that are more easily carried away by the aqueous phase. At the same time, high pH can weaken the bonding between oily soils and the substrate surface, making it easier for surfactants to enter the interface between the soil and the substrate, thereby promoting oil detachment, emulsification, and dispersion.
4.2 Builder Function: Improving the Effectiveness of Surfactants
The core role of a builder is to improve the overall efficiency of a cleaning system, rather than to perform cleaning alone. As an inorganic builder, sodium metasilicate mainly improves the performance of surfactants through the following mechanisms:
Builder Function | Mechanism |
Maintaining alkalinity | Acidic soils and oils consume alkalinity during cleaning; sodium metasilicate helps maintain an effective pH value |
Reducing hard-water effects | Ca²⁺, Mg²⁺, and other hard-water ions can reduce the efficiency of some surfactants; silicate systems can reduce the negative effects of hard water to a certain extent |
Promoting emulsification | An alkaline environment facilitates emulsification and dispersion of oily soils |
Suspending soils | Detached soil particles need to remain stably suspended to prevent redeposition |
4.3 Dispersion and Anti-Redeposition: Keeping Soil from Returning After It Leaves the Surface
Cleaning is not only about detaching soils from surfaces; it also requires keeping soils in the cleaning solution and preventing them from reattaching to fabrics, tableware, equipment, or metal surfaces. The silicate system provided by sodium metasilicate helps improve the dispersion stability of soil particles in the aqueous phase. For mud, oily deposits, carbon black, metal oxide particles, and mixed soils, this dispersion effect can reduce soil redeposition and improve cleanliness after washing.
5 Corrosion Inhibition and Metal Cleaning Functions of Sodium Metasilicate
5.1 The Core Role in Metal Cleaning: Degreasing and Protection Together
In metal processing, mechanical maintenance, equipment cleaning, and parts cleaning, common surface contaminants include cutting oils, rust-preventive oils, greases, dust, metal chips, oxide particles, and mixed soils. The role of sodium metasilicate in metal cleaning mainly includes two aspects:
① Providing alkaline conditions to promote emulsification, saponification, and detachment of oily soils.
② Providing silicate species that, under certain conditions, participate in the formation of a protective layer on metal surfaces, thereby reducing the risk of continued corrosion during cleaning or flash rust after cleaning.
5.2 Corrosion-Inhibition Mechanism: Silicate-Based Surface Protection
The corrosion-inhibition effect of sodium metasilicate does not mean that it is safe for all metals. Rather, it means that under suitable pH, silicate concentration, water-quality, and formulation conditions, silicate species may provide a certain protective effect on specific metal surfaces. Its corrosion-inhibition mechanism is usually related to the adsorption, deposition, or reaction of silicate species on metal surfaces.
Under suitable conditions, silicate species may interact with oxides, hydroxides, or metal ions on the metal surface to form a surface layer with a certain barrier effect, thereby reducing the opportunity for corrosive media such as oxygen, water, and chloride ions to come into direct contact with the metal substrate. For steel surfaces, silicates may act through adsorption, deposition, or interaction with surface iron oxides to form less soluble silicates or composite protective layers, thereby showing certain corrosion-inhibition and flash-rust-reduction effects.
It should be noted that silicate protection is strongly system-dependent. Factors such as pH, temperature, sodium metasilicate concentration, contact time, water hardness, chloride ion content, metal type, and formulation components such as surfactants, chelating agents, phosphates, and phosphonates can all affect the final corrosion-inhibition performance. For alkali-sensitive materials such as aluminum, zinc, tin, plated parts, and certain alloys, sodium metasilicate systems should not be assumed to be safe by default. Substrate compatibility should be confirmed through testing under the actual cleaning concentration, temperature, and contact time.
6 Selection and Differences Between Sodium Metasilicate and Caustic Soda
6.1 Common Features
Both sodium metasilicate and caustic soda can provide alkalinity and can be used to remove oils, greases, and some organic soils. In strongly alkaline cleaning, both require attention to risks involving the skin, eyes, respiratory tract, and metal corrosion. However, having common features does not mean that they can be directly substituted for each other. They differ in chemical identity and formulation function.
6.2 Fundamental Differences
Comparison Item | Sodium Metasilicate | Caustic Soda |
Chemical name | Sodium metasilicate | Sodium hydroxide |
Typical molecular formula | Na₂SiO₃·nH₂O | NaOH |
Chemical property | Alkaline silicate | Strong base |
Main function | Provides alkalinity, builder function, dispersion, buffering, and corrosion inhibition | Rapidly provides OH⁻ and strongly increases pH |
Cleaning characteristics | Emphasizes synergy in the overall cleaning system | Emphasizes strong alkaline saponification and degreasing |
Effect on metals | Has certain corrosion-inhibition potential, but still requires testing | More direct corrosion risk, especially for amphoteric metals such as aluminum and zinc |
Substitution relationship | Cannot replace caustic soda on an equal-mass basis | Cannot replace the silicate functions of sodium metasilicate |
6.3 Selection Logic
Caustic soda is suitable for systems that require rapid pH increase, strong saponification of oils and fats, and strong degreasing, such as heavy-oil cleaning, strong alkaline degreasing, pipeline cleaning, and certain industrial cleaning scenarios. However, caustic soda is highly corrosive, releases significant heat during dissolution, poses higher risks to metals such as aluminum and zinc, and requires stricter operational safety controls.
Sodium metasilicate is more suitable for systems requiring comprehensive cleaning performance, such as laundry powders, machine dishwashing powders, hard-surface cleaners, metal degreasers, and powdered industrial cleaners. It not only provides alkalinity but also improves soil dispersion, anti-redeposition, and metal corrosion inhibition.
In actual formulations, the two can be combined according to cleaning strength, material compatibility, safety requirements, and cost targets. However, they cannot be simply substituted on an equal-mass or equal-pH basis.
7 Does Sodium Metasilicate Have Rust-Removal Function?
7.1 Sodium Metasilicate Is Not a Typical Primary Rust Remover
Sodium metasilicate can help treat certain rust-related soils, but it is not a typical primary rust remover. Rust is usually mainly composed of iron oxides and hydrated iron oxides. The true removal of firmly adherent rust layers generally relies on acid dissolution, complexation, reduction, or mechanical action. Common rust-removal systems include phosphoric acid, hydrochloric acid, oxalic acid, citric acid, sulfamic acid, chelating agents, or reducing components.
Sodium metasilicate belongs to alkaline cleaning systems and is better suited for oil removal, dispersion, suspension, and corrosion inhibition. It has a good auxiliary cleaning effect on oily soils, mud, and loose rust powder, but it is not the main active component for removing firmly adherent oxide scale or thick rust layers.
7.2 Why Sodium Metasilicate Sometimes Appears to Remove “Rust Stains”
The actual soils on metal surfaces are often not single-component rust, but mixed layers of oil, dust, mud, loose oxides, and rust powder. Sodium metasilicate can make the surface appear cleaner through the following actions:
Target Soil | Actual Role of Sodium Metasilicate |
Oil-covered layer | Removes oil through alkalinity, emulsification, and saponification |
Loose rust powder | Helps carry away particles through dispersion and suspension |
Oil-rust mixed soil | First disrupts oil binding, then carries away some loose particles |
Metal surface after cleaning | Reduces the risk of flash rust through silicate protection |
Sodium metasilicate is not a primary rust remover. Rather, it is an auxiliary component in metal cleaning, oil removal, rust-powder dispersion, and post-cleaning corrosion-inhibition systems.
8 Application Selection of Anhydrous, Pentahydrate, and Nonahydrate Sodium Metasilicate
8.1 Selection by Application Objective
Application Objective | Suitable Choice | Reason |
Highly concentrated strong alkaline powder | Anhydrous sodium metasilicate | High active content; large alkalinity and silicate contribution per unit mass |
Laundry powder, dishwashing powder, general cleaning powder | Sodium metasilicate pentahydrate | Balanced overall performance and good formulation compatibility |
Metal degreasing and industrial cleaning | Anhydrous or pentahydrate sodium metasilicate | Can be selected according to cleaning strength, solubility, and cost |
Systems requiring more balanced dosing and dissolution behavior | Sodium metasilicate pentahydrate, or sodium metasilicate nonahydrate after evaluation based on specifications | Hydrated forms generally offer better handling properties, but active content must be converted |
Strong saponification of heavy oily soils | Caustic soda or caustic-soda-based blended systems | NaOH provides a more direct strong alkaline effect |
8.2 Composition, Physical Properties, and Application Indicators to Consider During Selection
Indicator | Importance |
Effective Na₂SiO₃ content or calculated Na₂SiO₃ content | Reflects the amount of effective sodium metasilicate provided per unit mass of product; the core indicator for dosage conversion and cost comparison among anhydrous, pentahydrate, and nonahydrate products |
Na₂O content | Reflects the calculated alkaline component content; affects pH value, alkali reserve, oil-removal ability, and material corrosion risk |
SiO₂ content | Reflects the calculated siliceous component content; affects silicate builder function, soil dispersion, anti-redeposition, and metal surface protection |
SiO₂/Na₂O molar ratio, or Na₂O/SiO₂ composition ratio | Reflects the relative relationship between siliceous and alkaline components; affects solution alkalinity, distribution of silicate species, buffering capacity, dispersion performance, and metal surface interactions |
Water-insoluble matter | Affects clarity after dissolution, residue risk, and surface cleanliness after cleaning |
Particle size and dust | Affect dosing, dissolution rate, dust exposure, and production operation safety |
Bulk density | Affects packaging, metering, transportation, and powder-formulation volume |
Hygroscopicity and caking tendency | Affect storage stability, dosing flowability, and consistency of batch use |
pH value of a 1% aqueous solution | Reflects the actual alkalinity at a specified concentration and can be used to compare different batches or different hydrate products |
Metal compatibility | Affects the cleaning safety of aluminum, zinc, plated parts, and precision metals; confirmation through application testing is required |
Certificate of Analysis (COA) and Safety Data Sheet (SDS) | The COA is used to confirm batch composition and quality indicators; the SDS is used to confirm hazard classification, storage conditions, and protective measures during use |
9 Misconceptions to Avoid When Using Sodium Metasilicate
9.1 Misconception 1: Anhydrous, Pentahydrate, and Nonahydrate Products Can Be Replaced on an Equal-Mass Basis
The three forms cannot be replaced on an equal-mass basis. Hydrated products contain a large amount of water of crystallization, so their effective Na₂SiO₃ content per unit mass is significantly lower than that of the anhydrous product. Equal-mass replacement will change pH value, alkalinity, cleaning power, cost, and product stability.
9.2 Misconception 2: Sodium Metasilicate Is Simply a Milder Version of Caustic Soda
Sodium metasilicate is not simply a milder version of caustic soda. It is still a strongly alkaline raw material with corrosive and irritating properties. Its advantage is not that it is “milder,” but that it provides both alkalinity and silicate functionality.
9.3 Misconception 3: Because Sodium Metasilicate Has Corrosion-Inhibition Properties, It Is Safe for All Metals
Sodium metasilicate has certain corrosion-inhibition potential, but this does not mean it is safe for all metals. Aluminum, zinc, tin, plated parts, and certain alloys may corrode under strongly alkaline conditions. Actual use must be confirmed through testing based on concentration, temperature, contact time, and substrate.
9.4 Misconception 4: Sodium Metasilicate Can Serve as a Primary Rust Remover
Sodium metasilicate can assist in removing oil-rust mixed soils and loose rust powder, but it is not a typical primary rust remover. For firmly adherent rust and oxide scale, acidic, complexing, reducing, or mechanical rust-removal systems should be used.
10 Classification Tables of Representative Chemicals Related to Sodium Metasilicate and Cleaning Systems
Table 1 Metasilicates and Alkaline Cleaning Builders
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Core sodium metasilicate product | 6834-92-0 | S102095 | Anhydrous sodium metasilicate | SiO₂, 44–47% | Used for active-content conversion of anhydrous sodium metasilicate, strong alkaline building, powdered cleaning agents, metal degreasing, and research on silicate-based corrosion-inhibition systems |
Core sodium metasilicate product | 10213-79-3 | Sodium metasilicate pentahydrate | ≥95% | Used for research on the hydration structure, active content, dissolution behavior, detergent builder function, and metal-cleaning formulations of sodium metasilicate pentahydrate | |
Sodium metasilicate-related hydrate | 13517-24-3 | Sodium metasilicate nonahydrate | AR, ≥98% | Used for comparison of different sodium metasilicate hydrates, the influence of water of crystallization, effective alkalinity conversion, and dissolution behavior of hydrated salts | |
Silicate builder | 1344-09-8 | Powdered instant sodium silicate | For use as a synthetic detergent builder | Used for research on silicate building, soil dispersion, anti-redeposition, powdered detergents, and cleaner formulations | |
Silicate builder | 1312-76-1 | Potassium silicate | Liquid, modulus 3.1–3.4 | Used for research on potassium silicate systems, inorganic bonding, metal protection, alkaline cleaning, and the influence of silicate modulus | |
Strong alkaline cleaner | 1310-73-2 | S111498 | Sodium hydroxide | GR, ≥96% | Used for comparison between caustic soda and sodium metasilicate, strong alkaline degreasing, saponification reactions, pH adjustment, and corrosivity evaluation |
Strong alkaline cleaner | 1310-58-3 | Potassium hydroxide | Anhydrous grade, ≥99.95% metals basis | Used for research on strong alkaline cleaning, oil and fat saponification, liquid alkaline cleaners, and comparison of potassium-based systems | |
Alkaline builder | 497-19-8 | Anhydrous sodium carbonate | UltraBio™, anhydrous grade, ≥99.5% (T) | Used for alkalinity adjustment, detergent building, control of hard-water effects, and research on sodium metasilicate blended systems | |
Mild alkaline auxiliary | 144-55-8 | Sodium bicarbonate | Pharmaceutical grade, PharmPure™ | Used for research on alkalinity buffering, mild cleaning, acid-base neutralization, and comparison of alkaline auxiliaries | |
Phosphate alkaline builder | 7601-54-9 | Trisodium phosphate, anhydrous | ≥96% | Used for research on strong alkaline cleaning, degreasing, hard-surface cleaning, and comparison of inorganic builders | |
Amine alkaline auxiliary | 102-71-6 | Triethanolamine | Reagent grade, ≥98% | Used for research on pH adjustment, metal cleaning, corrosion-inhibition assistance, oil emulsification, and alkaline formulation stability | |
Amine alkaline auxiliary | 141-43-5 | Ethanolamine | Refined grade, ≥99.5% | Used for research on alkaline cleaning, pH adjustment, oil removal, metal cleaning, and comparison of amine-based auxiliaries |
Table 2 Chelating Agents, Complexing Agents, and Dispersing/Anti-Redeposition Auxiliaries
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Anti-redeposition auxiliary | 9004-32-4 | Sodium carboxymethyl cellulose (CMC) | Viscosity: 1000–1400 mPa·s, USP grade | Used for research on detergent anti-redeposition, soil suspension, system thickening, and synergy with sodium metasilicate cleaning systems | |
Green chelating agent | 51981-21-6 | Tetrasodium N,N-bis(carboxymethyl)-L-glutamate | Active content ≥47% | Used for research on biodegradable chelation, hard-water ion control, alkaline cleaning formulations, and metal ion sequestration | |
Hydroxycarboxylate chelating agent | 527-07-1 | Sodium D-gluconate | ≥99% | Used for research on metal ion complexation, hard-water effect control, metal cleaning, alkaline cleaners, and corrosion-inhibition assistance | |
Carboxylate chelating agent | 6132-04-3 | Sodium citrate dihydrate | AR, ≥99% | Used for research on mild complexation, buffering systems, hard-water ion control, cleaners, and descaling formulations | |
Aminocarboxylate chelating agent | 6381-92-6 | Disodium ethylenediaminetetraacetate dihydrate | GR, ≥99% | Used for research on metal ion sequestration, hard-water effect control, analytical experiments, and chelating performance in cleaning formulations | |
Aminocarboxylate chelating agent | 60-00-4 | Ethylenediaminetetraacetic acid | AR, ≥99.5% | Used as a classic chelating-agent reference and for research on metal ion complexation, hard-water control, and cleaning-system evaluation | |
Dispersant and scale inhibitor | 9003-04-7 | Sodium polyacrylate (PAAS) | Average Mw ~8000, 45% in H₂O | Used for research on soil dispersion, scale inhibition, anti-redeposition, inorganic salt deposition control, and cleaning formulation stability | |
Aminocarboxylate chelating agent | 140-01-2 | Pentasodium diethylenetriaminepentaacetate | ca. 50% in water | Used for research on efficient metal ion sequestration, alkaline cleaning, industrial cleaning, and chelation under complex water-quality conditions | |
Aminocarboxylate chelating agent | 10378-23-1 | Tetrasodium ethylenediaminetetraacetate dihydrate | AR, ≥99% (T) | Used for research on metal ion control in alkaline systems, cleaning-builder blending, and hard-water ion sequestration | |
Aminocarboxylate chelating agent | 67-43-6 | Diethylenetriaminepentaacetic acid (DTPA) | AR, ≥99% (T) | Used for research on strong chelating performance evaluation, metal ion control, industrial cleaning, and descaling systems | |
Green chelating agent | 164462-16-2 | Trisodium N-(1-carboxyethyl)iminodiacetate | ≥95% (T) | Used for research on biodegradable chelation, hard-water ion control, alkaline cleaners, and environmentally friendly builder systems |
Table 3 Phosphates, Phosphonates, and Scale-Inhibition/Corrosion-Inhibition Auxiliaries
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Phosphate builder | 7758-29-4 | Sodium tripolyphosphate | Industrial grade, ≥85% | Used as a classic builder reference and for research on hard-water ion control, detergent formulations, and sodium metasilicate blended systems | |
Phosphonate scale and corrosion inhibitor | 2809-21-4 | 1-Hydroxyethylidene-1,1-diphosphonic acid (HEDP) | Moligand™, 60% aqueous solution | Used for research on scale inhibition, complexation, corrosion inhibition, metal cleaning, and synergy with silicate-based corrosion-inhibition systems | |
Phosphate builder | 7722-88-5 | Sodium pyrophosphate | AR, ≥99% | Used for research on alkaline building, metal ion control, dispersion, and comparison of detergent builders | |
Molybdate corrosion inhibitor | 7631-95-0 | Sodium molybdate | Anhydrous grade, ≥99.9% metals basis, powder, >100 mesh | Used for research on metal corrosion inhibition, rust-prevention systems, inorganic corrosion-inhibitor references, and silicate surface-protection effects | |
Molybdate corrosion inhibitor | 10102-40-6 | Sodium molybdate dihydrate | AR, ≥99% | Used for research on hydrated molybdate corrosion inhibition, metal protection, circulating water systems, and post-cleaning rust-prevention systems | |
Phosphate dispersant | 10124-56-8 | Sodium hexametaphosphate (SHMP) | AR | Used for research on dispersion, hard-water ion control, scale inhibition, detergent building, and inorganic salt deposition control | |
Oxidizing corrosion inhibitor | 7632-00-0 | S433708 | Sodium nitrite | Anhydrous grade, high-purity, reagent grade, ≥99% | Used for research on steel corrosion inhibition, rust-prevention systems, metal surface protection, and comparison of inorganic corrosion inhibitors |
Phosphonate scale and corrosion inhibitor | 6419-19-8 | Nitrilotris(methylenephosphonic acid) | ≥95% | Used for research on scale inhibition, corrosion inhibition, metal ion control, industrial cleaning, and circulating water treatment | |
Copper corrosion inhibitor | 95-14-7 | Benzotriazole | ≥99% | Used for research on corrosion inhibition of copper and copper alloys, metal surface protection, and post-cleaning anti-discoloration systems | |
Copper corrosion inhibitor | 29385-43-1 | Methyl-1H-benzotriazole, mixture (TTA) | ≥98% (GC) | Used for research on corrosion inhibition of copper and copper alloys, water treatment, metal cleaning, and protective formulations |
Table 4 Products Related to Acidic Rust Removal, Descaling, and Metal Surface Treatment
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Strong acid rust remover | 7647-01-0 | H485680 | Fuming hydrochloric acid, 37% (regulated precursor chemical) | GR, suitable for analysis, max. 0.001 ppm Hg | Used for research on acid pickling and rust removal, dissolution of metal oxides, inorganic acid cleaning, and comparison with the rust-removal effect of sodium metasilicate |
Organic acid cleaner | 64-19-7 | Glacial acetic acid | GR, ≥99.5% | Used for research on mild acidic cleaning, light descaling, acid-base neutralization, and organic acid cleaning systems | |
Organic acid descaler | 77-92-9 | Anhydrous citric acid | AR, ≥99.5% (T) | Used for research on mild descaling, metal ion complexation, light rust cleaning, and acidic cleaning formulations | |
Organic acid rust remover | 144-62-7 | Oxalic acid, anhydrous | Anhydrous grade, ≥99% | Used for research on rust-stain cleaning, iron ion complexation, acidic rust removal, and comparison with the rust-removal effect of sodium metasilicate | |
Organic acid rust remover | 6153-56-6 | Oxalic acid dihydrate | Suitable for synthesis | Used for research on oxalic acid rust-removal systems, iron ion complexation, metal oxide treatment, and acidic cleaning | |
Acidic descaler | 5329-14-6 | Sulfamic acid | Suitable for analysis, premium grade | Used for research on scale removal, metal surface pickling, industrial descaling, and acidic cleaning systems | |
Organic acid descaler | 5949-29-1 | Citric acid monohydrate | Reagent grade, ≥98% (GC/T) | Used for research on descaling, metal ion complexation, mild acidic cleaning, and comparison of hydrate forms | |
Inorganic acid surface-treatment agent | 7664-38-2 | Phosphoric acid | HPLC grade, ≥85% | Used for research on phosphoric-acid rust removal, metal surface treatment, oxide dissolution, and acidic cleaning systems |
Table 5 Surfactants and Solubilizing Auxiliaries
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Hydrotrope | 1300-72-7 | Sodium xylene sulfonate solution | Mixture of isomers, 40 wt.% in H₂O | Used for research on solubilization in liquid cleaners, system stability, surfactant compatibility, and high-alkaline cleaning formulations | |
Anionic surfactant | 151-21-3 | Sodium dodecyl sulfate (SDS) | Anhydrous grade, ACS, ≥99% | Used for research on oil emulsification, interfacial tension reduction, foaming systems, and synergy with sodium metasilicate cleaning | |
Anionic surfactant | 25155-30-0 | Sodium dodecylbenzenesulfonate (SDBS) | Anionic active matter, 85% | Used for research on detergent cleaning, hard-surface cleaning, oil emulsification, and synergy with alkaline builders | |
Anionic surfactant | 9004-82-4 | Sodium laureth sulfate | ≥25% | Used for research on cleaning, foaming, emulsification, liquid detergents, and compatibility in alkaline systems |
Table 6 Oxidative Cleaning and Bleaching Synergy Products
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Oxidative cleaner | 7722-84-1 | H112515 | Hydrogen peroxide solution (hydrogen peroxide) (explosive precursor chemical) | AR, 30 wt.% in H₂O | Used for research on oxidative cleaning, bleaching, surface treatment, and oxidative synergy in alkaline cleaning systems |
Solid oxygen bleach | 10486-00-7 | Sodium perborate tetrahydrate | 9–11% available oxygen | Used for research on oxygen-bleach cleaning, powdered detergents, stain oxidation, and blending with alkaline builders | |
Solid oxygen bleach | 15630-89-4 | Sodium percarbonate | ≥13% active oxygen | Used for research on oxygen-bleach washing, powdered cleaners, stain oxidation, and blending with sodium metasilicate alkaline systems |
Note: The products listed above are representative Aladdin products related to scientific research and formulation studies. For more product specifications, grades, and COA information, please search by “product name/CAS/catalog number” on the Aladdin official website.
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Understanding Brij 35: A Deep Dive into Its Role as a Nonionic Surfactant
Structural Basis and Laboratory Applications of Sodium Cholate as an Anionic Biosurfactant
From Foxglove to the Lab Bench: How Digitonin Works as a Non-ionic Surfactant
Understanding n-Octyl-β-D-glucopyranoside: A Non-ionic Surfactant for Research and Biotechnology
n-Dodecyl-β-D-maltoside (DDM): Structure, Properties, and Applications as a Non-ionic Surfactant
Sodium Lauroyl Sarcosinate: Structure–Property–Application of an Amino-Acid–Based Anionic Surfactant
CTAB Demystified: Structure, Properties, and Practical Uses of a Classic Cationic Surfactant
Poloxamers Explained: A Comprehensive Guide to Non-Ionic Block Copolymer Surfactants
Tween 20 and Tween 80 as Non-Ionic Surfactants: Structure, Properties, and Applications
Saponins as Natural Non-ionic Surfactants: Structure, Function, and Applications
Non-ionic Detergents Explained: From Chemical Structure to Laboratory Use
