Cerium Hydroxide

Cerium Hydroxide Properties

High Purity cerium hydroxide Specification

Particle Size(D50)  As Requirement

What is Cerium Hydroxide used for?

As an expert in metal compound research, I will combine the chemical properties of cerium hydroxide (Ce(OH)₄) to systematically explain its key applications in high-tech and industrial fields, and deeply analyze its mechanism of action: 

1. Petroleum refining: Fluidized catalytic cracking (FCC) catalyst core additive
Core role: As a multifunctional modifier of molecular sieves (such as Y-type zeolite) in FCC catalysts.
Mechanism of action:
Heat stabilizer: Ce(OH)₄ is converted into CeO₂ by roasting, and anchors the zeolite framework aluminum through the "oxygen vacancy buffer effect", inhibiting the structural collapse under high-temperature regeneration (>700℃) conditions.
Metal passivator: Captures heavy metals such as Ni and V in crude oil (forming CeNiO₃/CeV₂O₇), prevents its catalytic dehydrogenation reaction, and reduces the coke/hydrogen yield.
Sulfur transfer agent: Ce³⁺/Ce⁴⁺ redox cycle promotes the conversion of SOₓ into renewable sulfate, reducing flue gas sulfur emissions (SOₓ → Ce₂(SO₄)₃).
Industrial value: Increase catalyst life by 15-30%, increase production of high-octane gasoline, and reduce regeneration energy consumption.

2. Automobile exhaust purification: key component of three-way catalyst (TWC)
Core function: Nano CeO₂-ZrO₂ solid solution (CZO) generated by thermal decomposition is the oxygen storage material (OSC) of TWC.
Action mechanism:
Dynamic oxygen buffering: Ce⁴⁺ + 2e⁻ ⇌ Ce³⁺ + ½O₂, quickly release/absorb oxygen under lean/rich conditions, and widen the air-fuel ratio window (λ≈1).
Precious metal dispersion carrier: High specific surface area CeO₂ improves Pt/Pd/Rh dispersion and enhances CO/HC oxidation and NOₓ reduction activity.
Enhanced thermal stability: Zr⁴⁺ doping inhibits CeO₂ sintering (>1000℃) and maintains OSC life.
Performance indicators: CZO accounts for 20-30% of modern TWC, achieving >99% pollutant conversion rate.

3. Precision optical polishing: high-end polishing powder precursor
Core process: Ce(OH)₄ is calcined and graded to prepare highly active CeO₂ polishing powder.
Mechanism of action:
Chemical-mechanical synergistic polishing: CeO₂ reacts with SiO₂ on the glass surface to form easily removable Ce-O-Si bonds, reducing mechanical damage.
Nanoscale cutting: Single crystal/spherical CeO₂ particles (particle size 50-500nm) achieve sub-angstrom surface roughness (Ra<0.5nm).
Application areas:
Semiconductors: Silicon wafers, sapphire substrate, CMP polishing
Display panels: LCD/OLED glass substrates, protective cover
Optical devices: Camera lenses, photolithography machine lenses

4. Special glass and enamel: functional modification additives
Key functions:
UV cutoff agent: Ce⁴⁺ strongly absorbs in the ultraviolet region (200-350nm) to protect the contents (pharmaceutical glass, art packaging).
Shading agent/colorant: Works with TiO₂ to produce a milky effect (enamel); controls the ratio of Ce³⁺/Ce⁴⁺ to adjust the yellow tone (Ce³⁺: blue light absorption; Ce⁴⁺: yellow light absorption).
Radiation-resistant glass: Ce³⁺ captures electron-hole pairs generated by X-rays and inhibits glass discoloration (nuclear power plant observation window).
Technical advantages: Replaces traditional As₂O₃ clarifier and complies with environmental regulations.

5. Industrial catalysis: Styrene production enhancer
Application process: Ethylbenzene dehydrogenation to produce styrene (Fe₂O₃-K₂O-Cr₂O₃ catalyst system).
Mechanism of action:
Potassium migration inhibitor: CeO₂ fixes K⁺ ions to prevent the loss of active components at high temperatures (600°C).
Redox promoter: Ce³⁺/Ce⁴⁺ cycle accelerates catalyst regeneration and inhibits carbon deposition (C + 4Ce⁴⁺ → CO₂ + 4Ce³⁺).
Structural stabilizer: Improves Fe₂O₃ phase change tolerance and extends catalyst life by 2-3 times.
Economic benefits: Improves styrene selectivity to 92-95% and reduces steam consumption by 30%.

6. Metal corrosion protection: Intelligent corrosion inhibitor
Innovative mechanism:
Self-healing film formation: Ce³⁺ is oxidized to Ce(OH)₃/CeO₂ deposition film (thickness 50-200nm) in the cathode area to block oxygen diffusion.
Local pH regulation: OH⁻ releases neutralize acidic corrosion products (such as Fe²⁺ → FeOOH).
Anodic passivation: Generates a Ce-oxide/hydroxide passivation layer on the surface of Al/Zn/Mg alloy.
Application scenarios: Aviation aluminum alloy (AA2024), shipbuilding steel, automotive galvanized sheet coating additives.

7. Environmental remediation: High-efficiency water treatment agent
Multi-functional application:
Phosphorus removal agent: Ce³⁺ and PO₄³⁻ form insoluble CePO₄ (Ksp=10⁻²³), deep phosphorus removal to <0.1mg/L.
Fluorine removal agent: Generates CeF₃ colloid (Ksp=10¹⁶), with an adsorption capacity of 80mg F⁻/g.
Radioactive nuclide fixation: Has strong coordination ability for UO₂²⁺, TcO₄⁻, etc. (Kd>10⁴ mL/g).
Green Advantages: No toxic byproducts, and the amount of sludge is only 1/3 of aluminum salt/iron salt.

8. High-end cerium salt synthesis precursor
Derivative high-purity products: