Titanium Dioxide Segregation in Water-Based Pigments: Causes and Solutions

Titanium Dioxide Segregation in Water-Based Pigments: Causes and Solutions

In the coatings, inks, and building materials industries, water-based pigments are widely used due to their environmental and safety advantages. Titanium dioxide, as a core white pigment, is a key component of water-based pigments due to its excellent hiding power and whiteness. However, in actual use, titanium dioxide stratification is a common problem plaguing the industry—after a period of storage, a clear liquid appears on the top layer of the pigment, while a hard precipitate forms at the bottom. This not only affects color uniformity but also leads to difficulties in application and a decline in product quality. This phenomenon is not accidental but the result of multiple factors working together. Identifying the root cause allows for targeted solutions.

I. Core Causes of Titanium Dioxide Segregation

1. Density Difference: A “Natural Hidden Danger” of Gravity

The density of titanium dioxide is much higher than that of water and water-based resin systems (rutile titanium dioxide has a density of approximately 4.2 g/cm³, anatase approximately 3.9 g/cm³, while water has a density of only 1 g/cm³). According to the principles of physics, density differences cause titanium dioxide particles to gradually settle downwards under the influence of gravity. This density difference is an inherent factor in sedimentation; without sufficient stabilizing mechanisms to counteract the effects of gravity, stratification will inevitably occur.

2. Particle Agglomeration: A Direct Cause of Dispersion Failure

Ideally, titanium dioxide should be uniformly dispersed in an aqueous system as monodisperse particles of nanometer or micrometer size. However, in actual production, strong van der Waals forces and hydrogen bonds exist between titanium dioxide particles. If dispersion is insufficient, small particles will adsorb each other to form large agglomerates. According to Stokes' law, particle settling velocity is proportional to the square of the particle size—agglomerated particles have significantly larger sizes, and the settling velocity increases geometrically, eventually settling rapidly to the bottom.

3. Inappropriate Dispersant Selection: A Key Deficiency in Stabilizing the System

In aqueous systems, the dispersant is crucial for maintaining stable dispersion of titanium dioxide. The dispersant adsorbs onto the surface of titanium dioxide particles, forming an electric double layer or steric barrier, preventing particles from agglomerating. If the dispersant has poor compatibility with titanium dioxide, insufficient adsorption capacity, or is added in too small a quantity, an effective stable barrier cannot be formed: After the double layer is damaged, the electrostatic repulsion between particles weakens; when steric hindrance is insufficient, particles easily break through the "protective layer" and collide and agglomerate, ultimately leading to sedimentation.

4. Titanium Dioxide Surface Characteristics: An Inherent Shortcoming of Hydrophilicity and Hydrophobicity

Titanium dioxide is essentially a hydrophobic inorganic powder, while water is the dispersion medium for water-based pigments. If titanium dioxide has not undergone surface modification, or the modification effect is poor (e.g., incomplete coating, poor hydrophilicity of the coating layer), its surface cannot form a stable bond with water molecules. Instead, it will aggregate due to "hydrophobic interaction," forming large flocculent particles and accelerating sedimentation. Furthermore, the number and charge properties of the hydroxyl groups on the surface of titanium dioxide also affect the adsorption effect with the dispersant, further exacerbating stability problems.

5. System Environmental Imbalance: External Factors Fueling the Situation

The system parameters of water-based pigments are crucial to their stability: First, low viscosity. Insufficient viscosity prevents the formation of sufficient "resistance" to slow particle sedimentation, making particles like "pebbles in thin porridge" sink more easily. Second, unsuitable pH. Titanium dioxide exhibits optimal stability in a neutral to slightly alkaline environment (pH 7-9). Acidic or alkaline conditions disrupt the adsorption state of the dispersant and the surface charge of the titanium dioxide, leading to agglomeration. Third, improper storage conditions. High temperatures, violent vibrations, or prolonged static storage accelerate particle movement and agglomeration, inducing sedimentation.

II. Practical Solutions for Titanium Dioxide Segregation

To address the above issues, a comprehensive approach is needed, focusing on "source control, process optimization, and system stability," to build a stable water-based pigment system:

1. Optimizing Dispersion Process: Breaking Agglomeration and Refining Particle Size

Dispersion is fundamental to resolving sedimentation; the core is to break up titanium dioxide agglomerates into monodisperse particles. In production, a combined process of "high-speed dispersion + sand milling" can be adopted: first, large agglomerates are initially dispersed using a high-speed disperser (1500-3000 r/min), and then finely ground using a sand mill (medium particle size 0.3-1.0 mm) to control the titanium dioxide particle size within the 1-5 μm range (optimal dispersion range), reducing the "power" for gravity sedimentation. Temperature must be controlled during grinding (avoid exceeding 60℃) to prevent dispersant failure.

2. Scientific Selection of Dispersants: Precise Matching, Building a Strong Barrier

The selection of dispersants should follow the principle of "compatibility first, functional complementarity": Prioritize dispersants that match the surface charge of titanium dioxide: anionic dispersants (such as polycarboxylate and naphthalenesulfonate formaldehyde condensate) can form a strong electric double layer on the titanium dioxide surface, with strong electrostatic repulsion; nonionic dispersants (such as polyether and polyvinyl alcohol) can form steric hindrance and have good acid and alkali resistance. Combining both can balance stability and compatibility. Controlling the amount of dispersant added: Generally, it is 0.5%-3% of the titanium dioxide mass. Too little will not form a complete adsorption layer, while too much will lead to abnormal system viscosity. The optimal amount needs to be determined experimentally (based on the finding that the pigment paste shows no significant sedimentation after 30 days of standing).

3. Optimal selection of titanium dioxide type: Improving dispersion stability from the source.

 Selecting surface-modified titanium dioxide is key: Prioritize water-based titanium dioxide with alumina or silica coating. The coating layer can improve the hydrophilicity of the particles and reduce hydrophobic agglomeration. At the same time, pay attention to the "dispersibility indicators" of the titanium dioxide (such as oil absorption and particle size distribution), selecting products with moderate oil absorption (20-30g/100g) and narrow particle size distribution to reduce the risk of sedimentation from the source.

4. Adjusting System Parameters: Establishing a Stable Dispersion Environment

**Moderately Increase System Viscosity:** Add water-based thickeners (such as hydroxyethyl cellulose or polyurethane thickeners) to control the pigment paste viscosity between 500-2000 mPa·s (rotational viscometer at 60 r/min). This increases the resistance of the dispersion medium, slowing particle settling, but excessive viscosity must be avoided to prevent affecting the flowability during application.

Adjust pH to a Stable Range: Add adjusters such as ammonia or triethanolamine to control the pigment paste pH between 7-9. At this pH, the surface charge of titanium dioxide is stable, and the dispersant adsorption effect is optimal.

Control System Solid Content: Excessive solid content increases the probability of particle collision, while insufficient solid content results in insufficient viscosity. Generally, a solid content of 30%-50% is ideal, balancing stability and workability.

5. Standardized Storage and Use: Minimizing the Impact of External Factors

Storage should adhere to the principles of "low temperature, protection from light, and sealing," with the ambient temperature controlled between 5-35℃. Avoid direct sunlight and high-temperature exposure. Pigment containers should be placed upright and gently stirred periodically (every 7-15 days) to prevent particle agglomeration due to prolonged static conditions. Before use, thoroughly stir until homogeneous. If slight sedimentation has occurred, homogeneity can be restored by low-speed stirring (300-500 rpm). Severe sedimentation requires re-grinding and dispersion.

III. Summary

The stratification and sedimentation of titanium dioxide in water-based pigments is essentially the result of the combined effects of "gravity, particle agglomeration, and system instability." Solving this problem does not rely on a single method but should involve a complete chain of control: "selection - dispersion - system - storage." This includes selecting modified titanium dioxide at the source, refining particle size through optimized dispersion processes, building a stable barrier with suitable dispersants, and reducing external interference by adjusting system parameters and standardizing storage. By precisely controlling each step, we can effectively suppress the sedimentation of titanium dioxide, ensure the storage stability and performance of water-based pigments, and safeguard the quality of downstream products.