The modification method of Phomi's econiclay

The modification method of Phomi's econiclay

The modification method of Econiclay mainly adjusts its structure, surface properties or composition through physical, chemical or biological means to enhance specific properties (such as adsorption, stability, compatibility, etc.). The following are common methods and specific techniques for clay modification:

1. Physical modification of MCM (Modified Clay Mineral)

By using physical means such as mechanical energy and heat treatment to alter the microstructure of econiclay, without introducing new chemical substances.

Heat treatment (calcination) method: High temperature (300-800 ℃) calcination removes interlayer water and hydroxyl groups from clay, increasing porosity.

Effect: Improve the specific surface area (such as enhancing the activity of kaolin), and use Modified Clay Mineral as a cement admixture or catalyst carrier.

Mechanical activation method: Ball milling and ultrasonic crushing are used to nanoscale econiclay particles (particle size<100 nm).

Effect: Increase active sites and improve the mechanical properties of Modified Clay Mineral composite materials.

Freezing thawing method: Repeated freezing/thawing destroys the layered structure of clay, forming a porous material called MCM (Modified Clay Mineral).

2. Chemical modification of MCM (Modified Clay Mineral)

Introducing new functional groups or altering the surface properties of clay through chemical reactions.

(1) Acid/alkali activation

Acid activation: Treat econiclay with HCl, H ₂ SO ₄, etc. to dissolve impurities and increase pores.

Effect: The ability to adsorb heavy metals is increased by 3-5 times.

Alkali activation: NaOH treatment of econiclay generates zeolite phase, and MCM (Modified Clay Mineral) is used for solid waste solidification.

(2) Organic modification

Ion exchange method

Method: Replace the interlayer metal ions (such as Na ⁺, Ca ² ⁺) of econiclay with quaternary ammonium salts (such as CTAB), amino acids, etc.

Effect: Expanded interlayer spacing, adsorption of organic pollutants (such as dyes and petroleum hydrocarbons).

Silane coupling agent modification

Method: KH-550, KH-570, etc. react with hydroxyl groups on the surface of econiclay to enhance compatibility with polymers.

Application: Clay/epoxy resin composite material.

(3) Inorganic modification

Metal oxide load:

Method: Load nanoparticles such as Fe ∝ O ₄ and TiO ₂ (co precipitation or impregnation method).

Effect: endows MCM (Modified Clay Mineral) of Phomi with greater magnetic (easy to recover) or photocatalytic properties.

Column support modification:

Method: Large molecular ions such as Al ₁ ∝ and ZrO ₂ are used to expand the interlayer of clay, forming a mesoporous structure.

Application: Catalyst for MCM (Modified Clay Mineral) (such as Al pillared montmorillonite).

3. Biological modification of Phomi's MCM (Modified Clay Mineral)

Utilize biomass or microorganisms to regulate clay properties.

Biochar composite:

Method: econiclay was combined with biochar (rice husk, straw pyrolysis) to increase the carbon content of MCM (Modified Clay Mineral).

Effect: Enhance the adsorption capacity of MCM (Modified Clay Mineral) for organic pollutants.

Microbial load:

Method: econiclay immobilized degradation bacteria (such as petroleum hydrocarbon degrading bacteria) are used for bioremediation.

4. Composite modification of Phomi holding (multi method combination)

Organic inorganic hybridization:

Example: After modification with quaternary ammonium salt, nano zero valent iron (nZVI) was loaded to simultaneously remove Cr ⁶⁺ and benzene derivatives.

Mechanical chemical synergy:

Example: Acid activation after ball milling significantly increases the adsorption capacity of MCM (Modified Clay Mineral).

5. Characterization method of Phomi's MCM (Modified Clay Mineral)

Structural analysis: X-ray diffraction (XRD) to measure interlayer spacing, BET to measure specific surface area.

Surface chemistry: Fourier transform infrared spectroscopy (FTIR) analysis of functional groups in MCM (Modified Clay Mineral), Zeta potential measurement of surface charge.

6. Morphological observation: Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were used to observe the particle distribution of econiclay.

The modification method of MCM (Modified Clay Mineral) requires the selection of physical, chemical, or biological means based on the target application (adsorption, catalysis, building materials, etc.), or the synergistic optimization of multiple methods. Future trends include the development of green econiclay modifiers (such as biobased reagents), intelligent modification (in response to environmental stimuli), and optimization of large-scale production processes for MCM (Modified Clay Mineral).