Aluminum Nitride (AlN) is a covalent compound with a hexagonal wurtzite crystal structure, characterized by lattice constants of a = 0.3110 nm and c = 0.4978 nm. In this structure, aluminum (Al) atoms are arranged in a hexagonal close-packed configuration, while nitrogen (N) atoms occupy half of the tetrahedral interstitial sites, forming distorted [AlN₄] tetrahedra—with an Al-N bond length of 0.1917 nm along the c-axis and 0.1885 nm in the other three directions. High-purity AlN ceramics are theoretically colorless and transparent, but in practice, they often appear grayish-white or light yellow due to impurities.

 

 

This wurtzite-type covalent crystal, based on [AlN₄] tetrahedral frameworks, has a density of 3.26 g/cm³ and decomposes at 2480°C under ambient pressure. The ceramic material exhibits the following advantageous properties:

①High mechanical strength at room temperature (gradually decreasing with rising temperature)

②Exceptional thermal conductivity

③Low dielectric constant and loss

④Small thermal expansion coefficient

⑤Excellent chemical inertness and biocompatibility

⑥Powder Synthesis Methods

 

The superior performance of AlN ceramics stems from high-quality AlN powder, which can be prepared via various techniques:

①Direct nitridation

②Carbothermal reduction

③High-energy ball milling

④Self-propagating high-temperature synthesis (SHS)

⑤In-situ reaction synthesis

⑥Plasma-assisted chemical vapor deposition (CVD)

⑦Solvothermal synthesis

⑧Organometallic salt decomposition

 

 

Forming Techniques

Ceramic forming processes are categorized into two main approaches:

(1) Dry forming (suitable for simple shapes and high-cost products):

Conventional die pressing

Cold isostatic pressing (CIP)

(2) Wet forming (suitable for complex geometries and low-cost mass production):

Tape casting

Slip casting

Injection molding

Gel casting

Sintering Methods

Sintering with additives

Spark plasma sintering (SPS)

Microwave sintering

Pressureless sintering

 

 

Applications

Thanks to its high volume resistivity, insulation strength, thermal conductivity, and low dielectric loss, AlN ceramics are widely used in:

Insulating  AlN substrates for high-power semiconductor devices

Heat dissipation AlN substrates for ultra-large-scale integrated circuits (ULSIs)

Surface acoustic wave (SAW) devices in high-frequency signal processors (leveraging its high acoustic velocity) High-temperature AlN crucibles (1300–2000°C) (due to excellent thermal stability)

 

 

Current Research Focus

Efforts are concentrated on:

Reducing synthesis costs for high-purity powders

Achieving low-temperature densification sintering

Stabilizing high-quality tape-cast substrates

If these technical challenges can be overcome, AlN ceramics will see broader adoption in microelectronics and other high-tech industries.

 

About Xiamen Juci Technology Co., Ltd.

Xiamen Juci Technology Co., Ltd. is a high-tech enterprise specializing in the research, development, production, and sales of high-performance ceramic materials. As a leading AlN powder manufacturer, the company is committed to providing high-quality aluminum nitride series products and solutions for industries such as electronics, semiconductors, and aerospace. With exceptional quality and service, Xiamen Juci has earned widespread trust from global customers.

 

Media Contact:
Xiamen Juci Technology Co., Ltd.

Phone: +86 592 7080230
Email: miki_huang@chinajuci.com

Website: www.jucialnglobal.com