Classification of Surface Mount Technologies for Ceramic PCB

Classification of Surface Mount Technologies for Ceramic PCB

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Ceramic circuit boards are a new class of materials known for their high-temperature stability, excellent insulation properties, low thermal expansion coefficient, and superior processability. These characteristics make them widely used in high-temperature and high-frequency circuits, power electronics, and electromagnetic compatibility applications.

As electronic technologies continue to advance, the use of ceramic PCBs is becoming increasingly prevalent. Among their key technological aspects, surface mount technology (Пост) plays a crucial role. This article explores the classification of SMT techniques for ceramic PCBs and analyzes their prospects in the electronics industry.

Classification of Surface Mount Technologies for Ceramic PCBs

1. Thin Film Method (DPC – Direct Plated Copper)

Process: A metal seed layer is deposited on the ceramic surface using magnetron sputtering or vacuum evaporation, followed by electroplating to thicken the copper layer. Photolithography and etching are then used for circuit patterning.
Technical Features:

  • High Precision: Line width/spacing can reach 20μm, suitable for high-frequency, high-density circuits.

  • Material Compatibility: Supports substrates such as alumina (Al₂O₃) and aluminum nitride (AlN), offering excellent surface flatness.
    Типичные приложения:

  • Светодиодное освещение: High thermal conductivity (AlN substrate up to 230 W/m·K) ensures efficient heat dissipation.

  • Microwave & RF Devices: Low dielectric loss (ε_r ≈ 9) meets 5G/6G communication requirements.

2. Thick Film Method (TFC – Thick Film Ceramic)

Process: Conductive paste containing metal and glass powders is screen-printed onto a керамический субстрат and then sintered at high temperatures to form circuits.
Technical Features:

  • Cost-Effective: Simple process with low equipment costs, though line width precision is limited (≥0.1 mm).

  • Material Constraints: Conductive layer thickness is typically 10–20μm, suitable for low- to medium-power applications.
    Типичные приложения:

  • Автомобильная электроника: Used in ECUs and control modules requiring resistance to high temperatures (>150° C.) and mechanical vibration.

3. Co-fired Method (HTCC / LTCC)

High-Temperature Co-fired Ceramic (HTCC):

  • Process: Sintered at 1650–1850°C, involving multilayer ceramic green tapes printed with circuits and laminated.

  • Преимущества: High mechanical strength (flexural strength >400 MPa), ideal for aerospace applications.

Low-Temperature Co-fired Ceramic (LTCC):

  • Process: Sintered at 800–950°C; allows integration of passive components like resistors and capacitors.

  • Преимущества: Excellent high-frequency performance (Q factor >500), suitable for 5G filters.

4. Direct Copper Bonding Method (DBC / AMB)

Direct Bonded Copper (DBC):

  • Process: A Cu/O eutectic liquid phase is formed at 1065–1083°C, bonding copper foil directly to the ceramic substrate.

  • Преимущества: High thermal conductivity (Al₂O₃ substrate up to 25 W/m·K), widely used in IGBT modules.

Active Metal Brazing (AMB):

  • Process: Utilizes active solders (containing Ti, Ag) to enhance bonding strength and reliability.

  • Преимущества: Excellent thermal cycling performance (survives 1000 cycles from –55°C to 200°C without failure).

Керамическая печатная плата

Advantages of Surface Mount Technology (Пост) for Ceramic PCBs

  1. High Thermal Conductivity:
    Surface mount technology enhances the thermal performance of ceramic PCBs, improving the overall reliability and efficiency of electronic devices.

  2. Superior Wear Resistance:
    SMT improves the wear resistance of ceramic substrates, thereby extending the operational life of the equipment.

  3. High Mechanical Strength:
    SMT increases the mechanical robustness of ceramic PCBs, ensuring enhanced safety and durability of electronic systems.

  4. Environmental Friendliness:
    Ceramic PCBs with advanced SMT can reduce electromagnetic emissions, contributing to better environmental compliance and reduced interference.

  5. Гибкость дизайна:
    SMT enables more flexible design configurations, allowing ceramic PCBs to meet the varying demands of different electronic applications.

SMT Process Flow for Ceramic PCBs

The SMT process for ceramic PCBs is similar to that for traditional organic substrates, but must be optimized to accommodate the unique properties of ceramic materials:

  1. Substrate Preparation and Surface Treatment

    • Cleaning and Polishing: Remove surface contaminants to ensure flatness (surface roughness Ra < 0.1 мкм).

    • Поверхностная обработка: Use Electroless Nickel Immersion Gold (Соглашаться) or Electroless Nickel Palladium Immersion Gold (Enepic) for enhanced solderability. ENEPIG includes a palladium layer to reduceblack paddefects, making it ideal for fine-pitch components such as BGAs.

  2. Припаяная печать

    • Paste Selection: Choose high-viscosity lead-free solder paste (НАПРИМЕР., SnAgCu alloys) to prevent slump.

    • Printing Parameters: Precisely control squeegee pressure and speed to ensure consistent solder paste thickness (typically 25–75 μm).

  3. Component Placement and Reflow Soldering

    • High-Speed Placement Machines: Must be adapted for the rigidity of ceramic substrates to minimize mechanical stress.

    • Reflow Profile: Use a stepped temperature ramp to mitigate stress from mismatched thermal expansion between ceramic and components. Peak temperature should be maintained between 240–260°C. Nitrogen atmosphere is preferred to reduce oxidation.

  4. Inspection and Rework

    • Аои (Автоматическая оптическая проверка): Used to check solder paste quality and component alignment.

    • Рентгеновский осмотр: Essential for bottom-terminated components like BGAs, to detect voids in solder joints.

    • Rework Process: Utilize localized heating platforms with ±2°C accuracy to prevent damage to adjacent components.

Заключение

The classification of surface mount technologies for ceramic PCBs must consider a combination of process capability, material properties, and end-use application. Current trends are moving toward ultra-fine precision (line widths <10 мкм), high-frequency performance (5G+), and eco-friendly practices (lead-free and recyclable). Innovations such as 3D Печать and laser activation are emerging as key enablers. Material choices must balance performance with cost efficiency.

With the rapid rise of industries such as new energy vehicles and 5G communications, demand for ceramic PCBs is expected to grow steadily. Future technological advancements will focus on cross-disciplinary integration and intelligent manufacturing.