Resonator materials

Ultrasonic resonators require special materials (called "acoustic materials").

Requirements

The following factors may be important, depending on the application.

1. Fatigue resistance. Most ultrasonic resonators fail by fatigue cracking. Materials with high fatigue strength can be run at high stress levels (higher amplitudes).
2. Loss. Materials with low loss can be run at high amplitudes without generating excessive heat. Materials with high loss must be run at lower amplitudes, at lower duty cycles, or with increased cooling. Otherwise, the frequency of the stack may drift downward until the power supply can no longer drive the stack. Additionally, materials with high loss consume energy that would otherwise be available for the intended application.
3. Cavitation resistance. Resonators that are immersed in liquids will experience cavitation erosion if the amplitude is high enough. Harder materials generally have better cavitation resistance.
4. Wear resistance. Resonators that rub against other materials may experience wear. Harder materials generally have better wear resistance.
5. Impact resistance (toughness). For inserting. Not the same as hardness, since may be hard on surface but soft underneath.
6. Chemical resistance. for chemical processing, resonators that need to be cleaned with caustics (food processing installations), medical devices (saline irrigation, body fluids; dental tools with irrigation/cooling).
7. Yield strength. High yield strength is desirable to reduce deformation for impact-type applications (e.g., inserting) and where static stresses may be high (e.g., on threads).
8. Repeatable modulus of elasticity (E). The modulus of elasticity (which, in part, determines the wave speed) should be repeatable among different lots of material. Otherwise, the tuned dimension of the resonator will not be consistent.
9. Thermal conductivity. Thermal conductivity should be high where heat transfer must be maximized (e.g., in a front driver that transfers heat from the piezoelectric ceramics and in certain plastic welding applications where heat must be transferred from the part). In some cases thermal conductivity should be low (e.g., to minimize heat transfer from the load to the piezoelectric ceramics).
10. Biological compatibility. This is a requirement for surgical instruments.
11. Machinability. This is the ease with which the material can be machined.
12. Safety. Some materials (such as beryllium) pose health risks if improperly machined.
13. Availability.
14. Cost.

Material for horns and boosters

The following table shows some common resonator materials and their characteristics. Click the material name for additional information.

Material	Characteristics	Typical uses
Titanium	Fatigue resistance ----------------------------------------------------------- High Loss ----------------------------------------------------------- Moderate Cavitation resistance ----------------------------------------------------------- Moderate Wear resistance ----------------------------------------------------------- Moderate Impact resistance ----------------------------------------------------------- Moderate Chemical resistance ----------------------------------------------------------- Depends Yield strength ----------------------------------------------------------- Moderate Repeatable modulus E ----------------------------------------------------------- Moderate Thermal conductivity ----------------------------------------------------------- Low Biological compatibility ----------------------------------------------------------- High Machinability ----------------------------------------------------------- Moderate Cost ----------------------------------------------------------- High	High amplitude horns for plastic and metal welding Medical probes Liquid processing Horns in the food industry High gain boosters
Aluminum	Fatigue resistance ----------------------------------------------------------- Moderate Loss ----------------------------------------------------------- Low Cavitation resistance ----------------------------------------------------------- Low Wear resistance ----------------------------------------------------------- Low Impact resistance ----------------------------------------------------------- Low Chemical resistance ----------------------------------------------------------- Depends Yield strength ----------------------------------------------------------- Moderate Repeatable modulus E ----------------------------------------------------------- High Thermal conductivity ----------------------------------------------------------- High Biological compatibility ----------------------------------------------------------- Low Machinability ----------------------------------------------------------- High Cost ----------------------------------------------------------- Low	Horns (particularly larger horns) Boosters Transducer front drivers
Tool steel	Fatigue resistance ----------------------------------------------------------- High Loss ----------------------------------------------------------- High at high stress Cavitation resistance ----------------------------------------------------------- High Wear resistance ----------------------------------------------------------- High Impact resistance ----------------------------------------------------------- High Chemical resistance ----------------------------------------------------------- Depends Yield strength ----------------------------------------------------------- High Repeatable modulus E ----------------------------------------------------------- High Thermal conductivity ----------------------------------------------------------- Moderate Biological compatibility ----------------------------------------------------------- Low Machinability ----------------------------------------------------------- Moderate Cost ----------------------------------------------------------- Moderate	Inserting Soldering Metal welding
Stainless steel	Fatigue resistance ----------------------------------------------------------- Moderate Loss ----------------------------------------------------------- High at high stress Cavitation resistance ----------------------------------------------------------- High Wear resistance ----------------------------------------------------------- High Impact resistance ----------------------------------------------------------- High Chemical resistance ----------------------------------------------------------- Depends Yield strength ----------------------------------------------------------- High Repeatable modulus E ----------------------------------------------------------- Moderate Thermal conductivity ----------------------------------------------------------- Moderate Biological compatibility ----------------------------------------------------------- Low Machinability ----------------------------------------------------------- Moderate Cost ----------------------------------------------------------- Moderate	Block horns, especially where tips are to be brazed to the horn Some medical probes
Brass	Tunes significantly shorter than most acoustic materials.	Horns where tips are to be soldered to the horn
Ceramic	Brittle	High temperature applications
Ferro-Tic		Horns subjected to high wear

The above table assumes that the materials have been heat treated (as appropriate) for the best properties.

Notes:

1. For titanium and aluminum, the loss increases approximately with the square of the stress (amplitude). For most other materials the loss increases substantially faster. Thus, while these other materials may perform acceptably at lower amplitudes, their loss may be excessive at higher amplitudes.
2. Most acoustic metals have a wave speed near 5000 m/sec (about 200,000 inches/sec). However,  copper-based materials (e.g., brass) have substantially lower wave speeds.

Material for transducers

In addition to the above materials, the following may be used as component parts for transducers.

• Piezoelectric ceramics
• Ferromagnetic materials - nickel, Premendur
• Electrode materials - nickel, brass, beryllium copper, copper
• Insulators - Macor
• Tungsten

Materials for wear or appearance

Except for D-gun and carbide, the following have thin layers and don't affect tuning.

• D-gun
• Carbide
• Chrome
• Nickel
• Anodize

Test methods

Click here for test methods.