Optical and optoelectronic (OE) devices are being rapidly integrated into many facets of everyday life. From telecommunications to sensor applications, these devices are expected to perform accurately and reliably for long periods of time.

Figure 1. Laser-fiber coupler schematic.
Common optoelectronic components such as drop/add filters, fiber amplifiers, variable optical amplifiers (VOAs), and Vertical-External-Cavity Surface-Emitting-Lasers (VECSELs) are used in dense wavelength division muliplex (DWDM) telecom infrastructure. As the functionality of these devices increases, the number of new materials used also increases. In all of these cases, the materials must be put together in a specific design and packaged to ensure reliability and function. The assembly normally includes bonding at the interfaces of the various materials. Typically, the bonding is done with adhesives or with solders; however, both of these approaches have their shortcomings.

Figure 2. Strained fiber Bragg grating mounted onto temperature compensator.
Organic-based adhesives can join a variety of materials, but often lack the long-term stability required for optoelectronic components. On the other hand, solders are mechanically more robust, but not capable of bonding to some materials without surface preparation such as metallization or flux. Optical/optoelectronic components can comprise a number of different materials. In addition to SiO2, ceramics, optically transparent materials (e.g. LiNbO3, MgF2, CaF2, ZnSe, and ZnS) and heat sink substrates (e.g. diamond and SiC) are used. Traditional solder cannot bond to these materials and there is a need for a more universal solder.

The use of reactive solders, which are capable of bonding to a host of materials, is described below, as well as the function and advantages of the solder in two integrated photonic devices.

Value in the Package

Long-term stability in packaging and assembly is critical to the performance of optical/optoelectronic devices. Gradual misalignment of optical components over time can lead to reduced signal strength or a complete loss of transmission intensity (i.e. device failure). As such, a robust solution is required to prevent such catastrophic losses.

While Nobel prizes typically go to groundbreaking basic scientific research and businesses get excited about new optical disc formats, scientists and engineers understand that their financial future often rests on the mundane topics of assembly, packaging, and interconnection of components and systems. So, while new bonding technologies may not receive the fanfare of discoveries in spintronics or lasers, being aware of the latest bonding methods and materials is often the difference between success and failure.

Reactive Solder

From Canada balsam and sealing wax to direct diffusion, the range of bonding materials (and bonding without added material) is vast. Adhera Technologies and the Fiber Optic Center have focused on materials (AdherAlloy) that look like solder and stick to ceramics like frit glass.

Metallic bonding can offer several advantages over conventional polymer-based adhesives. These include:

  • Strength — in tension, compression, shear
  • Stability — dimensional constancy, low creep, nil internal stress
  • Inertness/hermeticity — nil outgassing or permeability
  • Thermal/electrical conductivity — superior to adhesives

As stated earlier, most solders require pre-treatment such as etching/metallization in order to form a useful joint; with fluxing and post-cleaning, a single bond may require many costly and yield-reducing process steps and inspections. A potentially more efficient approach is to use reactive solders that bond directly to most metals, ceramics, diamond, and other materials without pre-treatment beyond simple cleaning.