Method of forming a laser circuit having low penetration...

Details Method of forming a laser circuit having low penetration... Method of forming a laser circuit having low penetration...

2000-04-07

2003-04-29

Niebling, John F. (Department: 2812)

Semiconductor device manufacturing: process

Coating with electrically or thermally conductive material

To form ohmic contact to semiconductive material

C438S098000, C438S473000, C438S476000, C438S602000, C438S603000, C438S604000, C438S605000, C438S606000, C438S607000, C438S608000, C438S609000

Reexamination Certificate

active

06555457

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to the field of ohmic contacts for semiconductor electronic devices and, more particularly, to a low-penetration ohmic contact providing a gettering function to remove impurities from semiconductor devices and to a method of forming it.
2. Description of the Related Art
In recent years, communications systems have been developed in many parts of the world that take advantage of optical fiber technology to increase the speed of information transfer. Demand for ever-higher information transfer rates has resulted in pressure to advance the state of the art of optoelectronic communications technology, including the design and manufacturing of semiconductor lasers.
Semiconductor lasers are the power sources for optoelectronic communications. They transform electronic signals into light with specific properties of intensity and spectral purity designed to allow for transmission of information over optical fiber networks. Although prior art semiconductors most commonly employed the elements Si and Ge, listed in Group IV of the Periodic Table, other materials, such as intermetallic compounds, have also been found to exhibit properties useful in the formation of semiconductor lasers.
Modern semiconductor lasers are precision devices in which many layers of semiconductors are used to control the flow of current and light. The device may have as many as twenty or more semiconductor substructures and require up to 4 or 5 crystal growth steps. The active region of the laser, the area in which the conversion of electrons and holes to photons occurs, may be made up of a number of substructures called quantum wells, some of which may be only 10 atoms thick.
In order to provide high efficiency of conversion of electrical to optical power, the electrical fields inside the active region should be controlled. This implies a high degree of control of the dopant impurities in the neighborhood of the active region. Impurities deliberately introduced into the semiconductor to modify the carrier density and control conductivity type should be controlled with respect to position and density to a high degree of spatial precision—a few nanometers (nm).
The contact metallization, or the part of the laser that interfaces with the outside world to provide chemical barriers and electrical contacts, has generally received less attention in design efforts than the active region itself. Designs for the contact structure have been nearly frozen for a long time. However, in recent years it has become apparent that the control of dopant diffusion into the active region requires that the other layers be optimized with respect to thickness and doping density. This has in turn placed additional requirements on the contact metallization, or ohmic contact.
Ohmic contacts to semiconductor devices are the point at which the outside world in the form of electricity flowing in wires influences the semiconductor. In addition to the obvious function of conducting electricity, ohmic contacts provide chemical isolation of the active region from impurities that can affect device performance. These impurities are often generated by further processing of the device during manufacturing or during normal usage. Ohmic contacts also provide an important path for heat to escape from the active region, and they may also be required to provide mechanical isolation of the device during bonding processes. To perform these functions, the contact structure applied to the semiconductor may be comprised of many layers, all of which should be compatible with each other and with the semiconductors and other elements of the device.
In modern ohmic contacts, the ohmic function is provided by one or a few layers of metal and the other functions (chemical barrier, mechanical protection, etc.) are provided by other layers specifically aimed at those purposes. Ohmic metallization recipes of the “alloyed” type incorporate a solvent metal such as Au which reacts strongly with the semiconductor and a dopant element such as Sn or Ge for N-type III-V materials and Be or Zn for P-type materials. The purpose of the solvent is to break up the semiconductor and form a strong physical bond. The purpose of the dopant is to increase the concentration of acceptors or donors in the immediate neighborhood of the interface and thereby reduce the contact resistance. Such an “alloyed” ohmic contact recipe is primarily designed to optimize contact resistance.
The classic ohmic contact used in many current optoelectronic devices is produced using an alloyed ohmic contact recipe and consists of Au and Be. This contact is used for P-type materials and consists of an alloy of Au and Be which is evaporated as a single film from a source of mixed metal. The Au is a solvent and the Be a P-type dopant. The vapor pressures of Au and Be are similar enough to allow material of essentially constant composition to be applied by physical evaporation, typically in an vacuum chamber at pressures below 5×10
−7
Torr using an electron-beam gun as a power source. The AuBe alloy is applied to the semiconductor through a patterned photoresist mask and the excess metal lifted off when the photoresist is dissolved in acetone. The AuBe layer is then annealed (heated) at a temperature of 350-420 degrees Celsius to form the metallurgical bond and other metal layers are applied in subsequent fabrication steps to form the protective barrier and mechanical bond layers.
At the end of the complete metallization process, the metals in the stack may comprise up to 5 microns of metal in 7 to 10 distinct layers. For example, a typical metallization might have the sequence: AuBe\Ti\Pt\Au\Au\Pt\Au (i.e., AuBe is first deposited, Ti is deposited on the AuBe, Pt is deposited on the Ti, etc.), in which the AuBe layer functions as the ohmic contact interface to the semiconductor, the sequence Ti\Pt\Au functions as the barrier metallization for chemical protection, and the sequence Au\Pt\Au functions as the bonding layer for mechanical protection. It is desirable to use Au as a final layer of a metal sequence which will be exposed to air or processing materials. This is because Au is the least reactive and most easily cleaned metal.
Between the semiconductor and the metal layers, a layer of low-bandgap, lattice-matched semiconductor is often applied as the final “cap layer” interface to reduce the Schottky barrier height and further facilitate the contact. In the case of the InGaAsP alloy system, the lattice-matched material is InGaAs. An additional benefit of using InGaAs as the cap layer is that it has a higher solubility for the preferred P-dopant Zn than does InP.
However, the use of an InGaAs cap layer presents a hazard of introducing additional impurities into the active region of the semiconductor. Uncontrolled diffusion of Zn, an impurity, in the neighborhood of the active region occurs mainly during the growth of the InGaAs cap layer. Therefore, it is desirable to minimize the amount of time spent forming the cap layer, thus reducing the desired cap layer thickness. In the past, most laser devices used a 500 nm thick cap layer. Recently, this was reduced to 200 nm and more recently to a minimum of 50 nm.
Because of the concern to reduce the thickness of the InGaAs cap layer, development efforts were aimed at producing a “low penetration contact” which was designed to react with a controlled minimum amount of semiconductor. The depth of reaction with the semiconductor is controlled by the thickness of the layers of metallization which interacted directly with the semiconductor. The idea is that the complete reaction of the layers of metal which combine with the semiconductor consumes only a small amount of semiconductor cap layer material. In order to make sure that the total penetration of the metal is kept to a desired limit, it is necessary to use very thin layers at the semiconductor/metal interface. For purposes of manufacturability, it is des

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