RU2151449C1 - Method for producing photoelectric transducers with porous silicon film - Google Patents

Abstract

FIELD: optoelectronic devices. SUBSTANCE: upon diffusion doping of silicon surface photosensitive areas of surface are covered, prior to depositing contacts, with porous silicon film that functions as shielding mask during deposition of contacts. Additional growth of transducer efficiency is provided due to the fact that when p-n junction is formed, phosphor-doped layer on porous silicon areas is made thinner than on contact areas. EFFECT: facilitated manufacture, improved efficiency of device. 2 cl

Description

 The invention relates to the manufacture of optoelectronic devices, namely silicon photoconverters (FP).

 A known method of manufacturing an FP, including the manufacture of a diode structure, the deposition of metal contacts by chemical nickel plating of the silicon surface and antireflective coating (Vasiliev A.M., Landsman A.P. Semiconductor photoconverters.- M .: Soviet Radio, 1971). The disadvantage of this method is the low efficiency of AF.

 A known method of manufacturing FP, including the application of an antireflection coating in the form of a film of silicon oxide, a film of metal oxides (tantalum, niobium, titanium) or a film of silicon nitride (Koltun M.M. Solar cells.- M.: Nauka, 1987). The disadvantages of the known methods are the high complexity of the manufacture of antireflection film associated with vacuum deposition, heat treatment, selective application of enlightenment and the lack of efficiency of the AF.

As a prototype, a method is known for manufacturing silicon phase transitions, including creating a diode structure, applying metal contacts in the form of a contact pattern, applying an acid-resistant protective mask on top of the contacts, creating a porous silicon film between the contact areas and removing the protective mask (report by L. Schirone, G. Sotgiu, M. Montecchi, A. Parisini: "Porous Silicon in High Efficiency Large Solar Cells", 14 ^{th European Photovoltaic Solar Energy Conference, Barcelona} , Spain, 1997). According to this method, a film of porous silicon is created by a very simple operation - immersion of the FP preform in an acid solution for several seconds.

 The disadvantage of this method is the great complexity of manufacturing associated with the alignment of the protective mask with the previously created contact pattern, the inability to create a porous film close to the metal contact on the entire photosensitive surface. The slightest damage to the protective mask and exposure of the contact metal leads to a poor-quality porous film and low AF efficiency.

 The objective of the invention is to reduce the complexity of manufacturing and increase the efficiency of AF.

 The task is achieved by the fact that after diffusion doping of the silicon surface with phosphorus on photosensitive parts of the surface, a porous silicon film is created before contact is made, and porous silicon acts as a protective mask. An additional increase in the efficiency of phase transitions is achieved by the fact that with diffusion doping of the silicon surface, the thickness of the phosphorus-doped layer (pn junction depth) in the areas of porous silicon formation is less than in the contact areas.

 Reducing the complexity of manufacturing is ensured by the fact that the proposed method does not require accurate alignment when applying a protective mask and reduces the number of technological operations. Due to its dielectric properties, a porous silicon film acts as a protective mask during selective chemical deposition of contacts. Silicon-free metal surface allows high reproducibility to obtain a porous silicon film with desired properties (uniform in thickness with a low surface recombination rate), which improves the efficiency of phase transitions. Another advantage of this method is that an increase in the thickness of the phosphorus-doped layer (pn junction depth) under the contacts (at least up to 1 μm) leads to a decrease in recombination losses and an increase in the efficiency of the phase transition.

 Examples of specific performance may be as follows.

1. Diffusion doping of the front side with phosphorus and the back side with boron of silicon wafers is carried out in one step to a depth of 0.5-1 microns, then an acid-resistant polymer (mask) is applied to the front and back sides by screen printing in the form of a future contact pattern (on the back side in the form of a continuous layer), a mask is dried at a temperature of about 100 ^o C, by immersion in hydrofluoric acid solution with a small addition of nitric acid to provide for not more than 1 minute on the front side of the porous silicon film AF blue thickness of 0.1 d 0.15 micron, the protective mask is removed with hot water and a silicon-free areas of the porous silicon is deposited by chemical sequentially contact layers of nickel, copper and silver. As a result, fabricated FPs have an average efficiency of about 14%.

 2. Higher efficiencies up to 15% have AFs, in which, in contrast to Example 1, due to double diffusion, the thickness of the layer doped with phosphorus (p-n junction depth) in the areas of future contact on the front side is increased to 1 μm.

Claims (2)

 1. A method of manufacturing silicon photoconverters with a porous silicon film, including doping with phosphorus the front side of the silicon wafers, the selective deposition of metal contacts on the contact areas of silicon and the creation of an antireflection film of porous silicon between the contact areas, characterized in that after doping the surface of the silicon wafers, an acid-resistant coating is applied to it a protective mask in the form of a contact pattern by immersion in an acid solution on the mask-free areas of the silicon surface ayut porous silicon film, and after removing the mask on lots of silicon occupied by it is carried out the selective deposition of metal contacts.  2. The method according to claim 1, characterized in that the thickness of the layer doped with phosphorus at the sites of formation of porous silicon is made less than at the contact sites.