Patent Description:
Metal contact formation to electrically active areas in semi-conductor and solar industries often involves a removal of dielectric material(s) (e.g., an oxide or nitride material), which may exist to electrically isolate or passivate certain active areas. Commonly practiced methods may require several process operations, such as deposition of a mask layer, selective etching of dielectric layer(s), and removal of a mask, or laser with subsequent etch or anneal.

<CIT> discloses a buried insulator isolation for solar cell contacts. A buried oxide is provided under the emitter of a polysilicon emitter solar cell. Holes in the oxide provide contact areas, increasing the current density to enhance efficiency. The oxide isolates the contacts from the substrate. <CIT> Al discloses methods for forming a photovoltaic cell electrode. The methods involve creating contact openings in the passivation layer, selectively plating contact metal, depositing a metal-containing material (such as lead-free silver paste), and firing the deposited contact metal and the deposited metal containing material.

According to an aspect, the present invention provides a solar cell as defined in claim <NUM>. According to an aspect, a solar cell comprises:.

The formation of solar cell contact openings using a laser is described herein. In the following description, numerous specific details are set forth, such as specific process flow operations, in order to provide a thorough understanding of embodiments of the present invention. It will be apparent to one skilled in the art that embodiments of the present invention may be practiced without these specific details. In other instances, well-known fabrication techniques, such as lithographic techniques, are not described in detail in order to not unnecessarily obscure embodiments of the present invention. Furthermore, it is to be understood that the various embodiments shown in the Figures are illustrative representations and are not necessarily drawn to scale.

Disclosed herein are methods of fabricating back-contact solar cells. In one embodiment, a method includes forming a poly-crystalline material layer above a single-crystalline substrate. A dielectric material stack is formed above the poly-crystalline material layer. A plurality of contacts holes is formed in the dielectric material stack by laser ablation, each of the contact holes exposing a portion of the poly-crystalline material layer. Conductive contacts are formed in the plurality of contact holes. In one embodiment, a method includes forming a poly-crystalline material layer above a single-crystalline substrate. A dielectric material stack is formed above the poly-crystalline material layer. A recast poly signature is formed in the poly-crystalline material layer. A plurality of conductive contacts is formed in the dielectric material stack and coupled directly to a portion of the poly-crystalline material layer, one of the conductive contacts in alignment with the recast poly signature. It is to be understood that embodiments of the present invention need not be limited to the formation of back-side contacts, but could be used to form front-side contacts instead or as well.

Also disclosed herein are back-contact solar cells. In one embodiment, a back-contact solar cell includes a poly-crystalline material layer disposed above a single-crystalline substrate. A dielectric material stack is disposed above the poly-crystalline material layer. A plurality of conductive contacts is disposed in the dielectric material stack and coupled directly to a portion of the poly-crystalline material layer. A recast poly signature is disposed in the poly-crystalline material layer and in alignment with one of the plurality of conductive contacts.

In accordance with an embodiment of the present invention, contact formation is simplified and an associated cost of manufacture is reduced through reduction of consumables used, reduction of capital expenditure, and reduction of complexity. In one embodiment, contact formation for a solar cell includes contact formation in a dielectric layer by a direct-fire laser approach. Such an approach may otherwise be detrimental for single-crystal substrate based solar cells. However, in an embodiment, a poly-crystalline layer is included above a single-crystal substrate based solar cell. In that embodiment, any damage or melt is received and accommodated by the poly-crystalline layer instead of by the single-crystal substrate. Furthermore, in an embodiment, by using a poly-crystalline layer to receive a process of direct-fired contact formation, the formation of recombination sites in the single-crystal substrate is reduced or even essentially eliminated.

Conventional approaches to using laser treatment in the fabrication of contacts may often result in loss of efficiency over standard mask and etch techniques due to damage induced by lasers, which may increase contact resistance, may increase recombination at the emitter/metal junction, and may increase recombination an area known as the heat affected zone (HAZ). In an embodiment, such conventional approaches have lead to high emitter recombination, accentuating the traditional confounding problem of the need to minimize efficiency loss through contact recombination, while maintaining adequate contact coverage.

In accordance with an embodiment of the present invention, such laser-induced damage is minimized or essentially eliminated with use of highly advanced lasers with ultra short pulse lengths (e.g., in the femto second range) and short wavelength light (UV). However, in the case that such lasers are not available commercially or could be highly unstable with a myriad of industrial problems (e.g., optical coating degradation), then standard cell architectures may still exhibit electrical degradation with such laser configurations. As such, in another embodiment, to avoid any inherent electrical losses, commercially available and reliably-tested lasers are applied to semiconductors without causing additional emitter recombination sites. In one embodiment, recombination in a solar cell is insensitive to typical optical and thermal damages induced by a laser since any damage remains within a poly-crystalline material layer instead on an underlying single-crystalline substrate. In an embodiment, a contact resistance of a solar cell surface remains low after contact formation by laser.

In an embodiment, formation of a dielectric or passivation layer in combination with a poly-crystalline material layer is tuned in a way to accommodate commercially available lasers which confine any laser damage to the poly-crystalline material layer or to the dielectric or passivation layer. For example, in an embodiment, a pico-second laser is used and the thermal penetration depth in silicon is limited to a submicron level. In a specific embodiment, an optical penetration depth in silicon during a laser-induced contact formation process is confined to a submicron level by using a laser wavelength less than approximately <NUM> nanometers. In an embodiment, with the addition of an absorbing layer, such as a silicon nitride layer with the composition SixNy, total thermal and optical damage is confined within a poly-crystalline material layer so that high-efficiencies are achieved in a solar cell without the need for post-laser etching processes, or selective emitter formation. In an embodiment, a thin, e.g. less than approximately <NUM> nanometers, thermal oxide layer is grown to help mitigate thermal damage and promote ablation quality, optimizing a laser absorption process. In another embodiment, an appropriately tuned poly/oxide/nitride stack is used to accommodate longer pulse length (e.g., nano-second), or higher wavelength lasers (e.g., <NUM> nanometers).

<FIG> illustrates a flowchart <NUM> representing operations in a method of fabricating a back-contact solar cell, in accordance with an embodiment of the present invention. <FIG> illustrate cross-sectional views of various stages in the fabrication of a back-contact solar cell corresponding to the operations of flowchart <NUM>.

Referring to operation <NUM> of flowchart <NUM> and corresponding <FIG>, a method of fabricating a back-contact solar cell includes forming a poly-crystalline material layer <NUM> above a single-crystalline substrate <NUM>. In accordance with an embodiment of the present invention, forming poly-crystalline material layer <NUM> above single-crystalline substrate <NUM> includes forming a layer of poly-crystalline silicon above a single-crystalline silicon substrate. In an embodiment, poly-crystalline material layer <NUM> is formed to a thickness of approximately <NUM> nanometers. In one embodiment, forming the layer of poly-crystalline silicon above the single-crystalline silicon substrate includes forming the layer of poly-crystalline silicon directly on a dielectric film <NUM>, dielectric film <NUM> formed directly on single-crystalline silicon substrate <NUM>, and forming both N-type and P-type doped regions 202A and 202B, respectively, in the layer of poly-crystalline silicon, as depicted in <FIG>. In one embodiment, the dielectric film <NUM> is a material such as, but not limited to, silicon dioxide (SiO2), phosphosilicate glass (PSG), or borosilicate glass (BSG) having a thickness approximately in the range of <NUM> to <NUM> nanometers. In a specific embodiment, dielectric film <NUM> is composed of silicon dioxide and has a thickness approximately in the range of <NUM> - <NUM> nanometers. In a particular embodiment, dielectric film <NUM> is a tunnel oxide barrier layer film. In an alternative embodiment, instead of forming poly-crystalline material layer <NUM>, a non-poly-crystalline absorbing material is formed instead such as, but not limited to an amorphous layer, a polymer layer, or a multi-crystalline layer. In another alternative embodiment, instead of using single-crystalline substrate <NUM>, a multi-crystalline substrate is used in its place. In an embodiment, a trench or gap is present between the P and N diffused regions, e.g., in the case of one embodiment of a back-contact design.

Referring to operation <NUM> of flowchart <NUM> and corresponding <FIG>, the method of fabricating a back-contact solar cell also includes forming a dielectric material stack <NUM> above poly-crystalline material layer <NUM>. In accordance with an embodiment of the present invention, forming dielectric material stack <NUM> above poly-crystalline material layer <NUM> includes forming a silicon dioxide layer 203A directly on poly-crystalline material layer <NUM>, and forming a silicon nitride layer 203B directly on silicon dioxide layer 203A. In an embodiment, forming silicon dioxide layer 203A includes forming to a thickness sufficiently low to not reflect back laser energy during a laser ablation process. However, in another embodiment, forming silicon dioxide layer 203A includes forming to a thickness sufficiently high to act as an ablation stop layer during a laser ablation process. In one embodiment, forming silicon dioxide layer 203A includes forming the layer to have a thickness approximately in the range of <NUM> - <NUM> nanometers. In a specific embodiment, forming silicon dioxide layer 203A includes forming the layer to have a thickness approximately in the range of <NUM> - <NUM> nanometers. However, in another embodiment, there is no layer 203A in the dielectric stack and only a silicon nitride layer 203B is included, as depicted in <FIG>.

Referring to operation <NUM> of flowchart <NUM> and corresponding <FIG>, the method of fabricating a back-contact solar cell also includes forming, by laser ablation <NUM>, a plurality of contacts holes <NUM> in dielectric material stack <NUM>, each of the contact holes <NUM> exposing a portion of poly-crystalline material layer <NUM>. In accordance with an embodiment of the present invention, forming the plurality of contact holes <NUM> is performed without the use of a patterned mask. In an embodiment, forming the plurality of contact holes <NUM> includes ablating with a laser having a wavelength approximately at, or less than, <NUM> nanometers.

Referring to operation <NUM> of flowchart <NUM> and corresponding <FIG>, the method of fabricating a back-contact solar cell also includes forming conductive contacts <NUM> in the plurality of contact holes <NUM>.

By applying a laser-induced contact formation process such as the process described above, certain signatures or features may be included in the resulting solar cell. For example, <FIG> illustrates a cross-sectional view of a back-contact solar cell, in accordance with an embodiment of the present invention.

Referring to <FIG>, a back-contact solar cell <NUM> includes a poly-crystalline material layer 302A + 302B disposed above a single-crystalline substrate <NUM>. A dielectric material stack <NUM> is disposed above poly-crystalline material layer 302A + 302B. A plurality of conductive contacts <NUM> is disposed in dielectric material stack <NUM> and coupled directly to a portion of poly-crystalline material layer 302A + 302B. A recast poly signature <NUM> is disposed in poly-crystalline material layer 302A + 302B and is in alignment with one of the plurality of conductive contacts <NUM>.

In accordance with an embodiment of the present invention, poly-crystalline material layer 302A + 302B is a layer of poly-crystalline silicon, and single-crystalline substrate <NUM> is a single-crystalline silicon substrate. In one embodiment, the layer of poly-crystalline silicon is disposed directly on a dielectric film <NUM>, and dielectric film <NUM> is disposed directly on single-crystalline silicon substrate <NUM>, as depicted in <FIG>. In a specific embodiment, the layer of poly-crystalline silicon includes both N-type and P-type doped regions, 302A + 302B, as is also depicted in <FIG>. In an embodiment, dielectric material stack <NUM> includes a silicon dioxide layer 303A disposed directly on poly-crystalline material layer 302A + 302B, and a silicon nitride layer 303B disposed directly on silicon dioxide layer 303A, as depicted in <FIG>. In one embodiment, silicon dioxide layer 303A has a thickness approximately in the range of <NUM> - <NUM> nanometers. In an embodiment, each of the plurality of conductive contacts <NUM> is round in shape. In an alternative embodiment, instead of forming poly-crystalline material layer 302A + 302B, a non-poly-crystalline absorbing material is formed instead such as, but not limited to an amorphous layer, a polymer layer, or a multi-crystalline layer. In another alternative embodiment, instead of using single-crystalline substrate <NUM>, a multi-crystalline substrate is used in its place. In an embodiment, a trench or gap is present between the P and N diffused regions, e.g., in the case of one embodiment of a back-contact design. In another embodiment, as depicted in <FIG>, a single dielectric material 303B with a thickness approximately in the range of <NUM>-<NUM> nanometers is used, and layer 303A is excluded.

A back-contact solar cell having a recast poly signature may be formed when contact holes in the back-contact solar cell are formed by a laser ablation process. <FIG> illustrates a flowchart <NUM> representing operations in a method of fabricating a back-contact solar cell, in accordance with an embodiment of the present invention.

Referring to operation <NUM> of flowchart <NUM>, a method of fabricating a back-contact solar cell includes forming a poly-crystalline material layer above a single-crystalline substrate. In accordance with an embodiment of the present invention, forming the poly-crystalline material layer above the single-crystalline substrate includes forming a layer of poly-crystalline silicon above a single-crystalline silicon substrate. In one embodiment, forming the layer of poly-crystalline silicon above the single-crystalline silicon substrate includes forming the layer of poly-crystalline silicon directly on a dielectric film, the dielectric film formed directly on the single-crystalline silicon substrate, and forming both N-type and P-type doped regions in the layer of poly-crystalline silicon. In an alternative embodiment, instead of forming the poly-crystalline material layer, a non-poly-crystalline absorbing material is formed instead such as, but not limited to an amorphous layer, a polymer layer, or a multi-crystalline layer. In another alternative embodiment, instead of using the single-crystalline substrate, a multi-crystalline substrate is used in its place. In an embodiment, a trench or gap is present between the P and N diffused regions, e.g., in the case of one embodiment of a back-contact design.

Referring to operation <NUM> of flowchart <NUM>, the method of fabricating a back-contact solar cell also includes forming a dielectric material stack above the poly-crystalline material layer. In accordance with an embodiment of the present invention, forming the dielectric material stack above the poly-crystalline material layer includes forming a silicon dioxide layer directly on the poly-crystalline material layer, and forming a silicon nitride layer directly on the silicon dioxide layer. In one embodiment, forming the silicon dioxide layer includes forming the layer to have a thickness approximately in the range of <NUM> - <NUM> nanometers. In a specific embodiment, forming the silicon dioxide layer includes forming the layer to have a thickness approximately in the range of <NUM> - <NUM> nanometers.

Referring to operation <NUM> of flowchart <NUM>, the method of fabricating a back-contact solar cell also includes forming a recast poly signature in the poly-crystalline material layer. In accordance with an embodiment of the present invention, each of the plurality of conductive contacts is round in shape.

Referring to operation <NUM> of flowchart <NUM>, the method of fabricating a back-contact solar cell also includes forming a plurality of conductive contacts in the dielectric material stack and coupled directly to a portion of the poly-crystalline material layer, one of the conductive contacts in alignment with the recast poly signature. In accordance with an embodiment of the present invention, forming the recast poly signature includes ablating with a laser having a wavelength approximately at, or less than, <NUM> nanometers.

It is to be understood that use of the term poly-crystalline layer, when referring to a polycrystalline silicon layer, is intended to also cover material that can be described as amorphous- or α-silicon. It is also to be understood that, instead of or in addition to forming N-type and P-type doped regions in the poly-crystalline layer, such regions can instead be formed directly in a single crystalline substrate. It is also to be understood that a variety of laser pulse periodicities may be used for ablation. However, in an embodiment, laser ablation is performed with laser pulse lengths in the pico- to nano-second range.

Claim 1:
A solar cell comprising:
a silicon substrate (<NUM>);
a dielectric material (<NUM>) above the silicon substrate;
a material layer (302A+302B) above the dielectric material (<NUM>), the material layer (302A+302B) comprising a polycrystalline silicon layer and having P-type and N-type doped regions (302A, 302B) and a plurality of recast poly signatures (<NUM>);
a dielectric material stack (<NUM>) above the poly-crystalline silicon layer, the dielectric material stack comprising a first dielectric layer (303B) and a second dielectric layer (303A), wherein the first dielectric layer (303B) is disposed above the material layer (302A+302B) and the second dielectric layer (303A) is disposed directly on the material layer (302A+302B);
a plurality of conductive contacts (<NUM>) through the dielectric material stack (<NUM>) with each of the plurality of conductive contacts being in alignment with one of the plurality of recast poly signatures (<NUM>) in the poly-crystalline silicon layer;
and wherein the dielectric material stack (<NUM>) comprises a silicon nitride layer (303B), and wherein the dielectric material stack (<NUM>) further comprises a silicon dioxide layer (303A) between the poly-crystalline silicon layer and the silicon nitride layer (303B).