Abstract: A method of forming a multi-doped junction is disclosed. The method includes providing a first substrate and a second substrate. The method also includes depositing a first ink on a first surface of each of the first substrate and the second substrate, the first ink containing a first set of nanoparticles and a first set of solvents, the first set of nanoparticles containing a first concentration of a first dopant. The method further includes depositing a second ink on a second surface of each of the first substrate and the second substrate, the second ink containing a second set of nanoparticles and a second set of solvents, the second set of nanoparticles containing a second concentration of a second dopant. The method also includes placing the first substrate and the second substrate in a back to back configuration; and heating the first substrate and the second substrate in a first drive-in ambient to a first temperature and for a first time period.

Abstract: Disclosed are methods of forming multi-doped junctions, which utilize a nanoparticle ink to form an ink pattern on a surface of a substrate. From the ink pattern, a densified film ink pattern can be formed. The disclosed methods may allow in situ controlling of dopant diffusion profiles.

Abstract: A method of forming a multi-doped junction is disclosed. The method includes providing a substrate doped with boron atoms, the substrate comprising a front substrate surface. The method also includes depositing an ink on the front substrate surface in an ink pattern, the ink comprising a set of nanoparticles and a set of solvents; and heating the substrate in a baking ambient at a baking temperature and for a baking time period wherein a densified ink layer is formed. The method further includes exposing the substrate to a phosphorous dopant source at a drive-in temperature and for a drive-in time period.

Abstract: A method of distinguishing a set of highly doped regions from a set of lightly doped regions on a silicon substrate is disclosed. The method includes providing the silicon substrate, the silicon substrate configured with the set of lightly doped regions and the set of highly doped regions. The method further includes illuminating the silicon substrate with an electromagnetic radiation source, the electromagnetic radiation source transmitting a wavelength of light above about 1100 nm. The method also includes measuring a wavelength absorption of the set of lightly doped regions and the set of heavily doped regions with a sensor, wherein for any wavelength above about 1100 nm, the percentage absorption of the wavelength in the lightly doped regions is substantially less than the percentage absorption of the wavelength in the heavily doped regions.

Abstract: A method of forming a multi-doped junction on a substrate is disclosed. The method includes providing the substrate doped with boron atoms, the substrate comprising a front substrate surface, and depositing an ink on the front substrate surface in an ink pattern, the ink comprising a set of nanoparticles and a set of solvents. The method further includes heating the substrate in a baking ambient to a first temperature of between about 200° C. and about 800° C. and for a first time period of between about 3 minutes and about 20 minutes in order to create a densified film ink pattern. The method also includes exposing the substrate to a dopant source in a diffusion furnace with a deposition ambient, the deposition ambient comprising POCl3, a carrier N2 gas, a main N2 gas, and a reactive O2 gas, wherein a ratio of the carrier N2 gas to the reactive O2 gas is between about 1:1 to about 1.5:1, at a second temperature of between about 700° C. and about 1000° C.

Abstract: A method of forming a multi-doped junction on a substrate is disclosed. The method includes providing the substrate doped with boron atoms, the substrate comprising a front substrate surface. The method further includes depositing an ink on the front substrate surface in a ink pattern, the ink comprising a set of silicon-containing particles and a set of solvents. The method also includes heating the substrate in a baking ambient to a first temperature and for a first time period in order to create a densified film ink pattern.

Abstract: A method of forming a multi-doped junction on a substrate is disclosed. The method includes providing the substrate doped with boron atoms, the substrate comprising a front crystalline substrate surface; and forming a mask on the front crystalline substrate surface, the mask comprising exposed mask areas and non-exposed mask areas. The method also includes exposing the mask to an etchant, wherein porous silicon is formed on the front crystalline substrate surface defined by the exposed mask areas; and removing the mask. The method further includes exposing the substrate to a dopant source in a diffusion furnace with a deposition ambient, the deposition ambient comprising POCl3 gas, at a first temperature and for a first time period, wherein a PSG layer is formed on the front substrate surface; and heating the substrate in a drive-in ambient to a second temperature and for a second time period.

Abstract: A method of forming a multi-doped junction is disclosed. The method includes providing a first substrate and a second substrate. The method also includes depositing a first ink on a first surface of each of the first substrate and the second substrate, the first ink comprising a first set of nanoparticles and a first set of solvents, the first set of nanoparticles comprising a first concentration of a first dopant. The method further includes depositing a second ink on a second surface of each of the first substrate and the second substrate, the second ink comprising a second set of nanoparticles and a second set of solvents, the second set of nanoparticles comprising a second concentration of a second dopant. The method also includes placing the first substrate and the second substrate in a back to back configuration; and heating the first substrate and the second substrate in a first drive-in ambient to a first temperature and for a first time period.