Abstract: A method of treating an electrode for a battery to enhance its performance is disclosed. By depositing a layer of porous carbon onto the electrode, its charging and discharging characteristics, as well as chemical stability may be improved. The method includes creating a plasma that includes carbon and attracting the plasma toward the electrode, such as by biasing a platen on which the electrode is disposed. In some embodiments, an etching process is also performed on the deposited porous carbon to increase its surface area. The electrode may also be exposed to a hydrophilic treatment to improve its interaction with the electrolyte. In addition, a battery which includes at least one electrode treated according to this process is disclosed.

Abstract: A system for processing a substrate includes a plasma chamber to produce a plasma including reactive gas ions at a first pressure, a bias supply to supply a bias between the plasma chamber and the substrate, a plasma sheath modifier disposed between the plasma chamber and substrate, the plasma sheath modifier having an aperture configured to direct the reactive ions toward the substrate in a beam having an ion beam profile, and a process chamber enclosing the substrate, the process chamber at a second pressure different than the first pressure to define a pressure differential.

Abstract: A method of processing a substrate includes performing a first exposure that comprises generating a plasma containing reactive gas ions in a plasma chamber and generating a bias voltage between the substrate and the plasma chamber. The method also includes providing a plasma sheath modifier having an aperture disposed between the plasma and substrate and operable to direct the reactive gas ions toward the substrate, and establishing a pressure differential between the plasma chamber and substrate region while the reactive gas ions are directed onto the substrate.

Abstract: An improved method of creating thermoelectric materials which have high electrical conductivity and low thermal conductivity is disclosed. In one embodiment, the thermoelectric material is made by depositing a porous film onto a substrate, introducing a dopant into the porous film and annealing the porous film to activate the dopant. In other embodiments, additional amounts of dopant may be introduced via subsequent ion implantations of dopant into the deposited porous film.

Abstract: A method of processing a substrate includes performing a first exposure that comprises generating a plasma containing reactive gas ions in a plasma chamber and generating a bias voltage between the substrate and the plasma chamber. The method also includes providing a plasma sheath modifier having an aperture disposed between the plasma and substrate and operable to direct the reactive gas ions toward the substrate, and establishing a pressure differential between the plasma chamber and substrate region while the reactive gas ions are directed onto the substrate.

Abstract: A method of treating an electrode for a battery to enhance its performance is disclosed. By depositing a layer of porous carbon onto the electrode, its charging and discharging characteristics, as well as chemical stability may be improved. The method includes creating a plasma that includes carbon and attracting the plasma toward the electrode, such as by biasing a platen on which the electrode is disposed. In some embodiments, an etching process is also performed on the deposited porous carbon to increase its surface area. The electrode may also be exposed to a hydrophilic treatment to improve its interaction with the electrolyte. In addition, a battery which includes at least one electrode treated according to this process is disclosed.

Abstract: In one embodiment, a method of producing a porous semiconductor film on a workpiece includes generating semiconductor precursor ions that comprise one or more of: germanium precursor ions and silicon precursor ions in a plasma of a plasma chamber, in which the semiconductor precursor ions are operative to form a porous film on the workpiece. The method further includes directing the semiconductor precursor ions to the workpiece over a range of angles.

Abstract: An improved method of creating thermoelectric materials which have high electrical conductivity and low thermal conductivity is disclosed. In one embodiment, the thermoelectric material is made by depositing a porous film onto a substrate, introducing a dopant into the porous film and annealing the porous film to activate the dopant. In other embodiments, additional amounts of dopant may be introduced via subsequent ion implantations of dopant into the deposited porous film.

Abstract: Techniques for diamond nucleation control for thin film processing are disclosed. In one particular embodiment, the techniques may be realized as a method for generating a plasma having a plurality of ions; depositing a plurality of diamond nucleation centers on a substrate with the ions in the plasma using an extraction plate having at least one gap, wherein the plasma ions pass through the at least one gap in the extraction plate to generate a focused ion beam to deposit the plurality of diamond nucleation centers; and controlling the growth of a continuous diamond film from the diamond nucleation centers on the substrate by controlling at least one of a temperature around the substrate, a temperature of the plasma, a pressure around the substrate, and a concentration of the ions in the plasma.

Abstract: Methods of affecting a material's properties through the implantation of ions, such as by using a plasma processing apparatus with a plasma sheath modifier. In this way, properties such as resistance to chemicals, adhesiveness, hydrophobicity, and hydrophilicity, may be affected. These methods can be applied to a variety of technologies. In some cases, ion implantation is used in the manufacture of printer heads to reduce clogging by increasing the materials hydrophobicity. In other embodiments, MEMS and NEMS devices are produced using ion implantation to change the properties of fluid channels and other structures. In addition, ion implantation can be used to affect a material's resistance to chemicals, such as acids.

Abstract: Methods of creating porous materials, such as silicon, are described. In some embodiments, plasma sheath modification is used to create ion beams of various incidence angles. These ion beams may, in some cases, form a focused ion beam. The wide range of incidence angles allows the material to be deposited amorphously. The porosity and pore size can be varied by changing various process parameters. In other embodiments, porous oxides can be created by adding oxygen to previously created layers of porous material.

Abstract: ZnTe is implanted with a first species selected from Group III and a second species selected from Group VII. This may be preformed using sequential implants, implants of the first species and second species that are at least partially simultaneous, or a molecular species comprising an atom selected from Group III and an atom selected from Group VII. The implants may be performed at an elevated temperature in one instance between 70° C. and 800° C.

Abstract: ZnTe is implanted with a first species selected from Group III and a second species selected from Group VII. This may be performed using sequential implants, implants of the first species and second species that are at least partially simultaneous, or a molecular species comprising an atom selected from Group III and an atom selected from Group VII. The implants may be performed at an elevated temperature in one instance between 70° C. and 800° C.