Abstract: During the processing of substrates, the substrate surface may be subjected to a cleaning process using supercritical CO2. Surface matter may remain, for example, because it is only minimally soluble in the supercritical CO2. For example, an oxidation cleaning process causes the substrate structure to cleave at several points leaving smaller fragments of oxidized residue behind. This residue has only minimal solubility in supercritical CO2 due to the polar constituents resulting from oxidation. The method thus further includes processing the substrate with supercritical CO2 and a functionalizing agent that can react with the smaller fragments and/or other less soluble components. These functionalized components are rendered more soluble in supercritical CO2 and are more easily removed than their predecessors.

Abstract: A method and system for treating a dielectric film includes exposing at least one surface of the dielectric film to an alkyl silane, an alkoxysilane, an alkyl siloxane, an alkoxysiloxane, an aryl silane, an acyl silane, a cyclo siloxane, a polysilsesquioxane (PSS), an aryl siloxane, an acyl siloxane, or a halo siloxane, or any combination thereof. The dielectric film can include a low dielectric constant film with or without pores having an etch feature formed therein following dry etch processing. As a result of the etch processing or ashing, exposed surfaces in the feature formed in the dielectric film can become damaged, or activated, leading to retention of contaminants, absorption of moisture, increase in dielectric constant, etc. Damaged surfaces, such as these, are treated by performing at least one of healing these surfaces to, for example, restore the dielectric constant (i.e., decrease the dielectric constant) and cleaning these surfaces to remove contaminants, moisture, or residue.

Abstract: A method and system for treating a dielectric film includes exposing at least one surface of the dielectric film to an alkyl silane, an alkoxysilane, an alkyl siloxane, an alkoxysiloxane, an aryl silane, an acyl silane, a cyclo siloxane, a polysilsesquioxane (PSS), an aryl siloxane, an acyl siloxane, or a halo siloxane, or any combination thereof. The dielectric film can include a low dielectric constant film with or without pores having an etch feature formed therein following dry etch processing. As a result of the etch processing or ashing, exposed surfaces in the feature formed in the dielectric film can become damaged, or activated, leading to retention of contaminants, absorption of moisture, increase in dielectric constant, etc. Damaged surfaces, such as these, are treated by performing at least one of healing these surfaces to, for example, restore the dielectric constant (i.e., decrease the dielectric constant) and cleaning these surfaces to remove contaminants, moisture, or residue.

Abstract: A method and system is described for treating a substrate to remove particles using a supercritical fluid, such as carbon dioxide in a supercritical state. A process chemistry is introduced to the high pressure fluid for removing particles from the substrate surface. The process chemistry comprises an etchant, a surfactant and, optionally, a co-solvent.

Abstract: During the processing of substrates, the substrate surface may be subjected to a cleaning process using supercritical CO2. Surface matter may remain, for example, because it is only minimally soluble in the supercritical CO2. For example, an oxidation cleaning process causes the substrate structure to cleave at several points leaving smaller fragments of oxidized residue behind. This residue has only minimal solubility in supercritical CO2 due to the polar constituents resulting from oxidation. The method thus further includes processing the substrate with supercritical CO2 and a functionalizing agent that can react with the smaller fragments and/or other less soluble components. These functionalized components are rendered more soluble in supercritical CO2 and are more easily removed than their predecessors.

Abstract: A method of and apparatus for treating a substrate to remove porogens and/or porogen residues form a dielectric layer using a processing chamber operating at a supercritical state is disclosed. In addition, other supercritical processes can be performed before and/or after the removal process.

Abstract: A method for etching and removing post-etch residue from a BPSG material is disclosed. In accordance with the method of the present invention, the BPSG material is etched and the residue is removed from the substrate structure using supercritical solutions.

Abstract: A method and system is described for treating a substrate with a high pressure fluid, such as carbon dioxide in a supercritical state. A process chemistry containing a process peroxide is introduced to the high pressure fluid for treating the substrate surface. The peroxide-based chemistry is used in conjunction with an initiator, wherein the initiator facilitates the formation of a radical of the process peroxide.

Abstract: A method and system is described for treating a substrate having an open metal surface thereon using a high pressure fluid, such as carbon dioxide in a supercritical state. A process chemistry is introduced to the high pressure fluid for removing residues from the substrate surface. The process chemistry comprises trifluoroacetic acid (TFA).

Abstract: A method and system is described for treating a substrate with a supercritical fluid using a high temperature process. For example, when the supercritical fluid includes carbon dioxide in a supercritical state, the high temperature process is performed at temperature approximately equal to and exceeding 80° C., which is greater than the critical temperature of approximately 31 ° C.

Abstract: A method and system is described for treating a substrate with a high pressure fluid, such as carbon dioxide in a supercritical state. A process chemistry is introduced to the high pressure fluid for treating the substrate surface. The process chemistry includes a peroxide-based chemistry.

Abstract: A method and system for treating a dielectric film includes exposing at least one surface of the dielectric film to an alkyl silane, an alkoxysilane, an alkyl siloxane, an alkoxysiloxane, an aryl silane, an acyl silane, a cyclo siloxane, a polysilsesquioxane (PSS), an aryl siloxane, an acyl siloxane, or a halo siloxane, or any combination thereof. The dielectric film can include a low dielectric constant film with or without pores having an etch feature formed therein following dry etch processing. As a result of the etch processing or ashing, exposed surfaces in the feature formed in the dielectric film can become damaged, or activated, leading to retention of contaminants, absorption of moisture, increase in dielectric constant, etc. Damaged surfaces, such as these, are treated by performing at least one of healing these surfaces to, for example, restore the dielectric constant (i.e., decrease the dielectric constant) and cleaning these surfaces to remove contaminants, moisture, or residue.