Abstract: A moisture delivery apparatus comprises a liquid reservoir with liquid, a plurality of wicks, an enclosure with panels, and a supporting and adjusting structure for supporting and adjusting the body of the plurality of wicks to emit more or less of vapor of the liquid into the enclosure to provide moisture, wherein the supporting and adjusting structure may be injectors, stanchion, baffles, and fasteners on panels.

Abstract: A moisture delivery apparatus, comprising a liquid reservoir with liquid, a plurality of wicks, an enclosure with panels, and a supporting and adjusting structure for supporting and adjusting the body of the plurality of wicks to emit more or less of vapor of the liquid into the enclosure to provide moisture, wherein the supporting and adjusting structure may be injectors, stanchion, baffles, and fasteners on panels.

Abstract: A method for determining copper contamination on a semiconductor wafer is disclosed. The minority carrier diffusion length is measured, then the wafer is activated by the application of optical or thermal energy. Likely the wafer is also contaminated with iron and thus it is necessary to separate the diffusion length effects caused by the iron from those caused by the copper, that is, both copper and iron contaminants cause a reduction in the minority carrier diffusion length. The applied energy causes the iron-boron pairs to dissociate and also causes the copper to form a metastable copper silicide state. After about 24 to 36 hours, the iron-boron pairs reform and therefore the iron contaminants no longer influence the diffusion length. At this point the diffusion length is measured again, which values are due solely to the copper contamination, since the copper remains in the silicide state. The copper contamination can be determined from the measured diffusion length values.

Abstract: A method for determining copper contamination on a semiconductor wafer is disclosed. The minority carrier diffusion length is measured, then the wafer is activated by the application of optical or thermal energy. Likely the wafer is also contaminated with iron and thus it is necessary to separate the diffusion length effects caused by the iron from those caused by the copper, that is, both copper and iron contaminants cause a reduction in the minority carrier diffusion length. The applied energy causes the iron-boron pairs to dissociate and also causes the copper to form a metastable copper silicide state. After about 24 to 36 hours, the iron-boron pairs reform and therefore the iron contaminants no longer influence the diffusion length. At this point the diffusion length is measured again, which values are due solely to the copper contamination, since the copper remains in the silicide state. The copper contamination can be determined from the measured diffusion length values.

Abstract: A method of treating the surface of a semiconductor wafer is disclosed for making the wafer resistant to particle adhesion, the method involving the application of a uniform corona charge to the wafer surface. The corona charge is deposited on the wafer using commercially available tools, and if necessary, it may be later removed by immersing the wafer in deionized water or by depositing a compensating corona charge over the wafer of opposite polarity relative to the originally-applied charge.