Abstract: A method for producing a volume change compensated (SSLC) material is disclosed. An initially prelithiated SSLC material is produced and delithiated to produce a delithiated SSLC material. Perform at least one iteration involving: (a) re-prelithiating the delithiated SSLC material to produce a re-prelithiated SSLC material; and (b) delithiating the re-prelithiated SSLC material produced in (a). At least one of the following is satisfied: (i) prior to performing the at least one iteration the initially prelithiated SSLC material is essentially completely lithiated; and (ii) at least one iteration produces a re-prelithiated SSLC material that is essentially completely prelithiated. In a final iteration, delithiating the re-prelithiated SSLC material produced in (a) completely delithiates the re-prelithiated SSLC material to produce the volume change compensated SSLC material.

Abstract: Optical products are disclosed that include a polymeric substrate, provided with an infrared-reflective metal layer on an outer surface thereof that is subject to oxidation. The optical products are further provided with a protective coating, comprising one or more of a metal oxide or a metal nitride, deposited directly on the infrared-reflective metal layer using chemical vapor deposition. The optical products are further provided with a composite pigment coating, deposited on the protective coating, that include at least a first layer and a second layer, at least one of which layers comprises a first pigment, wherein each of the first layer and the second layer includes a binding group component, each of which binding group components together form a complementary binding group pair.

Abstract: A process for producing a silicon:silicon oxide:lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: Optical products are disclosed that include a polymeric substrate, provided with an infrared-reflective metal layer on an outer surface thereof that is subject to oxidation. The optical products are further provided with a protective coating, comprising one or more of a metal oxide or a metal nitride, deposited directly on the infrared-reflective metal layer using chemical vapor deposition. The optical products are further provided with a composite pigment coating, deposited on the protective coating, that include at least a first layer and a second layer, at least one of which layers comprises a first pigment, wherein each of the first layer and the second layer includes a binding group component, each of which binding group components together form a complementary binding group pair.

Abstract: A method for producing a volume change compensated silicon: silicon oxide: lithium composite (SSLC) material is disclosed. The method includes producing an initially prelithiated SSLC material; delithiating the initially prelithiated material to produce a delithiated SSLC material; and performing at least one iteration of a volume change compensation process involving: (a) re-prelithiating the delithiated SSLC material to produce a re-prelithiated SSLC material; and (b) delithiating the re-prelithiated SSLC material produced in (a), wherein at least one of the following is satisfied: (i) prior to performing the at least one iteration of the volume change compensation process the initially prelithiated SSLC material is essentially completely lithiated; and (ii) at least one iteration of the volume change compensation process produces a re-prelithiated SSLC material that is essentially completely prelithiated.

Abstract: A process for producing a silicon:silicon oxide:lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: A process for producing a silicon:silicon oxide: lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: A process for producing a silicon:silicon oxide: lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: An optical product for use in products such as window films and electronic displays is disclosed. The optical product includes a polymeric substrate and a hardcoat and has an abrasion resistance at the hardcoat surface as measured by haze increase of no more than 4.5% when measured according to Taber abrasion testing based on ASTM D1044 and a difference in water vapor transmission rate when compared to said polymeric substrate alone of no more than 5 grams/m2/day.

Abstract: The present invention provides a method to form Group IBIIIAVIA solar cell absorber layers on continuous flexible substrates. In a preferred aspect, the method forms a Group IBIIIAVIA absorber layer for manufacturing photovoltaic cells by providing a workpiece having a precursor layer formed over a substrate, the precursor layer including copper, indium, gallium and selenium; heating the precursor layer to a first temperature; reacting the precursor layer at the first temperature for a first predetermined time to transform the precursor layer to a partially formed absorber structure; cooling down the partially formed absorber structure to a second temperature, wherein both the first temperature and the second temperature are above 400° C.; and reacting the partially formed absorber structure at the second temperature for a second predetermined time, which is longer than the first predetermined time, to form a Group IBIIIAVIA absorber layer.

Abstract: The present invention provides a method to form Group IBIIIAVIA solar cell absorber layers on continuous flexible substrates. In a preferred aspect, the method forms a Group IBIIIAVIA absorber layer for manufacturing photovoltaic cells by providing a workpiece having a precursor layer formed over a substrate, the precursor layer including copper, indium, gallium and selenium; heating the precursor layer to a first temperature; reacting the precursor layer at the first temperature for a first predetermined time to transform the precursor layer to a partially formed absorber structure; cooling down the partially formed absorber structure to a second temperature, wherein both the first temperature and the second temperature are above 400° C.; and reacting the partially formed absorber structure at the second temperature for a second predetermined time, which is longer than the first predetermined time, to form a Group IBIIIAVIA absorber layer.

Abstract: A method of forming a doped Group IBIIIAVIA absorber layer for solar cells by reacting a a metallic precursor layer with a dopant structure. The metallic precursor layer including Group IB and Group IIIA materials such as Cu, Ga and In are deposited on a base. The dopant structure is formed on the metallic precursor layer, wherein the dopant structure includes a stack of one or more Group VIA material layers such as Se layers and one or more a dopant material layers such as Na.