No inorganic antireflection layer is present between the substrate and the polymeric antireflection layer.

The layer stack preferably includes at least an anti-reflective layer and a metallization layer disposed below the anti-reflective layer.

The mixed oxide layer comprises ZnO, Ti02 and at least one of the oxides Al203, Ga203 and Sb203 and finds application as upper and/or lower anti-reflection layer, partial layer of an anti-reflecting layer and/or a final finishing layer.

The ARC layer is formed on a metal layer (107), wherein the lower percentage of silicon of the ARC layer inhibits the unwanted formation of silicides at the metal layer/ARC layer interface.

A second antireflective layer is deposited over the first primer layer and a second infrared reflective layer is deposited over the second antireflective layer.

Thereby a new kind of ARC layer, in particular absorbing ARC layer, is provided.

The antiglare film comprises a transparent substrate and an antiglare layer laminated on the transparent substrate.

Anti-reflective (AR) coated transparent substrates and methods of making the same are provided wherein the AR coating includes a fluorinated polymer.

The disclosed antiglare film has an antiglare layer on a substrate film.

The light controlling film has a light controlling layer having an uneven pattern on the surface.

The antireflective layer is formed on a surface member (which serves as a base material for the antireflective layer) of an outdoor device.

An antireflection layer (18) is arranged on the transparent hard coat layer (16).

An antiglare film (1) comprises a transparent base film (2), a light-diffusing layer (3) formed on the transparent base film (2), and an antiglare layer (4) formed on the light-diffusing layer (3).

The photovoltaic device additionally comprises reflective layer, an anti-reflective layer and a protective laminating layer.

The cermet layer and the anti-reflection layer may each be formed of intermediate layers.