In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.
In an industry first, the all-new XPS 13 uses nine composite layers of white crystalline silica to achieve the alpine white glass fiber weave pattern on the palm rest, surpassing the limits of traditional carbon fiber. It’s also coated with titanium oxide to give it a sheen and make it UV and stain-resistant.