Planar Collection

Graphene sheet, artwork C016 / 8274
Graphene sheet. Computer artwork showing the molecular structure of a graphene sheet. Graphene is a single layer of graphite

Engraving depicting a geological fold, which occurs when one or a stack of originally flat and planar surfaces
5309459 Engraving depicting a geological fold, which occurs when one or a stack of originally flat and planar surfaces, such as sedimentary strata

Vitamin D2, molecular model. The chemical formula for vitamin D2, also called ergocalciferol, is C28.H44.O. Atoms are represented as spheres and are colour-coded: carbon (blue)

Graphene, molecular structure C016 / 8518
Graphene. Computer model of the molecular structure of graphene, a single layer of graphite. It is composed of hexagonally arranged carbon atoms (black) linked by strong covalent bonds (pink)

Graphene, molecular structure C016 / 8517
Graphene. Computer model of the molecular structure of graphene, a single layer of graphite. It is composed of hexagonally arranged carbon atoms (black) linked by strong covalent bonds (grey)

Graphene, molecular structure C016 / 8515
Graphene. Computer model of the molecular structure of graphene, a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres) linked by strong covalent bonds

Graphene, molecular structure C016 / 8513
Graphene. Computer model of the molecular structure of graphene, a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres) linked by strong covalent bonds (rods)

Graphene, molecular structure C016 / 8509
Graphene. Computer model of the molecular structure of graphene, a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres) linked by strong covalent bonds

Graphene sheet. Computer artwork showing the structure of a graphene sheet. Graphene is a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres)

Nanopore DNA sequencing, conceptual image C013 / 8901
Nanopore DNA sequencing, conceptual image. Computer artwork of a DNA (deoxyribonucleic acid) strand (green and red) being sequenced (letters) as it passes through a nanopore (tiny hole)

Graphene conductivity, conceptual image. Computer artwork of a graphene sheet with electricity (yellow) passing through it. Graphene is a single layer of graphite

Graphene conductivity, conceptual image C013 / 8897
Graphene conductivity, conceptual image. Computer artwork of a graphene sheet with electricity (yellow) passing through it. Graphene is a single layer of graphite

Molecular transistor, AFM
Molecular transistor. Coloured atomic force micro- graph (AFM) of a transistor on the molecule scale. It consists of electrodes (yellow) created by electron beam lithography (EBL)

Graphene, molecular structure

Graphene sheets, artwork
Graphene sheets, computer artwork. Graphene a single layer of graphite. It is composed of hexagonally arranged carbon atoms (spheres) linked by strong covalent bonds (rods)

Phthalocyanine, molecular model
Phthalocyanine. Molecular model of a phthalocyanine with a metal cation (green) bound at its centre. In this state it is also known as a metallophthalocyanine (MPc)

All Professionally Made to Order for Quick Shipping

"Unveiling the Marvels of Planar: Exploring Graphene's Limitless Potential" Step into a world where science and art converge, as we delve into the captivating realm wonders. At the heart of this enigmatic domain lies graphene, an extraordinary material that holds immense promise for countless applications. Imagine a single layer of carbon atoms intricately arranged in a two-dimensional lattice – that is graphene. Its remarkable properties have captivated scientists worldwide, leading to groundbreaking advancements in various fields. As we gaze upon artwork C016/8274, it unveils the mesmerizing beauty hidden within each graphene sheet. But what makes graphene truly exceptional? Its molecular structure, represented by artworks C016/8518, C016/8517, C016/8515, C016/8513, and C016/8509 showcases its hexagonal honeycomb pattern with unparalleled precision. This arrangement grants graphene incredible strength while retaining flexibility—a feat unmatched by any other material known to man. Beyond its structural marvels lies another facet of planar's allure—its conductivity. Conceptual images depicting graphene conductivity offer glimpses into how this wonder material could revolutionize electronics and energy storage systems. The potential for faster data transfer and more efficient devices becomes tantalizingly close. Moreover, let us not forget Nika—the embodiment of elegance intertwined with scientific brilliance. With grace and poise akin to a ballet dancer on stage, Nika epitomizes the fusion between artistry and technological innovation inspired by planar materials like graphene. In our quest for knowledge about these fascinating structures comes Vitamin D2—a molecular model symbolizing health and vitality derived from nature itself. It reminds us that even at the microscopic level, planar materials can impact our lives positively through medical breakthroughs or novel drug delivery systems yet to be discovered. And finally enters Nanopore DNA sequencing—an awe-inspiring conceptual image illustrating how planar materials could revolutionize genetic research.