LBNL Zoom Backgrounds

Instructions:
Click on the image you’d like to use. Right-click on the large version that appears and select “save image as” to save to your computer. Follow the Zoom instructions below to add to your account.

: Drone View of the Advanced Light Source

: Advanced Light Source entrance

: Advanced Light Source

: Best View from a Lab

: Building 50 at sunset

: Lab deer

: LBNL Site Office

: The Goat Life at LBNL

: Goats rid Lab of fire hazard

: Goats after a long day

: Molecular Foundry

: Lab shuttles and the Molecular Foundry

: NERSC conference room

: LBNL shuttle stop

: Turkey life

: View from JCAP

: Stairs in Forest

: LBNL Greenery

: Interior of ALS Dome

: Sunset from Lawrence Hall of Science

: View of Bay Area

: LBNL Art Teal

: LBNL Art Dark Blue

: Molecular Foundry open work space

: Molecular Foundry open work space

: Molecular Foundry breakroom

: Shyh Wang workspace

: Shyh Wang conference room

: Building 50 hallway

: Building 50 office space

: Building 50 conference room

: Integrative Genomics Building

: Building 50 Auditorium

: Flexlab Building

: Emery Station East

: Whiteboard

: Ernest Orlando Lawrence, Donald Cooksey, and Edwin McMillan standing in front of the 60-inch cycloton, March 26, 1939

: Turkey trot

: BELLA

: Bubble Chamber

: Daya Bay Neutrino Experiment

: Cray Cascade Edison Supercomputer Cluster

: Cori Supercomputer

: Cori Supercomputer

: NANO Art: This spin-polarized LEEM image shows ultra-thin cobalt islands on an Ru(0001) crystal. The colorized areas highlight magnetic domain structures with various orientations. This material is used in magnetic memory or logic devices. The image was taken on the SPLEEM at NCEM by Foundry user Gong Chen of UC Davis.

: NANO Art: Peptoid diblock copolymers as short as 10 monomers long, self assemble into monolayer nanosheets with crystalline order. New cryo-EM imaging techniques were developed that allow us to easily resolve individual molecules (wedge-shaped white areas). Computer modeling the peptoids atoms into these shapes provides a detailed atomic model (green) of the peptoid lattice, including the ability to see individual bromine atoms (magenta) for the first time in a soft material. Work by Foundry users and staff: Sunting Xuan, Xi Jiang, Ryan K. Spencer, Nan K. Li, David Prendergast, Nitash P. Balsara, Ronald N. Zuckermann using the Foundry’s Theory and Biological Facilities.

: NANO Art: Elecrostatically actuated nanoneedles for massively parallelized precision gene editing on a chip. Precise gene editing of clinically relevant cells for gene therapies on a scalable chip. The precision and scalability of semiconductor manufacturing is applied to the application space of cell reprogramming to cure disease and power fundamental biological discoveries. Work by Foundry industry users Mark Webb and the Mekonos Team using the Foundry’s Nanofabrication Facility.

: NANO Art: A metal organic framework (MOF) material that has great potential to be used as a hydrogen storage material to power cars and machines. Work by Foundry user Han Wang using the Foundry’s Theory Facility.

: NANO Art: This image shows a polymer electrolyte film which can be used to prepare lithium-metal batteries. It consists of two kinds of linked long-chained molecules which assemble into ordered, interpenetrating structures. The image was colored to accentuate the sample’s intricate morphology and a defect in the film which stems from the casting process. The sample was prepared by Foundry user Jacqueline Maslyn from the group of Prof. Nitash Balsara and the micrograph was taken by user Alexander Müller from the group of Prof. Andrew Minor at NCEM.

: NANO Art: This illustration depicts in situ photoluminescence (PL) spectra used to monitor the growth of CsPbBr 3 perovskite nanoplatelets via colloidal synthesis. Lateral size, width and corresponding emission wavelength are finely tuned to obtain 2–6 unit cell thick nanoplatelets. Submitted by Carolin Sutter-Fella.

: NANO Art: This is a scanning tunneling microscopy image of tungsten disulfide showing the atomic scale electronic structure. A single sulfur atom has been replaced by a carbon atom causing a dramatic change in the local electronic environment, resulting in this fiery cloud of electrons. Atomically thin WS2 has many different applications, from QIS to flexible electronics. The image was taken on the low temperature scanning tunneling microscope in the Imaging facility by Foundry users and staff: Katherine A. Cochrane, Bruno Schuler, and Alex Weber-Bargioni.

: NANO Art: This image shows a polymer electrolyte film which can be used to prepare lithium-metal batteries. The polymer consists of two kinds of linked long-chained molecules which assemble into ordered, alternating lamellar structures. These in turn form large (blue) and small (yellow) grains. Submitted by Alexander Mueller.

: NANO Art: The micromachining capability of the laser used for this image allows us to produce nanoscale electrodes and specialized AFM resonators. The polymer featured here exhibits both chemical resistance and electrical insulation for a variety of applications. Work by Foundry industry users Hilary Brunner, Christina Newcomb, and Dominik Ziegler from Scuba Probe Technologies using the Foundry’s Nanofabrication Facility.

: NANO Art: Spontaneous crystallization of organic semiconductor molecules into fractal patterns, as seen in this polarized optical microscopic image. These crystals can be ink-jet printed for use in flexible electronics. Work by Foundry user Christopher L. Anderson using the Foundry’s Organic Facility.

: NANO Art: Under polarized light, ice crystals reveal life-saving secrets in a colorful wonderland. (Top) Water freezes into large hexagonal ice crystals; (Bottom) Antifreeze protein from arctic fish alters the ice crystals into a dual pyramid shape. (Middle) Nature-inspired, ice-interactive peptoid “XT-ViVo” makes smaller, rounder, and safer ice crystals than nature. The image was taken at the Biological Nanostructures Facility on the Nikon Optiphot-POL polarized microscope with X-Therma Cryostage by Xiaoxi Wei of X-Therma Inc., including assistance by Mark Kline, Adam Childs, Mussie Gide, and Andrea Callegari.

Change your Zoom background on the desktop app

1. In the Zoom app, click your profile in the top right corner, and click Settings.

2. On the menu to the left, click Virtual Background.

3. You’ll see a few default background options provided by Zoom, including an outer space scene or blades of grass. You can choose one of those by clicking on it, and it will automatically change your screen as well. There’s also an option for if you have a green screen and want to use that.

4. If you want to upload a photo to use as your background, on the same Virtual Background Page, click the + icon next to where it says Choose Virtual Background. A box will pop up allowing you to upload a photo from your computer. Click on the one you want, and it will appear alongside the other pictures as an option for you to choose from.

5. To get rid of any photos you upload, tap the X in their top left corner.

Change your Zoom background on the mobile app

1. When you log into your account and join a meeting, tap the three dots at the bottom right of the screen to open the More menu.

2. Tap Virtual Background.

3. Select a background from the default options, or upload your own.

LBNL Zoom Backgrounds

Follow us on Instagram

Other News