Uncoated TEM Grids

The GT2000 is the grid with the finest grid currently available. It is produced using the latest lithographic techniques. It is a grid with hexagonal holes, which appear round due to the size and coating. This type was introduced by Gilder Grids in 2014.

The GT2000 is the grid with the finest grid currently available. It is produced using the latest lithographic techniques. It is a grid with hexagonal holes, which appear round due to the size and coating. This type was introduced by Gilder Grids in 2014.

The GT2000 is the grid with the finest grid currently available. It is produced using the latest lithographic techniques. It is a grid with hexagonal holes, which appear round due to the size and coating. This type was introduced by Gilder Grids in 2014.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

322 cells are uniquely identified by an alphanumeric code. At light microscope level, this code can be referenced from the letters and numbers on the rim of the grid, representing rows and columns respectively. At the electron microscope level, the row letter is indicated by a symbol to the bottom left of the cell. The column number is indicated by a binary coding attached to the baseline of the cell.

322 cells are uniquely identified by an alphanumeric code. At light microscope level, this code can be referenced from the letters and numbers on the rim of the grid, representing rows and columns respectively. At the electron microscope level, the row letter is indicated by a symbol to the bottom left of the cell. The column number is indicated by a binary coding attached to the baseline of the cell.

322 cells are uniquely identified by an alphanumeric code. At light microscope level, this code can be referenced from the letters and numbers on the rim of the grid, representing rows and columns respectively. At the electron microscope level, the row letter is indicated by a symbol to the bottom left of the cell. The column number is indicated by a binary coding attached to the baseline of the cell.

An alpha-numerical code identifies 48 blocks of 6 cells, delineated by thicker grid bars. Each block's code is attached to the baseline of its centre-bottom cell, letters representing rows and numbers representing columns.

An alpha-numerical code identifies 48 blocks of 6 cells, delineated by thicker grid bars. Each block's code is attached to the baseline of its centre-bottom cell, letters representing rows and numbers representing columns.

An alpha-numerical code identifies 48 blocks of 6 cells, delineated by thicker grid bars. Each block's code is attached to the baseline of its centre-bottom cell, letters representing rows and numbers representing columns.

The GT2000 grid represents the finest mesh grid that is currently available. It is manufactured using modern electron beam lithography techniques. It has found use in applications as diverse as vitreous ice (noncrystalline ice) specimen techniques to x-ray calibration.

The GT2000 grid represents the finest mesh grid that is currently available. It is manufactured using modern electron beam lithography techniques. It has found use in applications as diverse as vitreous ice (noncrystalline ice) specimen techniques to x-ray calibration.

The GT2000 grid represents the finest mesh grid that is currently available. It is manufactured using modern electron beam lithography techniques. It has found use in applications as diverse as vitreous ice (noncrystalline ice) specimen techniques to x-ray calibration.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GTH series offers a very high transmission value with the additional support of a hexagonal pattern. They offer an alternative to the standard hexagonal mesh grids for use in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GTH series offers a very high transmission value with the additional support of a hexagonal pattern. They offer an alternative to the standard hexagonal mesh grids for use in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GTH series offers a very high transmission value with the additional support of a hexagonal pattern. They offer an alternative to the standard hexagonal mesh grids for use in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

The GT series are a development from the earlier GTH ultra-high transmission grids. They offer an alternative to the standard square mesh grid. Fine Bar grids offer solutions in applications where it is important that the maximum area of specimen is available for viewing in the microscope.

As an alternative to square mesh, hexagonal mesh grids offer a higher support factor for a given mesh repeat distance.

As an alternative to square mesh, hexagonal mesh grids offer a higher support factor for a given mesh repeat distance.

As an alternative to square mesh, hexagonal mesh grids offer a higher support factor for a given mesh repeat distance.