Uncoated TEM Grids

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.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Double grids, offering a combination of mesh support values, are used primarily in metallurgical applications for supporting thin metal foils. Two grids are joined by a thin 'hinge', allowing one grid to be folded on top of the other, trapping the specimen between them.

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns

Aperture grids consist of one central circular hole. The larger the aperture dimension, the thicker the grid, for maximum rigidity. Overall thickness variation : GA75: 25 microns, +/- 3 microns, GA2000: 50 microns, +/- 5 microns