Uncoated TEM Grids

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.

A 15 by 15 grid of cells is indexed with letters representing columns, and numbers representing rows. Each cell is asymmetrical due to a marking at every grid bar intersection, similar to the centre marking detailed on the Centre/yes Specs page, allowing grid orientation to be determined at microscopic levels.

A 15 by 15 grid of cells is indexed with letters representing columns, and numbers representing rows. Each cell is asymmetrical due to a marking at every grid bar intersection, similar to the centre marking detailed on the Centre/yes Specs page, allowing grid orientation to be determined at microscopic levels.

A 15 by 15 grid of cells is indexed with letters representing columns, and numbers representing rows. Each cell is asymmetrical due to a marking at every grid bar intersection, similar to the centre marking detailed on the Centre/yes Specs page, allowing grid orientation to be determined at microscopic levels.

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.

24 blocks of 9 cells are identified by a letter built into the centre cell of each block.

24 blocks of 9 cells are identified by a letter built into the centre cell of each block.

24 blocks of 9 cells are identified by a letter built into the centre cell of each block.

Each of the 60 square grids is identified using a base two binary numbering system. The six binary number symbols appear on the bottom grid bars along the horizontal axis. Zero is represented by a short pillar and one by a longer pillar.

Each of the 60 square grids is identified using a base two binary numbering system. The six binary number symbols appear on the bottom grid bars along the horizontal axis. Zero is represented by a short pillar and one by a longer pillar.

Each of the 60 square grids is identified using a base two binary numbering system. The six binary number symbols appear on the bottom grid bars along the horizontal axis. Zero is represented by a short pillar and one by a longer pillar.

Molybdenum grids are especially useful in ion milling applications because of its resistance to etching.

The G2010 slot grid has an overall thickness of ~50 microns. The grid type number corresponds to the overall slot size in mm eg. G2010 = 2x1mm slot. Molybdenum grids are especially useful in ion milling applications because of its resistance to etching.

The G2010 slot grid has an overall thickness of ~50 microns. The grid type number corresponds to the overall slot size in mm eg. G2010 = 2x1mm slot.

The G2010 slot grid has an overall thickness of ~50 microns. The grid type number corresponds to the overall slot size in mm eg. G2010 = 2x1mm slot.

The G2010 slot grid has an overall thickness of ~50 microns. The grid type number corresponds to the overall slot size in mm eg. G2010 = 2x1mm slot.