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Knowledge Base Fact Sheet

What the parameters mean in the wafer selection guide nomenclature charts.

Silicon Wafers

Silicon wafers are a thin slice of semiconducting material that is widely used in the production of electronic and micromechanical devices. They are characterised by a number of parameters, which affect their suitability and performance for a chosen tasks.

1. Wafer diameter

Diameter of the wafer listed in mm. Typically wafers are talked about in inches; typical sizes are 2”,3”,4”,5”,6”,8”& 12” – with 4”,6” and 8” the most commonly used in industry and academia.

2. Type

Type refers to the electrical behaviour of the wafer. Intrinsic (I), behaves as pure silicon. N-type, dominate charge carriers are electrons. P-type, dominate charge carriers are holes. Whether a wafer is P-type or N-type will affect the electrical response of  any device manufactured.

3. Crystallographic Orientation

Wafers are grown as single crystals that have an ordered, regular and repeating structure.  When they are sliced from the ingot the flat surface is aligned along one of several relative directions, known as the orientation. The orientation is classified by Miller indices, typical indices are (100), (110) and (111). Orientation affects the physical properties of the silicon wafers – how it is etched, ion implantation and how it integrates with other materials

4. Dopant

The dopant is a material that has been deliberately implanted in the silicon to change the TYPE of the silicon. TYPE and DOPANT are linked.

Typical N-type dopants are Phosphorus, Arsenic, and Antimony. These all provide an extra electron to the silicon which is then free to carry current.

Typical P-type dopants are Boron, Gallium. These have one less electron and so leave a ‘hole’ in the silicon lattice which is free to carry current.

5. Growth Method

The growth method refers to the process by which the silicon ingot is grown. There are two main techniques: Czochralski Zone (CZ) and Float Zone (FZ).

CZ: This is the dominant method used to grow commercial silicon wafers due to the better resistance to thermal stress, speed of production and low cost. CZ involves the heating a crucible of polycrystalline silicon until it melts; then dipping a seed of single crystal silicon in and withdrawing slowly to produce an ingot of crystalline silicon.

FZ: This is a high purity alternative to the CZ method. A polycrystalline rod of silicon and a single crystal seed are held face to face and rotated. The rod is then heated by a thin ring and the seed brought in to contact with the tip. The molten silicon orders itself into the single crystal and the heating zone is slowly moved up and the ingot of silicon extends. FZ produces high purity and high resistivity Si than typically possible in CZ processes.

6. Grade

Grade refers to the variety in the quality of the wafers. Typically these are PRIME, TEST and RECLAIMED.

  • Prime are the highest quality and produced to the highest tolerances on flatness, cleanliness and polish
  • Test are similar to prime, except with less rigourous specifications to flatness and cleanliness.
  • Reclaimed are wafers that have been stripped and polished of any previous patterning or processing.

There are sometimes other grades of Si wafer mentioned but these are either synonyms of the above or have a specific tolerance on a certain parameter.

7. Material

The material is the bulk material of the wafer, typically silicon, but this may vary, some transparent substrates such as glass or quartz are needed for optical devices and more exotic compound materials such as GaAs or InP for specific band gaps.

8. Resistivity

Resistivity is the measure of the resistance to current flow and the movement of the charge carriers (either holes or electrons) through the silicon. Resistivity is measured in Ohm-cm. The dopant level can be adjusted to reach target resistivities, with higher doping lowering the resistivity.

9. Thickness

The thickness of the silicon wafer affects the mechanical properties and is typically expressed in µm (microns) and with a tolerance (± ? µm), The tolerance is measured through a total thickness variation (TTV).

10. Polish

Wafer polishing is the final step in the manufacture of silicon wafers, which allows the production of a smooth, super-flat mirrored surface. There are two options for polishing: single side polish (SSP) and double side polish (DSP)

SSP: Only one face is polished, the second (the backside) is etched.

DSP: Both faces are polished, giving a high flatness to the wafer.

11. Alignment Fiducial

Alignment fiducial refers to the flats or notches used to identify the wafer. Originally flats were used to identify TYPE and well as ORIENTATION but now there is less convention about what the flats mean and notches are quite common on 8” (200mm) wafers.

12. Other

At Inseto, we use other to indicate if the wafers are laser marked with a unique identifier or if they have been stacked in a particular manner.

Cassette of Prime Silicon Wafers

Coated Wafers

Coated wafers are a subset of silicon wafers where either one or both surfaces have been coated with an additional material. In the Inseto naming convention they are characterised by COATING – the material the wafer is coated with; and COATING THICKNESS – the thickness of that coating, typically µm, nm or Å.

a. Oxide wafers

One typical coating requested is an Oxide coating. This can be a thermal oxide coating (ATOx) which always coats both sides of the wafer. ATOx stands for atmospheric thermal oxide. Other oxide coating methods include:

Dry Oxide – which produces a thinner oxide layer but with a higher uniformity film.

PECVD Oxide – produces a coating on a single side of the wafer

b. Nitride wafers

A second typical coating requested is a Nitride coating. Silicon Nitride (SiN) offers different mechanical and chemical properties to oxide layers. The nitride can be depositied by PECVD, LPCVD or low stress LPCVD. These variants are changes in the method of deposition and alter the final physical and mechanical properties of the film.

Oxide Coated Silicon Wafers

Glass Wafers

Glass wafers are generally used where the substrate is required to be transparent. At Inseto we separate out these from silicon and coated silicon wafers as they have some distinct parameters which inform your selection.

1. Wafer diameter

As with Silicon wafers, the diameter is typically listed in mm but may be referred to in inches. 

2. Material

This lists the material the glass is made from, typical options include Borosilicate, Fused Quartz, Fused Silica and Crystal Quartz. Some people use these terms interchangeably or will drop the ‘fused’ and ‘crystal’ terms

3. Crystallographic Orientation

Fused Quartz and Fused Silica have no orientation as they are not crystalline materials. Crystal quartz however does and can be X-Cut, Y-Cut, AT-Cut and ST-Cut depending on how the wafer is removed from the larger crystal.

4. Grade

The grade of the glass wafer listed here refers to the manufacturers specifications. Each has its own specific chemical, mechanical and optical properties.

5. Thickness

As with Silicon wafers this refers to the thickness and tolerance of the wafer, typically listed in µm.

6. Polish

As with Silicon wafers this refers to the finish on the surface of the glass and can be either SSP or DSP. Alongside this there is a rating X/Y. where both X and Y are numbers. X refers to the width of a scratch in µm and Y the diameter of a dig, pit or bubble in hundreths of a mm.

7. Edge Shape

This denotes how the edge of the glass wafer has been shaped. Most commonly a C shape, but chamfered and square cut are also options.

8. Alignment fiducial, Coating type, Coating thickness

The final 3 parameters we listed are alignment fiducial, coating type and coating thickness and contain the same information as in the Silicon wafers

Silica Wafers for Semiconductor Research

SOI Wafers

The last wafer type we separate out is SOI (Silicon on Insulator). SOI wafers make use of a silicon – insulator –silicon substrate and are used for specific applications where reducing parasitic capacity in the device is crucial. The choice of insulator within the silicon sandwich is highly specific to the application but silicon dioxide and sapphire are typical choices for microelectronics and radio frequency applications respectively.  The top layer of silicon is referred to as the ‘device’, the bottom layer the ‘handle’.

There are some standard parameters listed as with silicon wafers, these are Diameter, Type and crystallographic orientation. We then list the parameters specific to SOI wafers.

1. Device thickness

This is the thickness of the top layer of silicon, typically in µm

2. Growth Method

This is listed twice in an SOI wafer. First is the growth method of the device layer and can be CZ or FZ.

3. Device Resistivity

Measured as with a standard silicon wafer, this is the resistivity of the top layer of silicon in Ohm-cm

4. BOx

This is the thickness of the insulator layer or ‘buried oxide’ layer, hence BOx.  As with all thicknesses typically µm but can be nm or Å.    

5. Handle Thickness

The thickness of the bottom layer of silicon, typically in µm.

6. Growth Method

This second listing of growth method relates to the handle layer of silicon.

7. Handle Resistivity

Measured as with a standard silicon wafer, this is the resistivity of the bottom layer of silicon in Ohm-cm

8. Backside

This relates to how the backside of the handle layer has been treated and can be a variety of finishes including: Polished, etched, oxide, no oxide and laser marked.

SOI Prime Wafers





Chris Valentine


24 October 2019


IKB046 Rev. 1


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