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Chapter 3

Fabrication of Accelerometer

3.1 Introduction

There are basically two approaches for bulk micromachining of

silicon, wet and dry. Wet bulk micromachining is usually carried out

using anisotropic etchants like KOH (Potassium Hydroxide), TMAH (Tetra

Methyl Ammonium Hydroxide) and EDP (Ethylene Diamine Pyrocatecol).

Dry micromachining of silicon is done using Flourine based plasma

chemistry. For the fabrication of accelerometer, the wet bulk

micromachining approach is selected because of two major reasons (1)

proof-mass and beams are having different thicknesses (2) beams need to

be centralized w.r.t the proof-mass. Another critical process developed

here is controlled wet oxidation and precisely controlled patterning of

silicon dioxide using BHF (Buffered Hydro Fluoric acid). Silicon dioxide

is used as a mask for etching in KOH.

3.2 Wet bulk micromachining

Anisotropic chemical wet etching is a key technology in fabricating

Micro Electro Mechanical Systems (MEMS). A substantial amount of

research has been conducted to understand the mechanism and

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eventually control the etched shape. Seidel et al. [40] Seidel [41] and

Glembocki et al. [42] and Palik et al. [43] modeled the etching process

and investigated the etching properties under a variety of KOH etching

conditions.

3.2.1 Theory

Single-crystal silicon has a diamond lattice structure as shown in

fig 3.1.

Fig 3.1 Silicon crystal structure

Each silicon atom has four covalent bonds. Each bond connects a

different pair of atoms. Silicon, with its four covalent bonds, coordinates

itself tetrahedrally, and these tetrahedrons make up the diamond-cubic

structure. This structure can also be represented as two

interpenetrating Face-Centered Cubic (FCC) lattices, one displaced w.r.t

the other. The lattice parameter „a‟ for Silicon is 5.4309 A and Silicon‟s

diamond-cubic lattice has a packing density of 34%, compared to 74%

for a regular FCC lattice. The {111} planes present the highest packing

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density and the atoms are oriented such that three bonds are below the

plane.

When an atom is located on a surface, the bond belonging to the

atom loses a neighboring atom. It is known as a dangling bond. The

dangling bonds easily react with the etching agent. Though, in many

cases, the dangling bonds do not remain free-ended, that is, the surface

bonds are reconstructed by combining with each other in high vacuum,

or the bonds are terminated with hydrogen atom in water, those bonds

on the surface are still a source of surface reactions, i.e., etching. When

the number of dangling bonds on three differently oriented surfaces,

(100), (110), and (111) are compared, it is apparent that the (111) surface

has the smallest number of bonds. There is only one dangling bond per

surface atom for (111), whereas there are two for (100), and one dangling

bond plus two surface bonds for (110). This is a conventional

explanation for why (111) is stable against etching. Experimentally it is

found that in pure KOH solutions, {110} planes exhibit highest etching

rate. According Seidal et al, [10] the back bonds and the energy levels of

the associated surface states is not necessarily the same for {110} and

{111} planes, as that energy will also be influenced by the effect of the

orientation of these bonds. Another argument in favor of high etching

rates of {110} planes is the easier penetrability of {110} surfaces for water

molecules along the channels in that plane [46].

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3.2.2 Etching solutions

Solutions showing orientation dependence on the etch rate of

silicon are KOH, TMAH, EDP (Ethylenediamine and Pyrocatecol), N2H4

(hydrazine) and NaOH. All are used as water solutions. The chemical

reaction for any of these etching solutions is described as follows:

𝑆𝑖 + 2𝑂𝐻− + 2𝐻2𝑂 𝑆𝑖𝑂2(𝑂𝐻)22− + 2𝐻2

Silicon reacts with water and an OH- ion and produces hydroxide ion and

hydrogen gas bubbles. Etching masks are usually made of either SiO2 or

Si3N4.

KOH shows strong anisotropy, and shows large values of etch rate

ratios among orientations of about (100). It means that high

controllability can be expected in etched profiles, while suppressing

mask undercut. KOH solutions are less toxic than other etchants, hence

are easy to process. These are the main reasons why KOH is widely used

for fabricating silicon microstructures in industry.

A drawback with KOH is that, it etches SiO2 mask also

significantly during long etching time. Selectivity of Si to SiO2 mask is

about 150 under normal conditions. Another drawback is that KOH

etching is incompatible to IC processes because contamination with

potassium ion is strictly prohibited in IC processes.

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3.2.3 Etching shapes

Etching shapes are categorized into two, one is concave-etched

profiles and the other is convex etched profile. Concave-etched profiles

on silicon wafers have been fabricated so far for applications in pressure

sensors and ink-jet printer head structures. In the case of concave

profiles, orientations having an etch rate that is locally minimum appear

and Si (111) is the only orientation that has an etch rate of a local

minimum for any etching conditions.

Incase of convex profiles, orientations having an etch rate that is

locally maximum appear. It becomes far more difficult to predict and to

control etch profiles having large etch rates. Again, characterization of

anisotropy in etch rate is of great importance. The planes occurring at

convex corners during anisotropic etching of (100) silicon in aqueous

KOH were identified as {411} planes [40]. The etching rate of these

planes in relation to the rate of the {100} planes declines with increasing

Potassium Hydroxide concentration. In contrast, the temperature

dependence of this etch rate ratio is negligible in the relevant range

between 60°C and 100°C.

3.2.4 Silicon dioxide as masking material

In the case of KOH etching, the etch rate of SiO2 is not negligible,

even if it is a thermally grown oxide. With 40% KOH solution at a

temperature of 60°C, it is experimentally verified that etching rate of SiO2

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is about 80 nm/hr. Growth of thin Oxide films (<1 µm) and multiple

oxidation steps are incorporated into the process to improve the quality

of oxide and also to reduce the pinhole density. The disadvantage of

higher etch rate of SiO2 when compared to other masking materials like

Si3N4, is converted into an advantage in the process for fabrication of

accelerometer structure by in-situ removal of oxide mask of required

thickness during silicon etching itself. Other advantages of using SiO2

as mask are easy to grow by thermal oxidation and easy to remove using

HF-based solutions.

3.2.5 Corner undercutting and compensation

When etching rectangular corners, deformation of the edges

occurs due to under cutting. This is an unwanted effect especially in the

fabrication of acceleration sensors where total symmetry and perfect 90o

convex corners on the proof-mass are mandatory for good device

prediction and specification. The undercutting is a function of etch time

and thus directly related to the desired etch depth. An undercut ratio is

defined as the ratio of undercut to etch depth.

Saturating KOH solutions with isopropanol (IPA) reduces the

convex corner undercutting. Unfortunately, this happens at the cost of

the anisotropy of the etchant. Undercutting can also be reduced or even

prevented by corner compensation structures which are added to the

corners in the mask layout. Depending on the etching solutions,

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different corner compensation schemes are used. Commonly used

techniques are square compensation (EDP or KOH) and rotated

rectangle corner compensation methods (KOH) [46]. The second method

for corner compensation technique is used in this case.

In the rotated rectangular corner compensation method, a

properly scaled rectangle (Breadth „B‟ should be twice the etch depth „De‟)

is added to each of the mask corners. The four sides of the mesa square

(proof-mass) are still aligned along the <110> directions, but the

compensation rectangles are rotated 45o with their longer sides along the

<100> directions. The rectangular bar along <100> direction is undercut

by KOH along three preferential directions, namely <100> sidewalls,

<410> sidewalls and <410> of the free end [44]. When the length of the

<100> bar is kept at 1.6 B (for 33% KOH), the undercut of the latter two

directions should stop first, and only the lateral (100) sidewalls etching

determines the final undercut. Thus, the etching rate is the same as

that of the (100) etching along with the depth, so if the width of the bar is

twice the etching depth, complete convex corners can be obtained.

Here, etch depth De = 172 µm is used, as etching takes place from

both sides of the wafer (344 µm thick). Width of the rotated rectangle is

B = 344 µm and Length L= 1.5 x 344 = 516 µm. The factor 1.5 comes

from the fact that 40% KOH is used. This is explained further in section

3.3.2. But here, in the last KOH etching step, the mask above the proof-

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mass is also removed for bringing down the proof-mass thickness to 300

µm. Therefore, the effective depth for which the corner compensation

mask was retained is only ((344 - 44)/2 = 150 µm). Taking this into

account, the new values are B = 300 µm and L = 450 µm. Considering

process alignment tolerances, the final values are finalized as B = 310

µm and L = 460 µm as shown in fig 3.2.

Fig 3.2 Corner compensation of the proof-mass

(LHS – full view and RHS – Zoomed view)

3.3 Simulations in Intellisuite

AnisE, an anisotropic etch process simulation tool from

Intellisuite software is used for anisotropic etching simulation. The input

to this is a two dimensional mask and the output is the three

dimensional etched structure. The mask used looks as shown in fig. 3.3.

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Fig 3.3 Mask without corner compensation

The mask shown is used for etching the (100) plane of silicon wafer with

40% KOH concentration, at temperature 60oC.

Fig 3.4 Structure after etch simulation

After etching, the silicon structure is as shown in fig.3.4. The

structure consists of a proof -mass and four beams whose thickness is

same as that of the proof-mass. The beams are attached to a frame of

thickness 300 microns. It is apparent from the figure that the corners of

the proof-mass and the beams are etched off. The deformation of the

edges occurs due to undercutting and this necessitates the use of

compensation structures.

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3.3.1 Dimensions of corner compensation structure

The experiments of Mayer et al showed that the undercutting of

convex corners in pure KOH etches are determined exclusively by {411}

planes. At the wafer surface, the sectional line of {411} and a {111} plane

points in the <410> direction, forming an angle of 30.96o with the <110>

direction. From literature [44], it is clear that for a rotated rectangle

compensation structure, the width „B‟ should be equal to twice the etch

depth if etching is done from only one side. Meanwhile, the necessary

length of the compensation bar depends on its width, hence the etching

depth as well as the ratio of etching rates of <410> and <100> [45]. The

length of the rectangle is given by L = 1.6 B for 33% KOH [44]. This is

verified using Anis-E module of Intellisuite. Here one of the corners of the

proof-mass is covered with compensation rectangle structure. The

structures after etching are shown in fig 3.5. For 40% KOH solution, the

length is even shorter and can fairly approximated as L = 1.5 B taking in

to account of the fact that the lateral etching (Etch rate along <410> /

Etch rate along <100>) decreases with increase in concentration of KOH

[44].

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L = B L = 1.2 B

L = 1.4 B L = 1.6 B

Fig 3.5 Proof-mass structures showing effect of length

variation of compensation mask (33% KOH)

3.3.2 Centralization of beams with respect to proof-mass

To realize the beams at the center of the proof-mass, a technique

known as self aligned etching is used. The anisotropic etching of KOH

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takes place in three phases. In the first phase, the silicon wafer is etched

for 55µm by masking the proof-mass and beam areas. In the second

phase of etching silicon, the beams are unmasked and the structure is

realized with the proof-mass of whole wafer thickness and the beams are

centralized with a thickness of 99 µm. In the final phase of etching

(44µm), the oxide over the proof-mass is also removed and the complete

structure is realized with a proof-mass thickness of 300 µm and beam

thickness of 55µm. The etched structure looks as shown in fig 3.6 (a)

and (b).

Fig 3.6(a) Etch simulation

result after first phase etching

Fig 3.6(b) Etch simulation

result after final phase etching

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3.4 Process flow for fabrication

3.4.1 Silicon wafer processing for microstructure

fabrication

1. (100) Oriented P-type silicon wafer 344 5 µm Thick, Resistivity

of 0.1-cm

The processed wafer thickness measured is 344 µm.

2. Wet thermal oxidation for a final oxide thickness of 1.1µm

Silicon

SiO2

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3. Pattern oxide in the contact area. Oxide is etched using BHF to depth

of 0.2µm.(Mask1)

Photoresist

MASK 1

The etch rate of silicon dioxide in BHF is 0.1µm / min. The above step is

required since in the final step, a bulk BHF etching of oxide is to be

carried out to open the contact area and also to reduce the oxide

thickness in the frame area to 0.15µm-0.2µm. This step also has the

added advantage of providing better aligning of the subsequent masks as

the contact pad area lies at a fixed distance from the proof-mass – beam

area.

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4. Oxide patterning with BHF in mass-beam area (Mask – 2)

MASK 2

5. Wet thermal oxidation in the mass-beam area for a thickness of

0.75µm

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6. Oxide etching using BHF in the beam area (Mask 3)

MASK 3

7. Wet thermal oxidation in the beam area for a thickness of 0.15µm

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8. Oxide etching using BHF in the through etching area (Mask 4)

MASK 4

9. First Phase KOH etching from both sides

KOH concentration : 40%

Temperature : 60oC

Etch depth from one side : 27.5 µm

Total Silicon thickness removed

from through etching area : 55 µ

Etch rate : 44 µm / hr

Time of etch : 37.5 mins

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Masking material (SiO2) etch rate : 0.08 µm / hr

Thickness of oxide removed from beam area : 0.05 µm

Thickness of oxide remaining in beam area : 0.1 µm

10. Oxide etching using BHF in the beam area

Etch rate of oxide in BHF : 0.1 µm /min

Time of etch : 1 min

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11. Second phase KOH etching from both sides

KOH concentration : 40%

Temperature : 60oC

Etch depth from one side : 122.5 µm

Total silicon thickness removed

from through etching area : 300 µm

Total silicon thickness removed

from beam area : 245 µm

Etch rate : 44 µm / hr

Time of etch : 167 mins

`

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Masking material (SiO2) Etch rate : 0.08 µm / hr

Thickness of oxide removed from proof-mass area : 0.25 µm

Thickness of oxide remaining in proof-mass area : 0.5 µm

12. Oxide etching using BHF in the proof-mass area

Etch rate of Oxide in BHF : 0.1 µm /min

Time of etch : 5.0 min

13. Third and final phase KOH etching from both sides

KOH concentration : 40%

Temperature : 60oC

Etch depth from one side : 22 µm

Total silicon thickness removed

from through etching area : 344 µm

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Total silicon thickness removed

from beam area : 289 µm

Beam width achieved : 344 – 289 = 55 µm

Proof-mass thickness achieved : 344 – 44 = 300 µm

Etch rate : 44 µm / hr

Time of etch : 30 mins

Masking material (SiO2) etch rate : 0.08 µm / hr

Thickness of oxide removed from contact area : 0.04 µm

Thickness of oxide remaining in contact area : 0.86 µm

14. Oxide etching using BHF in the contact area

Etch rate of Oxide in BHF : 0.1 µm /min

Time of etch : 8.6 min

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Maximum Oxide thickness left in the frame area: 0.2µm (Refer Table 3.1)

15. Evaporate 1500 Ao Al for contact pad (Mask 5)

MASK-5

Al

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Area

Maximum Thickness of Silicon dioxide (in microns)

remaining after

Oxidation 1st

Phase

KOH Etch

1st

Phase

BHF dip

2nd

Phase

KOH Etch

2nd

Phase

BHF dip

3rd

Phase

KOH Etch

3rd

Phase

BHF dip

Beam 0.15 0.1 0 - - - -

Proof-mass

0.9 0.85 0.75 0.5 0 - -

Contact 1.8 1.75 1.65 1.4 0.9 0.86 0

Frame 2.0 1.95 1.85 1.6 1.1 1.06 0.2

Table 3. 1 Thickness of Silicon dioxide in different regions at different stages of etching

Fig 3.7 Top view of the processed silicon die

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3.4.2 Top glass wafer processing

1. 100 mm Pyrex 7740 Glass wafer with a thickness of 500µm

2. Evaporate 1500 A0 Al, on one side of the wafer

3. Pattern Al using Mask 6

Glass

Al

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4. Pre dicing trenches are formed in top glass wafer with depth and

width of 100 µm.

3.4.3 Bottom glass wafer processing

MASK –6

1. 100 mm Pyrex 7740 Glass wafer with a thickness of 500µ

Glass

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2. Evaporate 1500 Ao Al, on one side of the wafer

3. Pattern Al using Mask 7

4. Wafer edge is also diced for placing electrode on Silicon during top

glass anodic bonding process

5. The three separately processed wafers are anodically bonded together

and diced using mechanical dicing equipment. The exploded view of

Al

MASK –7

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the diced chip is shown in fig 3.8. The total size of the chip is

9 mm x 8 mm x 1.344 mm

Fig 3.8 Exploded view & assembled view of the accelerometer chip

3.5 Results and discussion

Fig 3.9 shows the Scanning Electron Microscope (SEM) picture of

the proof-mass cross-section. The designed dimensions of the proof-

mass with rectangular cross-section were 2500 µm x 2500 µm x 300 µm.

Due to anisotropic etching, the fabricated proof-mass has hexagonal

cross - section and the dimensions achieved are 2458 µm x 2458 µm x

300 µm. This is fairly good result taking into account the complexity of

fabrication.

Fig 3.10 shows the SEM picture of the beam cross-section. The

designed dimensions of the rectangular cross section of beam were

150 µm x 55 µm and the achieved dimensions are 176 µm x 49 µm.

Here, the thickness of beam is reduced by 6 µm, and width increased by

26 µm, so the moment of inertia of beam reduces by 0.83

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times compared to the designed rectangular cross-section beam. This is

expected to cause 20% increased deflection & sensitivity.

Fig 3.9 SEM picture of the proof-mass and beam

Fig 3.10 SEM picture of the beam cross section

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Fig 3.11 Sharp corners realized on proof-mass and L-beams

Fig 3.12 Photograph of the diced sensor chip in its final form

Fig 3.11 shows the clean and sharp corners realized on the corners of the

proof-mass and on L-beams. This validates the corner compensation

design technique used in the thesis. Fig 3.12 shows the diced chip in its

final form. As shown here the top glass is diced in such a way that all the

electrical pads are accessible for further wire bonding.