EE C245 ME C218 Introduction to MEMS Design

EE C245 ME C218 Introduction to MEMS Design Fall 2007 Prof. Clark T.-C. Nguyen Dept. of Electrical Engineering & Computer Sciences University of California at Berkeley Berkeley, CA 94720 Lecture 10: Surface Micromachining i III / Mechanics of Materials EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 1

Lecture Outline Reading: Senturia Chpt. 3, Jaeger Chpt. 11, Handout: Surface Micromachining for Microelectromechanical Systems Lecture Topics: Polysilicon surface micromachining Stiction Residual stress Topography issues Nickel metal surface micromachining 3D pop-up MEMS Foundry MEMS: the MUMPS process The Sandia SUMMIT process EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 2

Foundry MEMS: The MUMPS Process EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 3

MUMPS: MultiUser MEMS ProcesS Originally created by the Microelectronics Center of North Carolina (MCNC) now owned by MEMSCAP in France Three-level polysilicon surface micromachining process for prototyping and foundry services Designed to service as many users as possible; basically an attempt to provide a universal MEMS process 8 photomasks $4,900 for 1 cm 2 dies Micromotor fabricated via MUMPS EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 4

MUMPS: MultiUser MEMS ProcesS Micromotor Example EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 5

MUMPS Process Flow Deposit PSG on the starting n- type (100) wafers Anneal to heavily dope the wafers Remove the PSG LPCVD 600 nm of low stress nitride LPCVD 500 nm of polysilicon Lithography using the POLY0(cf) mask and RIE etching to pattern the poly0 ground plane layer LPCVD 2 μm of PSG as the 1 st sacrificial layer Lithography using the DIMPLE(df) mask (align to poly0) RIE 750 nm deep to form dimple vias Lithography using the ANCHOR1 (df) mask (align to poly0) RIE anchor vias down to the nitride surface EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 6

Alignment: Choice of Aligning Layer EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 7

MUMPS Process Flow (cont.) LPCVD 2 μm undoped polysilicon LPCVD 200 nm of PSG Anneal for 1 hr. @ 1050 o C This both dopes the polysilicon and reduces its residual stress Lithography using the POLY1(cf) mask to define structures (align to anchor1) RIE the PSG to create a hard mask first, then RIE the polysilicon LPCVD 750 nm of PSG Lithography using the P1_P2_VIA (df) mask to define contacts t to the poly1 layer (align to poly1) EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 8

Utility of Hard Masks in Lithography EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 9

MUMPS Process Flow (cont.) Recoat with photoresist and do lithography using the ANCHOR2(df) mask to define openings where poly2 contacts nitride or poly0 (align to poly0) RIE the PSG at ANCHOR2 openings LPCVD 1.5 μm undoped polysilicon LPCVD 200 nm PSG as a hard mask and doping source Anneal for 1 hr @ 1050 o C to dope the polysilicon and reduce residual stress Lithography using the POLY2(cf) mask (align to anchor2) RIE PSG hard mask RIE poly2 film Remove PR and hard mask EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 10

Need to Anneal After Every Thick Dep EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 11

MUMPS Process Flow (cont.) Poly1 Rotor Poly1 Stator Lithography using the METAL (df) mask (align to poly2) Evaporate titanium (Ti) (as an adhesion layer for gold) Evaporate gold (Au) Liftoff ff to remove PR and define metal interconnects Coat wafers with protective PR Dice wafers Ship to customer Final Structure: Micromotor Customer releases structures by dipping and agitating dies in a 48.88 wt. % HF solution or via vapor phase HF Anti-stiction dry, if needed EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 12

polymumps Minimum Feature Constraints Minimum feature size Determined by MUMPS photolithographic resolution and alignment precision Violations result in missing (unanchored), under/oversized, or fused features Use minimum i feature only when absolutely l necessary Nominal [μm] Min Feature [μm] Min Spacing [μm] POLY0, POLY1, POLY2 3 2 2 POLY1_POLY2_VIAPOLY2 3 2 2 ANCHOR1, ANCHOR2 3 3 2 DIMPLE 3 2 3 METAL 3 3 3 HOLE1, HOLE2 4 3 3 HOLEM 5 4 4 EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 14

MUMPS Design Rules (cont.) Cross Sections Oxide1 Poly0 POLY0 Mask Levels ANCHOR1 EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 15

MUMPS Design Rules (cont.) Oxide1 Poly1 Poly0 G N H OK R Cross Sections POLY0 POLY1 Mask Levels ANCHOR1 EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 16

MUMPS Design Rules (cont.) EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 17

MUMPS Design Rules (cont.) EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 18

The Sandia SUMMIT Process EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 19

Sandia s SUMMiT V SUMMiT V: Sandia Ultra-planar Multi-level MEMS Technology 5 fabrication process Five-layer polysilicon surface micromachining i process One electrical interconnect layer & 4 mechanical layers Uses chemical mechanical polishing (CMP) to maintain planarity as more structural layers are realized 14 masks EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 20

SUMMiT V Layer Stack Uses chemical mechanical polishing (CMP) to maintain planarity as more structural layers are realized EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 21

Chemical Mechanical Polishing (CMP) Used to planarize the top surface of a semiconductor wafer or other substrate Uses U an abrasive b i and d corrosive i chemical h i l slurry l (i.e., (i a colloid) in conjunction with a polishing pad ª Wafer f and p pad are pressed p together g ª Polishing head is rotated with different axes of rotation (i.e., non-concentric) to randomize the polishing Carrier/Chuck Top View DI Water Slurry Slurry Carrier C i Chuck Pad EE C245: Introduction to MEMS Design Side View Pad Conditioner Platen Wafer Backing-Film Pad Pad Conditioner Lecture 10 C. Nguyen 9/30/08 22

CMP: Not the Same as Lapping Lapping Lapping is merely the removal of material to flatten a surface without selectivity Everything is removed at approximately the same rate Chemical Mechanical Polishing CMP is selective to certain films, and not selective to others Lapping Removes diff. materials at same rate CMP Stops at nonselective layer EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 23

Actual SUMMiT Cross-Section No CMP until after the first three polysi layers 1 μm mmpoly1 and 1.5 μm mmpoly2 can be combined to form a 2.5 μm polysilicon film Refer to the SUMMiT V manual (one of your handouts) for more detailed information on masks and layout instructions EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 24

New Topic: Mechanics of Materials Reading: Senturia, Chpt. 8 Lecture Topics: Stress, strain, etc., for isotropic materials Thin films: thermal stress, residual stress, and stress gradients Internal dissipation MEMS material properties and performance metrics EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 25

Vertical Stress Gradients Variation of residual stress in the direction of film growth Can warp released structures in z-direction EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 26

Elasticity EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 27

Normal Stress (1D) If the force acts normal to a surface, then the stress is called a normal stress z σ z x z σ y σ x y x y Differential volume element EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 28

Strain (1D) EE C245: Introduction to MEMS Design Lecture 10 C. Nguyen 9/30/08 29