Bruce Furnace Recipes Dr. Lynn Fuller Webpage: Electrical and Microelectronic Engineering

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ROCHESTER INSTITUTE OF TECHNOLOGY MICROELECTRONIC ENGINEERING Bruce Furnace Recipes Dr. Lynn Fuller Webpage: http://people.rit.edu/lffeee Electrical and 82 Lomb Memorial Drive Rochester, NY 14623-5604 Tel (585) 475-2035 Fax (585) 475-5041 Email: Lynn.Fuller@rit.edu Department Webpage: http://www.microe.rit.edu 7-5-2014 Bruce_Furnace.ppt Page 1

OUTLINE Bruce Furnace Bruce Furnace Recipes Advanced Recipes Calculations List of Recipes Recipe Details Measurement of Oxide Thickness Recall of Run Data Stabilization After Push Non Uniform Oxide Growth Problems SPC Out of Control Action Plans Bake of Spin-on Dopants Creating New Recipes References PLAY BACK NEXT Page 2

BRUCE FURNACE Tube 1 Tube 2 Tube 3 Tube 1 Steam Oxides Tube 2 P-type Diffusion Tube 3 N-type Diffusion Tube 4 Dry Oxides and Gate Oxides Tube 4 Page 3

BRUCE FURNACE RECIPES 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 40min 5min 40 min 12 min 1 1 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 Page 4

ADVANCED FURNACE RECIPES 1100 C Denude 10-40 µm 1100 C Well Drive and grow to 1000 A radius Push 600 C Nucleation 50 A radius sites Pull 12 min 10 lmp N2 20 min 10 lmp O2 240 min 15 lmp N2 40 min 10 lmp N2 48 hrs 10 lmp N2 40 min 10 lmp N2 16 hrs 10 lmp N2 40 min 10 lmp N2 12 min 15 lmp N2 15-20 ppma Oxygen Starting Wafers Page 5

OXIDE GROWTH Oxide Thickness Xox Original Silicon Surface 0.46 Xox Silicon Consumed Dry oxide O2 only Wet oxide O2 bubbled through water Steam burn H2 in O2 to make H20 (steam) PLAY Page 6

USING EXCEL SPREADSHEET FOR OXIDE GROWTH CALCULATIONS These spreadsheets are available on Dr. Fullers webpage. Page 7

USING EXCEL SPREADSHEET FOR D/S JUNCTION DEPTH & SHEET RHO CALCULATIONS CALCULATION OF ION IMPLANT JUNCTION DEPTH AND SHEET RESISTANCE AFTER DRIVE-IN CONSTANTS VALUE UNITS Boron Phosorous q = 1.60E-19 Coul Max Mobility of n-type carriers 470.5 1414 Min Mobility of p-type carriers 44.9 68.5 Nref 2.23E+17 9.20E+16 alpha 0.719 0.711 GIVEN VALUE UNITS Starting Wafer Resistivity Rho = 10 ohm-cm Starting Wafer Type n-type = 0 1 or 0 p-type = 1 1 or 0 Pre Deposition Ion Implant Dose 9.50E+12 ions/cm2 Implant Time for 6" wafers Implant Beam Current 20 µa 0.24 min Drive-in Temperature T = 1100 C Drive-in Time t = 750 min CALCULATE VALUE UNITS Diffusion Constant at Temperature of Drive-in D = 1.33E-13 cm2/sec Diffusion Constant x time (use to adjust t for multiple Drive-ins) Dt = 5.99E-09 cm2 CALCULATION OF DIFFUSION CONSTANTS D0 (cm2/s) EA (ev) Boron 0.76 3.46 Phosphorous 3.85 3.66 CALCULATIONS VALUE UNITS Substrate Doping = 1 / (q µmax Rho) Nsub = 1.33E+15 cm-3 These spreadsheets are available on Dr. Fullers webpage. RESULTS VALUE UNITS Pre deposition Dose Dose = 9.50E+12 atoms/cm2 xj after drive-in = ((4 Dd td/qa) ln (Nsub (pddtd)^0.5))^0.5 xj = 3.08 µm average doping Nave = Dose/xj Nave = 3.09E+16 atoms/cm3 mobility (µ) at Doping equal to Nave µ = 990 cm2/v-s Sheet Resistance = 1/(q (µ(nave))dose) Rhos = 664.5 ohms Surface Concentration = Dose/ (pdt)^0.5 Ns = 6.93E+16 cm-3 Diffusion Constants (cm2/sec) Solid Solubility (cm-3) Page 8

MINIMUM OXIDE NEEDED TO MASK DIFFUSION These spreadsheets are available on Dr. Fullers webpge. Page 9

OXIDE THICKNESS COLOR CHART Thickness Color Thickness Color 500 Tan 4900 Blue Blue 700 Brown 5000 Blue Green 1000 Dark Violet - Red Violet 5200 Green 1200 Royal Blue 5400 Yellow Green Blue 1500 Light Blue - Metallic Blue 5600 GreenYellow 1700 Metallic - very light Yellow Green 5700 Yellow -"Yellowish"(at times appears to be Lt gray or matell 2000 LIght Gold or Yellow - Slightly Metallic 5800 Light Orange or Yellow - Pink 2200 Gold with slight Yellow Orange 6000 Carnation Pink 2500 Orange - Melon 6300 Violet Red 2700 Red Violet 6800 "Bluish"(appears violet red, Blue Green, looks grayish) Blue 3000 Blue - Violet Blue 7200 Blue Green - Green 3100 Blue Blue 7700 "Yellowish" 3200 Blue - Blue Green 8000 Orange 3400 Light Green 8200 Salmon 3500 Green - Yellow Green 8500 Dull, LIght Red Violet 3600 Yellow Green 8600 Violet 3700 Yellow 8700 Blue Violet 3900 Light Orange 8900 Blue Blue 4100 Carnation Pink 9200 Blue Green 4200 Violet Red 9500 Dull Yellow Green 4400 Red Violet 9700 Yellow - "Yellowish" 4600 Violet 9900 Orange 4700 Blue Violet 10000 Carnation Pink Nitride Rochester Institute Thickness of Technology = (Oxide Thickness)(Oxide Index/Nitride Index) Microelectronic Eg. Engineering Yellow Nitride Thickness = (2000)(1.46/2.00) = 1460 Page 10

WHITE LIGHT SOURCE Bruce Furnace REFLECTANCE SPECTROMETER (NANOSPEC - THICKNESS MEASUREMENT) MONOCHROMATOR & DETECTOR INCIDENT WHITE LIGHT, THE INTENSITY OF THE REFLECTED LIGHT IS MEASURED VS WAVELENGTH WAFER OPTICS 3000 Å OXIDE 7000 Å OXIDE Oxide on Silicon 400-30,000 Å Nitride 400-30,000 Neg Resist 500-40,000 Poly on 300-1200 Ox 400-10,000 Neg Resist on Ox 300-350 300-3500 Nitride on Oxide 300-3500 300-3500 Thin Oxide 100-500 Thin Nitride 100-500 Polyimide 500-10,000 Positive Resist 500-40,000 Pos Resist on Ox 500-15,000 4,000-30,000 Page 11

NANOSPEC FILM THICKNESS MEASUREMENT TOOL Record: Color = Blue-Green Color Chart Thickness = Å Nanospec Thickness = Å Page 12

TENCORE FT-300 SPECROMAP Record: Mean Std Deviation Min Max No of Points Page 13

FT500 Page 14

ELLIPSOMETER MEASUREMENTS Measure wafers C1 and C2 Pattern 20 is 1 point in center of wafer Pattern 22 is 5 points on 4 wafer Pattern 25 is 5 points on 6 wafer Recipe 03 is oxide on silicon Recipe 07 is nitride on oxide on silicon Recipe 02 is used for one film and finds thickness and index of refraction Page 15

MEASURE C1 AND C2 ON SCA-2500 Login: FACTORY Password: OPER <F1> Operate <F1> Test Center the wafer on the stage Select (use arrow keys on the numeric pad (far right on the keyboard) space bar, page up, etc) PROGRAM = FAC-P or FAC-N LOT ID = F040909 WAFER NO. = D1 TOX = 463 (from nanospec) <F12> start test and wait for measurement <Print Screen> print results <F8> exit and log off <ESC> can be used anytime, but wait for current test to be completed Page 16

SCA MEASUREMENT OF GATE OXIDE PLAY Page 17

SCA THEORY W accumulation C 3 1 2 2 1 Rotate 180 depletion 3 inversion Q V P type Point 1 is at flat band bias, Qfb is extracted Point 2 is at intrinsic bias, Qox is extracted, if Qox is not equal to Q FB then there are interface traps, Dit is calculated from slope of region between point 1 and 3. Point 3 is at onset of inversion where Nsc is extracted Lifetime, Ts, is measured in inversion P or N type is determined from shape of the curve Q = C V C = eoer /W Page 18

RECALL RUN DATA Click on the furnace tube of interest. Click on the graph icon on the left end of the top banner. Select last month. Select the furnace run of interest. Select the items to be graphed. Example: center profile, red, add; nitrogen flow, blue, add; oxygen flow, green, add; hydrogen flow, orange, add. Tube settled at 1000 C after 20 min. Settle Pull Out Push In Stabilize Ramp Up Calculated slope Ramp-up rate = 10.4 C/min Settle Ramp Down Settle Tube reached 800 C after 21.9 min. Tube settled at 800 C after 43 min. Calculated slope Ramp-up rate = 34 C/min Calculated slope Ramp-down rate = 6.5 C/min Effect of Pull-out and Push-in It recovered back to 800 C after 10 min. Start Temp. at 30 C Page 19

STABILIZE AFTER PUSH Tube settled at 1000 C after 20 min. Settle Pull Out Push In Stabilize Calculated slope Ramp-up rate = 10.4 C/min Settle Ramp Down Settle Ramp Up Tube reached 800 C after 21.9 min. Tube settled at 800 C after 43 min. Calculated slope Ramp-down rate = 6.5 C/min Effect of Pull-out and Push-in It recovered back to 800 C after 10 min. Calculated slope Ramp-up rate = 34 C/min Start Temp. at 30 C Because of the temperature drop during pull/out and load and the push/in we need to add a stabilize step at 800C in nitrogen prior to ramp up. Include a 15 min stabilize after push/in to all recipes. Page 20

NON UNIFORM OXIDE GROWTH PROBLEMS Non uniform oxide growth (top different from bottom) is often caused by not having the door closed all the way against the tube allowing room air to mix with the gas in the furnace. A similar effect is caused by having the gas flow rates too high or too low. The flow should slowly push a volume of air down the tube, without turbulence and without high velocity as it passes by the wafers. If the flow is too low then the door needs to be closed more accurately. Use Total flow (lpm) = v (cm/s) x Area (cm2) x 60 (s/m) x 0.001 (l/cm3) and let v = 1.0 cm/s. For 20 cm diameter tube Total Flow= 18 lpm The Bruce Furnace at RIT uses flows from 5 lpm to 15 lpm, These are all on the low side to reduce gas usage. oooooooooooooooooooo HotAir Out Gas In Door oooooooooooooooooooo Heat Element Cold Air In Page 21

NON UNIFORM OXIDE GROWTH PROBLEMS Non uniform oxide growth (top different from bottom) is often caused by not having the door closed all the way against the tube allowing room air to mix with the gas in the furnace. Top 1 2 10-10-01 Recipe 350 Tube 3 Target 5000 Å Point 1 =3980 Å Point 2 = 3350 Å Point 3 = 2997 Å 3 Page 22

PAD OXIDE - SPC CHART Page 23

WELL OXIDE SPC CHART Page 24

GATE OXIDE SPC CHART Page 25

KOOI OXIDE SPC CHART Page 26

FIELD OXIDE SPC CHART Page 27

OUT OF CONTROL ACTION PLAN During Move-In Run SPC Chart Find: Tget, USL, LSL Last Few Runs In Spec? Yes Run Recipe Measure Results Compare to Spec No Move-Out Don t Run Product Run Dummy Wafer Yes In Spec? No In Spec? No Yes Fix Recipe Check Theory Do MESA Query Consult Experts Other Equipment Problems Do Run History Find Gas Flows And Temperatures Rework? Put Lot on Hold? Move-Out and Feed Forward? Yes No Recipe & MESA Agree? Check Furnace Recipe No Problem? Yes Consult Equipment Engineer Page 28

BAKE OF SPIN-ON DOPANT 200 C FOR 15 MIN. Use quartz boat from furnace tube you plan to use. Use holder as shown because the boat will be hot. Do not heat wafers with photoresist on them above 150 C Page 29

POSITION OF WAFERS ON PADDLE Load wafers here, when paddle is fully out. Do not use dummy filler wafers the improved uniformity is negligible. Page 30

CREATING NEW RECIPES Log In as engineer Find a similar recipe Edit > Copy > new recipe name Pick a number that has not been used Make changes save Page 31

LIST OF RECIPES FOR BRUCE FURNACE 10 Lfull Sub CMOS Well, 1100 C, 600 min, N2 11 Lfull Adv CMOS Well, 1100 C, 360 min, N2 15 Lfull Well-Oxide, 1100 C, 330 min, N2 + 25 min wet Oxide 16 Lfull TEOS Densification, 1hr. 1000 C, N2 99 Lfull Sinter, 400 C, 30min, N2/H2 101 Lfull Sinter, 450 C, 30min, N2/H2 105 Lfull 1000 C Anneal, 100 min, N2 only 106 Lfull Anneal sub-micron CMOS process, 900 C, 30 min., N2 110 Lfull PMOS D/S Diffusion and Wet Ox, N2 then Wet O2 111 Lfull P+ Doping + Wet O2 115 Lfull N+ Doping + Wet O2 119 Lfull N+ Doping Thick Poly 120 Lfull N+ Poly Doping from Spin-on Source, 1000 C, 15 min, N2 144 Lfull 1000 C Source/Drain Anneal Page 32

LIST OF RECIPES FOR BRUCE FURNACE 162 Lfull Well Drive SMFL-CMOS 25hr, 1100 C, N2 163 Lfull SMFL-CMOS Field Oxide, 6500Å, 950 C, Wet Oxide 175 Lfull Poly ReOxide 850 C, Wet Oxide, 15 min. 180 Lfull Well Drive P-well CMOS, 6 hrs O2, 30 hrs N2, 1100 C 210 Lfull 100Å Gate Oxide 213 Lfull 100Å Gate Oxide with N2O 215 Lfull 150Å Gate Oxide, 900 C, 50 min, Dry O2 225 Lfull 250Å Gate Oxide 250 Lfull 500Å Dry Oxide, 1000 C, 56 min., soak, Gate/Pad Ox 252 Lfull Dry Oxide Var Time, 1000 C Set your own soak time 270 Lfull 700Å Dry Oxide, 1Hr. 24min. 1000 C soak 280 Lfull D/S Implant Anneal, 1000 C, 20 min N2 +10 min Wet O2 284 Lfull D/S Anneal, 1000 C, 25 min. N2 310 Lfull 1,000Å Dry Oxide, 2Hr. 18min. 1000 C soak 311 Lfull 1,000Å Kooi/Sacrificial Oxide, 900 C, Wet O2, 40 min. Page 33

LIST OF RECIPES FOR BRUCE FURNACE 330 Lfull Wet 3,000 Å Wet Oxide, 1000 C, 50 min. soak 336 Lfull Wet 3,650 Å Wet Oxide, 1000 C, 55 min. soak 341 Lfull Wet 4,000Å Wet Oxide, 1100 C, 20 min. soak 350 Lfull Wet 5,000Å Wet Oxide, 1000 C, 100 min. soak 353 Short Course 5000Å, 1100 C, 45 min, Wet Ox 354 Short Course PreDep, 1050 C, 5min N2 + 5 min Wet Ox 355 Short Course Gate Ox, 1100 C, 17min, Dry O2 356 Short Course Sinter, 357 Short Course 8000Å, 1100 C, 95 min, Wet Ox 352 Lfull Wet Ox Var Time, 1100 C, Set your own soak time 406 Lfull 6,500Å Wet Oxide, Field Ox, 1100 C, 65 min. soak 410 Lfull 10,000Å Wet Oxide, Field Ox, 1100 C, 210 min. soak 430 Lfull 30,000Å Wet Oxide, Field Ox, 1100 C, 15 Hr. soak 440 Lfull 40,000Å Wet Oxide, Field Ox, 1100 C, 35 Hr. soak 463 SMFL TransLC Tube Clean, Tube 4 474 Lfull SMFL CMOS 310Å Gate Oxide, N2/O2, 1000C,15 min. Page 34

BRUCE FURNACE RECIPE 10 SUB-CMOS WELL DRIVE Recipe #10 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 30 min 600 min 5 min 60 min 12 min 10 lmp 1 1 1 1 1 5 lpm N2 N2 N2 N2 N2 N2 N2 Sub-CMOS Well Drive, No Oxide Growth, Tube 1 Page 35

BRUCE FURNACE RECIPE 11 ADV-CMOS WELL DRIVE Recipe #11 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 30 min 360 min 5 min 60 min 12 min 10 lmp 1 1 1 1 1 5 lpm N2 N2 N2 N2 N2 N2 N2 Adv-CMOS Well Drive, No Oxide Growth, Tube 1 Page 36

BRUCE FURNACE RECIPE 11 ADV-CMOS WELL DRIVE Recipe #15 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak O2 Wet Ox Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 4 5 Interval 6 Interval 7 Interval 8 12 min 15 min 30 min 330 min 5 min 25 min 60 min 12 min 10 lmp 1 1 1 1 3.6/2 lpm 1 5 lpm N2 N2 N2 N2 O2 H2/N2 N2 N2 CMOS Well Drive, 3000Å Wet Oxide Growth, Tube 1 Page 37

BRUCE FURNACE RECIPE 16 ADV-CMOS WELL DRIVE Recipe #16 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 12 min 20 min 30 min 60 min 40 min 15 min 10 lmp 1 1 1 1 5 lpm N2 N2 N2 N2 N2 N2 Adv-CMOS Well Drive, No Oxide Growth, Tube 1 Page 38

BRUCE FURNACE RECIPE 99 SINTER SINTER Recipe #99 Warm Push Stabilize Soak Anneal Pull 400 C Interval 0 1 2 3 4 5 6 ` 60 30 15 15 5 15 min 0 lmp 10 10 10 5 10 5 lpm None N2 N2 N2 N2/H2 N2 N2 Sinter, Tube 2 Page 39

BRUCE FURNACE RECIPE 101 SINTER SINTER Recipe #101 Verified:8-20-08 Warm Push Stabilize Soak Purge Pull 450 C Interval 0 1 2 3 4 5 6 ` 60 30 15 15 5 15 min 0 lmp 10 10 10 5 10 5 lpm None N2 N2 N2/H2 N2/H2 N2 N2 Sinter, Tube 2 Page 40

SINTER Before Sinter Reduce Contact Resistance After Sinter Native Oxide Oxygen Hydrogen, neutral region + charge region Silicon DiOxide silicon Interface atom that lost an electron Silicon Crystal Reduce Surface States Page 41

BRUCE FURNACE RECIPE 105 1000 C ANNEAL Recipe #105 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 100 min 5 min 40 min 12 min 10 lmp 1 1 15 lpm 1 1 5 lpm N2 N2 N2 N2 N2 N2 N2 1000 C Anneal, No Oxide Growth Page 42

BRUCE FURNACE RECIPE 106 900 C ANNEAL Recipe #106 900 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 10 min 30 min 5 min 20 min 12 min 10 lmp 1 1 15 lpm 1 1 5 lpm N2 N2 N2 N2 N2 N2 N2 900 C Anneal, No Oxide Growth Page 43

BRUCE FURNACE RECIPE 110 PMOS D/S &WET O2 Recipe #110 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Wet Oxide Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 20 min 30 min 40 min 12 min 1 1 1 1 2/3.6 lpm 1 5 lpm N2 N2 N2 N2 O2/H2 N2 N2 PMOS D/S Diffusion pluswet Oxide Growth Page 44

BRUCE FURNACE RECIPE 111 P+ POLY DOPE Recipe #111 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Wet Oxide Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 15 min 10 min 40 min 12 min 1 1 1 1 2/3.6 lpm 1 5 lpm N2 N2 N2 N2 O2/H2 N2 N2 P-Type Poly Dope plus Wet Oxide Growth Page 45

BRUCE FURNACE RECIPE 115 N+ DIFF &WET O2 Recipe #115 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Wet Oxide Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 30 min 30 min 40 min 12 min 1 1 1 1 2/3.6 lpm 1 5 lpm N2 N2 N2 N2 O2/H2 N2 N2 N+ Diffusion plus Wet Oxide Growth, Target 2854 Å Page 46

BRUCE FURNACE RECIPE 119 N++ POLY DOPE Recipe #119 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 6 Interval 7 12 min 15 min 20 min 30 min 40 min 15 min 1 10 lmp 5 lpm 1 1 5 lpm N2 N2 N2 N2 N2 N2 N+ Poly Doping, Thick Poly, > 1 µm, No Oxide Growth Page 47

BRUCE FURNACE RECIPE 120- N+ POLY DOPE Recipe #120 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 6 Interval 7 12 min 15 min 20 min 15 min 40 min 15 min 1 10 lmp 5 lpm 1 1 5 lpm N2 N2 N2 N2 N2 N2 N+ Poly Doping, Thin Poly, < 1 µm, No Oxide Growth Page 48

BRUCE FURNACE RECIPE 144 1000 C S/D ANNEAL Recipe #144 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Stabilize Wet Soak Dry Soak Purge Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 6 7 Interval 8 12 min 20 min 20 min 10 min 10 min 5 min 5 min 35 min 10 lmp 1 1 1 3.6/2 lpm 1 15 lpm 1 N2 N2 N2 N2 H2/O2 O2 N2 N2 1000 C Anneal, With Oxide Growth Page 49

BRUCE FURNACE RECIPE 162 1100 C 25HR WELL DRIVE Recipe #162 1100 C Boat Out Boat In Load Push Stabilize Ramp-Up Stabilize Soak Purge Ramp-Down Pull Boat Out Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 6 Interval 7 12 min 20 min 30 min 60 min 25 Hours 5 min 45 min 10 lmp 1 1 1 1 15 lpm 1 N2 N2 N2 N2 N2 N2 N2 1100 C Well Drive, No Oxide Growth Page 50

BRUCE FURNACE RECIPE 163 950 C 6500Ã FIELD OX Recipe #163 950 C Boat Out Boat In Load Push Stabilize Ramp-Up Stabilize O2 Flood Wet Soak O2 Purge N2Purge Ramp-Down Interval 0 Interval 1 Interval 2 3 4 5 6 7 8 9 12 min 20 min 15 min 10 min 5 min 5 hours 5 min 20 min 20 min 10 lmp 1 5 lpm 5 lpm 5 lpm 3.6/2 lpm 5 lpm 15 lpm 1 N2 N2 N2 N2 O2 H2/O2 O2 N2 N2 950 C Wet Oxide Growth, Target 6500Å Page 51

BRUCE FURNACE RECIPE 175 850 C POLY REOX Recipe #175 850 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Stabilize Wet Soak Purge Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 4 5 6 7 12 min 20 min 5 min 10 min 15 min 10 min 10 min 10 lmp 1 5 lpm 5 lpm 3.6/2 lpm 15 lpm 1 N2 N2 N2 N2 H2/O2 O2 N2 850 C Poly Reoxide Page 52

BRUCE FURNACE RECIPE 180 P-WELL DRIVE Recipe #180 1100 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 30 min 6 hr 30 hr 60 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 P-well CMOS Drive and Oxide Growth Page 53

BRUCE FURNACE RECIPE 210 TUNNEL OXIDE Recipe #210 950 C Boat Out Boat In Boat Out Load Push Ramp-Up Soak O2 Anneal Soak O2 Anneal Soak O2 Anneal Ramp Pull Interval 0 1 2 3 4 5 6 7 8 9 10 12 min 30 min 15 min 60min 10 min 20 min 10 min 30 min 30min 15 min 1 10 lmp 1 5 lpm 1 5 lpm 1 5 lpm 1 0 N2 N2 O2 N2 O2 N2 O2 N2 N2 Tunnel Oxide for EEPROM, Target 100 Å Page 54

BRUCE FURNACE RECIPE 213 100 Å DRY OXIDE Recipe #213 900 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Soak Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 30 min 30 min 30 min 30 min 30 min 15 min 5 lpm 5 lmp 1 1 1 1 5 lpm N2 N2 O2 N2O O2 N2 N2 Dry Oxide Growth with N2O, Target 100 Å Page 55

BRUCE FURNACE RECIPE 215 150Å DRY OXIDE Recipe #215 900 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 10 min 45 min 5 min 20 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 Dry Oxide Growth, Target 150 Å Page 56

BRUCE FURNACE RECIPE 225 250 Å DRY OXIDE Recipe #225 900 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 10 min 93 min 5 min 20 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 Dry Oxide Growth, Target 250 Å Page 57

BRUCE FURNACE RECIPE 250-500Å DRY OXIDE Recipe #250 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 56 min 5min 40 min 12 min 1 1 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 Dry Oxide Growth, Target 500 Å Page 58

BRUCE FURNACE RECIPE 252 - VARIABLE DRY OXIDE Recipe #252 1000 C Verified:2-24-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min Variable Time 5min 40 min 12 min 1 1 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 Dry Oxide Growth, Variable Target Page 59

BRUCE FURNACE RECIPE 270 700Å DRY OXIDE Recipe #270 1000 C Verified: 3-1-04 Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 93 min 5 min 40 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2/ N2 N2 N2 Dry Oxide Growth, Target 700 Å Page 60

BRUCE FURNACE RECIPE 280 Sub-CMOS ANNEAL Recipe #280 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 20 min 5 min 40 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2/ N2 N2 N2 DS Implant Anneal, Oxide Growth Page 61

BRUCE FURNACE RECIPE 284 Adv-CMOS ANNEAL Recipe #284 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 20 min 5 min 40 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 N2 N2 N2 N2 N2 DS Implant Anneal, Oxide Growth Page 62

BRUCE FURNACE RECIPE 310 DRY OXIDE 1,000Å Recipe #310 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up/O2 Purge Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 12 min 15 min 20 min 138 min 5 min 35 min 15 min 1 10 lmp 5 lpm 1 15 lpm 1 5 lpm N2 N2 O2 O2 N2 N2 N2 Dry Oxide Growth, Target 1000 Å Page 63

BRUCE FURNACE RECIPE 311 WET OXIDE 1,000Å Recipe #311 900 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up/O2 Purge Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 10 min 5 min 40 min 5 min 15 min 15 min 1 10 lmp 5 lpm 1 3.6/2. 15 lpm 1 5 lpm N2 N2 O2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 1000 Å, Kooi Page 64

BRUCE FURNACE RECIPE 330 WET OXIDE 3,000Å Recipe #330 Lfull 3000 A Wet Ox 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Flood Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 20 min 5 min 50 min 5 min 40 min 12 min 1 1 5 lpm 1 3.6/2. 15 lpm 1 5 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 3000 Å Page 65

BRUCE FURNACE RECIPE 336 WET OXIDE 3,650Å Recipe #336 Lfull 3650 A Wet Ox 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Flood Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 20 min 5 min 55 min 5 min 40 min 12 min 1 1 5 lpm 1 3.6/2. 15 lpm 1 5 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 3650 Å Page 66

BRUCE FURNACE RECIPE 341 WET OXIDE 4,000Å Recipe #341 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Flood Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 20 min 5 min 20 min 5 min 40 min 12 min 1 1 5 lpm 1 3.6/2. 15 lpm 1 5 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 4000 Å Page 67

BRUCE FURNACE RECIPE 350 WET OXIDE 5,000Å Recipe #350 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Flood Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 20 min 5 min 100 min 5 min 40 min 12 min 1 1 5 lpm 1 3.6/2. 15 lpm 1 5 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 5000 Å Page 68

BRUCE FURNACE RECIPE 352 WET OXIDE VARIABLE THICKNESS Recipe #352 1000 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Flood Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 20 min 5 min??? min 5 min 40 min 12 min 1 1 5 lpm 5 lpm 1 15 lpm 1 15 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Variable Target Page 69

BRUCE FURNACE RECIPE 406 WET OXIDE 6,500Å Recipe #406 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 30 min 5 min 65 min 5 min 60 min 12 min 1 1 5 lpm 5 lpm 1 15 lpm 1 15 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 6,500 Å Page 70

BRUCE FURNACE RECIPE 410 WET OXIDE 12,000Å Recipe #410 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 30 min 5 min 210 min 5 min 60 min 12 min 1 1 5 lpm 5 lpm 1 15 lpm 1 15 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 12,000 Å Page 71

BRUCE FURNACE RECIPE 430 WET OXIDE 30,000Å Recipe #430 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 30 min 5 min 15 hrs 5 min 60 min 12 min 1 1 5 lpm 5 lpm 1 15 lpm 1 15 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 30,000 Å Page 72

BRUCE FURNACE RECIPE 440 WET OXIDE 40,000Å Recipe #440 1100 C Boat Out Boat In Boat Out Load Push Stabilize Ramp-Up Soak Anneal Ramp-Down Pull Interval 0 Interval 1 Interval 2 Interval 3 Interval 4 Interval 5 Interval 6 Interval 7 Interval 8 12 min 15 min 30 min 5 min 35 hrs 5 min 60 min 12 min 1 1 5 lpm 1 3.6/2. 15 lpm 1 5 lpm N2 N2 N2 O2 O2/H2 N2 N2 N2 Wet Oxide Growth, Target 40,000 Å Page 73

BRUCE FURNACE RECIPE 463 TransLC CLEAN Recipe #463 1000 C Boat In Load O2 Flood Ramp TR-LC Trans LC N2 Purge Boat Out Interval 0 1 2 3 4 5 5 min 20 min 20 min 20 min 0 min 1 11.5 lpm O2 5 lpm 5 lpm O2 0.9 lpm O2 and 445 FL N2 N2 1000 C Trans LC Tube Clean, Tube 4 Page 74

BRUCE FURNACE RECIPE 474 GATE OXIDE 310Å Recipe #474 1000 C Boat Out Boat In Load Push Stabilize Ramp-Up Stabilize Soak O2 Purge N2 Purge Ramp-Down Boat Out Interval 0 1 2 3 4 5 6 7 8 12 min 20 min 20 min 5 min 9.5 MIN 5 min 5 min 35 min 1 1 5 lpm 5 lpm 1 1 15 lpm 1 O2 O2 O2 O2 O2+TransLC O2 N2 N2 1000 C 310Å Gate Oxide Growth Page 75

REFERENCES 1. Sdfklj 2. slfj Page 76

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