Transition from AMR to GMR Heads in Tape Recording

Transition from AMR to GMR Heads in Tape Recording John P. Nibarger Sun Microsystems 1450 Infinite Dr., Louisville CO 80027-9440 Phone: +1-303-661-2837 FAX: +1-303-661-8992 E-mail: john.nibarger@sun.com Presented at the THIC Meeting at the National Center for Atmospheric Research, 1850 Table Mesa Drive, Boulder CO 80305-5602 August 21-22, 2007 1

Outline Basics of magnetic recording > AMR (Anisotropic Magneto-Resistance) > GMR (Giant Magneto-Resistance) Transition in disk from AMR to GMR Issues surrounding the transition from AMR to GMR in tape 2

Digital Magnetic Recording Channel converts digital user data to analog signal Head writes data to media Media stores data Head reads data from media Channel converts analog signal to digital user data * * Using a peak detect channel 3

Magnetic Read Sensors Allow system to resolve changes in the magnetic media which stores the user information Two types in magnetic recording B > Inductive: Faraday s Law ( Ε = t ) > Magneto-Resistive (MR): electric resistance of the sensor changes with applied magnetic field Rotation of the magnetization in a MR sensor gives rise to a resistivity change ( ρ) ρ V = 0 ρ + ρ f = I R = I ( ) θ ρ w td w t d Magnetic flux Magnetic layer Magnetic sensor Magnetic moment 4

Tape and Disk Sensor Technology Inductive > A variable magnetic field from the media will induce a variable voltage in a coil Anisotropic magneto-resistance ( ρ/ρ ~ 2% in Ni 80 Fe 20 ) > Bulk effect in ferromagnetic materials Giant magneto-resistance ( ρ/ρ ~ 20% in Co/Cu/Co) > Interface effect in thin multilayers Tunneling giant magneto-resistance ( ρ/ρ ~ 250% in Co/MgO/Co) > Coherent tunneling effect across an insulator Tape Disk 1985 IBM 3480 2010?? Inductive AMR GMR Inductive AMR GMR TMR 1992 1997 2006 IBM Corsair IBM Deskstar 16GP Seagate Momentus5II

Magnetic Recording Tape area width (½ ) and length (900 m) > ~ 18,000 in 2 Disk area area of a platter and number of platters > ~ 8 in 2 for 1 single-sided platter Direction of media travel bits per inch (bpi) shields sensor Tracks per inch (tpi) Areal density (bits/in 2 ) = tpi bpi 6

Tape Disk Inductive AMR GMR 1985 1992 1997 2006 2010?? Inductive AMR GMR TMR 1000 INSIC EHDR demo goal Areal Density (Gb/in 2 ) 100 10 1 0.1 0.01 1990 1995 2000 2005 2010 2015 2020 Year of Introduction 16 TB 2 TB Disk Product Tape Product Tape INSIC Roadmap 7

AMR Response Anisotropic Magneto-Resistance (AMR) is a bulk effect in Permalloy (Ni 80 Fe 20 ) and other ferromagnetic materials > Optimum bias at 45 degrees 2 ( H) = + ( H) ρ ρ0 ρamr cos θ θ magnetization current AMR: Goal is to offset the bias field H R Rectified Sensor Output H R Sensor Output Vary field with tape Vary field with tape 8

AMR Sensor Stack Materials Cap Cap Sensor 25-45 nm Ni 80 Fe 20 Spacer 7-12 nm Ta 45 80 nm Soft Adjacent Layer (SAL) 15-25 nm Co 90 Zr 5 Mo 5 Seed Seed Substrate Substrate 9

Why Switch from AMR? AMR is a good sensor (and still used by tape) 20 BUT, it has a problem. Output decreases as sensor thickness decreases R/R (%) 15 10 Tape head AMR layer thickness and year of Sun/STK product introduction Why has sensor thickness decreased over time? 5 2006 2003 1999 1993 AMR 0 0 100 200 300 400 500 600 Sensing Layer Thickness (Angstroms) 10

Achieving Higher Densities Magnetic sensor Magnetic moment Magnetic flux Tape magnetic layer Tape substrate Thick media low density lots of flux Thick sensor to match flux Thin media high density less flux Thin sensor to match flux Sensor for higher densities: 1. Thinner sensor (for thinner media) 2. Higher sensitivity (to make up for reduced flux) 11

Decreasing Thickness Penalty in AMR 20 R/R (%) 15 10 5 2006 2003 1999 1993 AMR 0 0 100 200 300 400 500 600 Sensing Layer Thickness (Angstroms) Thinning the sensor allows higher density BUT the signal goes down! Want something that can increase output with decreasing sensor thickness 12

Advantage of GMR 20 GMR is an interface effect AMR is a bulk effect, interfacial scattering takes over at small thicknesses R/R (%) 15 GMR 10 5 AMR 0 0 100 200 300 400 500 600 Sensing Layer Thickness (Angstroms) 13

GMR Spin Dependent Scattering Aligned moments Low Resistance Free Layer Non-magnetic Spacer Pinned Layer Anti-aligned moments High Resistance Free Layer Non-magnetic Spacer Pinned Layer 14

GMR Response GMR is an interface effect > Bias at 0 degrees ( H) = + ( H) ρ ρ0 ρgmr sinθ pinned free Free Cu spacer Pinned Resistance R Applied Field R GMR: Goal is to zero the bias field H Small Sensor Output H Sensor Output Vary field with tape Vary field with tape 15

How Do We Make These Structures? GMR structures act as a spin valve > Resistance depends on direction of applied magnetic field on the sensor 3 important components > Free layer > Well behaved > Properly oriented and biased > Non-magnetic spacer > Interface properties are important > A solid pinned layer > Won t move with field from tape Cap Free Layer Non-magnetic spacer Pinned Layer Seed Substrate 16

GMR Sensor Stack Materials Cap Free Layer Spacer 5-15 nm 2-3 nm Cap Ni 80 Fe 20 Co 90 Fe 10 Cu magnetization Pinned Layer 10-40 nm Co 90 Fe 10 Ru (10 Ǻ) Co 90 Fe 10 Pt 50 Mn 50 Seed Substrate Seed Substrate Ru atomic radii ~ 2.6 Ǻ 10 Ǻ Ǻ = 10-10 m 17

GMR at Sun Peak to peak voltage (uv) 12000 10000 8000 6000 4000 2000 0-10 -5-2000 0 5 10 GMR 5 um reader 1.5 um stripe GMR 2.5 um reader 1.3 um stripe GMR 1 um reader 1 um stripe AMR 5 um reader 1.6 um stripe Ibias (ma) Vpp (uv) 5 µm reader width comparison 100000 10000 1000 100 0 2500 5000 7500 10000 12500 15000 density (frmm) NGD-B AMR sensor NGD-C GMR prototype 41 (1 um stripe) sensor ( R R ) ( ) R R frmm = flux reversals per mm GMR AMR 9% = = 4.5 2% 18

Recording Head Operations at Sun Louisville, CO Providing leading edge head technologies for Enterprise, Mid-Range, and Low-End tape drive products. > Sun Microsystems T10000 and 9x40 product lines; LTO2-LTO4 > The first thin film helical scan read & write heads in production with VXA-3 Developing the technology building blocks for future generation products now > GMR, increased device density, advanced materials Custom designed equipment technology to meet the unique requirements of tape head manufacturing > Dynamic testers, head assembly, critical dimension measurement State-of-the-art performance analysis capabilities to ensure product quality and competitive position > Dynamic performance, constructional analysis, magnetics analysis 19

GMR to TMR TMR GMR Gallagher and Parkin, IBM J. Res. Dev. 50, 5 (2006) 20

AMR to GMR Transition for IBM www.hitachigst.com/hdd/technolo/gmr/gmr.htm 21

AMR to GMR Transition for tape INSIC (2015), 10 Gb/in 2 (16 TB) INSIC (2013), 5 Gb/in 2 (8 TB) INSIC (2011), 2.7 Gb/in 2 (4 TB) INSIC (2009), 1.5 Gb/in 2 (2 TB) INSIC (2007), 0.8 Gb/in 2 (1 TB) T10000 (2006), 0.4 Gb/in 2 (500 GB) CGR = 40 % 9940B (2002), 0.2 Gb/in 2 (200 GB) INSIC high bpi scenario 20xx 02 04 06 07 09 11 13 15 ~ 12 year technology offset 22

Areal Density 100 2005 INSIC roadmap 1000 Disk - AMR Disk - GMR Tape Tape (high bpi) Tape (high tpi) areal density (Gb/in^2) 10 1 0.1 kbpi 100 0.01 10 0.1 1 10 100 100 1000 10000 100000 reader width (um) tpi Disk change to GMR ~ 2-5 Gb/in 2 Tape change to GMR ~ 1-2 Gb/in 2 23

Kbpi and Tpi 1000 2005 INSIC roadmap 100000 Disk - AMR Disk - GMR Tape Tape (high bpi) Tape (high tpi) 10000 kbpi 100 tpi 1000 Read width = ½ track width 10 0.1 1 10 100 reader width (um) 100 0.1 1 10 100 reader width (um) Disk change to GMR ~ 1 µm, but only at 200 kbpi Tape change to GMR ~ 2-3 µm, but only at 300-400 kbpi 24

Bit Aspect Ratio (BAR) 1000 L W BAR = bpi/tpi = W/L 1000 Disk - AMR Disk - GMR Tape Tape (high bpi) Tape (high tpi) 100 100 BAR BAR 10 10 1 0.1 1 10 100 1 0.01 0.1 1 10 100 reader width (um) areal density (Gb/in^2) Tape has much higher BAR since bpi is pushed more 25

Similarities and Differences Similarities > Fundamental physics of recording is identical Differences > Interchange is needed for tape > Disk is a closed environment compared to tape > Contamination and corrosion > Tape does read while write > Area (18,000 in 2 vs. 8 in 2 ) > Rigid disk vs. flexible tape media (sputtered vs. particulate) > Number of tracks > 32 data + 4 servo tracks in Sun T10000 drive (crosstalk is a major issue) > But disk can have lots of platters (5 two-sided disks with 10 heads) > Manufacturing yield: tape, 36/36 with 36 tracks, disk, 1/1 > (device yield) 36 = head yield > (83% device yield) 36 = 0.1% head yield > (99.5% device yield) 36 = 83% head yield 26

Electro-Static Discharge GMR sensors are extremely sensitive to ESD Two failure modes High temperatures melt and fuse materials together Moderate temperatures heat PtMn anti-ferromagnet above it s blocking temperature PtMn can reorient ~ 350º C NiFe free layer ~ 660 º C Cu spacer ~ 1000 º C (Al Wallash Maxtor Corporation) 27

HBM Failure Voltage (V) ESD Sensitivity Hard drive > Preamp on slider Tape > Long flex to preamp 250 200 150 100 50 AMR GMR 0 1990 1995 2000 2005 Year (Al Wallash Maxtor Corporation) 2006 Maxtor hard drive Sun T10000 head, flex, and voice coil 28

Conclusion Fundamental physics will drive the transition from AMR to GMR in tape just as it did in disk > Disk migrated at 2 5 Gb/in 2, ~ 200 kbpi, and 1 µm reader width > Tape will migrate ~ 1 2 Gb/in 2, ~ 300 400 kbpi, and 2 3 µm reader width Engineering tradeoffs have pushed disk to high tpi and tape to (relatively) high bpi due to track following issues in tape Disk migrated to GMR successfully (and then TMR) Tape will migrate to GMR but issues exist > Corrosion > ESD > Media 29

Questions? 30