Mask-writing Strategies for Increased CD Accuracy and Throughput - PowerPoint PPT Presentation

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Mask-writing Strategies for Increased CD Accuracy and Throughput

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The temperature of each subfield decays exponentially between flashes ... Critical subfield temperature profiles before occurrence of flash for. 16 16 subfield pattern ... – PowerPoint PPT presentation

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Title: Mask-writing Strategies for Increased CD Accuracy and Throughput


1
Mask-writing Strategies for
Increased CD Accuracy and
Throughput
Calibrating Achievable Design Annual Review
September 2003
Swamy V. Muddu, Andrew B. Kahng (Joint work with
Sergey Babin and Ion Mandoiu)
Abstract Resist heating and proximity effects
in e-beam mask writing affect critical dimension
(CD) accuracy and throughput. Tight CD control is
important for minimizing on-chip variability in
future technology nodes. High mask-writing
throughput is needed for reducing soaring mask
costs. Resist heating is a significant
contributor to CD distortion on mask. Current
e-beam writing strategies optimize beam current
density, number of passes etc., but at the cost
of decreasing throughput. We propose a new e-beam
writing strategy that reduces CD distortion while
maintaining throughput. Simulation results
indicate non-sequential writing of subfields lead
to effective dissipation of heat and improve CD
distortion. References S. Babin, A.B. Kahng,
I.I. Mandoiu, S. Muddu, Resist heating
dependence on subfield scheduling in 50kV
electron beam maskmaking, Proc. of Photomask
Japan, April 2004, to appear Sergey Babin,
Measurement of resist heating in photomask
fabrication, J. Vac. Sci. Technol. B 15(6),
Nov/Dec 1997, pp. 2209-2213
  • Subfield Scheduling
  • Key observation scheduling of subfields
    decreases maximum resist temperature
  • Non-sequential writing ? throughput overhead due
    to beam settling time
  • To maintain throughput, equalize mask write times
    by increasing beam current density
  • Rise in temperature due to increased current
    density is offset by non-sequential writing
    schedule
  • Simulation Setup
  • Resist heating simulations performed using
    TEMPTATION resist heating simulator
  • Simulated subfield scheduling strategies (1)
    Sequential and (2) Greedy
  • A two-phase simulation setup was used to simulate
    16 x 16 subfields
  • Phase I Every subfield is flashed using 4 coarse
    flashes with total dose equal to that of detailed
    fracture flashes
  • Phase II The simulation is repeated with the
    critical subfield (i.e., the subfield with
    maximum temperature before writing in phase I)
    flashed using detailed fracture flashes (512 2µm
    x 2µm fractures)
  • Greedy Subfield Scheduling
  • Greedy algorithm starts from a random ordering of
    subfields and iteratively modifies the ordering
    by swapping pairs of subfields
  • Evaluating the cost function takes O(n2) time,
    and thus the greedy algorithm requires O(n4) time
    per improving swap, where n is the number of
    subfields in a main deflection field
  • Our implementation evaluates only pairs (i,j) in
    which i is a subfield with max temperature this
    reduces runtime to O(n3) per improving swap

Greedy scheduling
1. Start with random subfield order ? 2. Repeat forever For all pairs (i,j) of subfields, compute cost of ? with i and j swapped If there exists at least one cost-improving swap, then modify ? by applying a swap with highest cost gain Else exit repeat
  • Motivation
  • Mask writing in DSM regimes is limited by resist
    heating effects, such as CD distortion
  • Current techniques for reducing resist heating
    (reducing e-beam density, multi-pass writing,
    etc.) reduce mask writing throughput
  • To reduce resist heating, avoid successive
    writing of subfields
  • To maintain throughput we increase beam current
    density such that reduction in dwell time
    compensates for increase in travel time
  • Scheduling Results
  • Critical subfield temperature profiles before
    occurrence of flash for 1616 subfield pattern

Mask Writing Schedule Problem Given Beam
voltage, resist parameters, threshold temperature
Tmax Find Beam current density and subfield
writing schedule such that the maximum resist
temperature never exceeds Tmax
  • Cost Computation
  • The cost of a subfield order ? is ? Tmax (1-
    ?)TavgTmax ? max temperature before
    writingTavg? avg temperature before writing
  • Tmax corresponds to CD distortion due to resist
    heating, while Tavg corresponds to increase in
    mask write time
  • To find an ordering, we can associate different
    weightings to Tmax, Tavg. In our experiments we
    use ? 0.5
  • The temperature rise of a subfield s due to the
    writing of subfield f depends on the distance
    between s and f, the energy deposited while
    writing f, and the thermal properties of resist
  • The temperature of each subfield decays
    exponentially between flashes
  • With this model, evaluating the cost function for
    a given subfield order requires O(n2) time
  • Variable-shaped E-beam Writing
  • Taxonomy of mask features
  • Fractures smallest features written on the mask
    dimensions in the range 0.5µm-2µm
  • Minor field collection of fractures
  • Subfield collection of minor fields typical
    subfield size 64µm X 64µm
  • Major field or cell collection of subfields
  • E-beam writing technology context
  • High power densities (up to 1GW/c.c.) needed to
    meet SIA Roadmap requirements
  • Power densities induce local heating causing
    significant critical dimension (CD) distortion
  • Scheduling of fractures incurs large positioning
    overheads
  • Scheduling subfields incurs very low overheads,
    yet is still effective in reducing excessive
    heating


Detailed temperature profile Sequential
Max105.10?C
  • Conclusions
  • Self-avoiding subfield ordering reduces the
    maximum temperature of resist by spacing
    successive writings
  • To normalize the throughput due to scheduling, we
    decrease the dwell time of each subfield by
    increasing the current density
  • Increase in current density does not increase
    resist heating significantly because of subfield
    ordering
  • Future Work
  • Use accurate temperature modeling approach in
    cost computation in greedy scheduling
  • Quantify the improvements in CD and throughput
    due to decrease in resist temperature
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