Anthony W. Thomas CSSM

Model Independent Chiral Extrapolation of Baryon Masses Anthony W. Thomas CSSM Asia-Pacific Mini-Workshop on Lattice QCD Tsukuba – January 2003

Outline PROBLEM: Lack of computer power ) need chiral extrapolation  PT : Radius of convergence TOO SMALL NO! STOP?? Just impose a little physics insight ! ) MODEL INDEPENDENT RESULTS! Then: 10 Teraflops (next generation) machines will allow 1% accuracy

Collaborators (Stewart Wright) Derek Leinweber Ross Young

Problem of Chiral Extrapolation ♦Currently limited to mq > 30-50 MeV Time to decrease m by factor of 2 : 27 » 100 ♦NEED perhaps 500 Teraflops to get to 5 MeV ! Furthermore EFT implies ALL hadronic properties are non-analytic functionsof mq …….. HENCE:NO simple power series expansion about mq = 0 : NO simple chiral extrapolation

Major Recent Advance Study of current lattice data for hadron properties as a function of quark mass (c.f. vs Nc ) Implies:Major surpriseplus solution Can ALREADY make accurate, controlled chiral extrapolation, respecting model independent constraintsof χ P T

Formal Chiral Expansion Formal expansion of Hadron mass: MN = c0 + c2 m2 + cLNA m3+ c4 m4 + cNLNA m4 ln m + c6 m6 + ….. Mass in chiral limit • Another branch cut • from N!! N • higher order in m • hence “next-to-leading” • non-analytic (NLNA) First (hence “leading”) non-analytic term ~ mq3/2 (LNA) Source: N ! N ! N No term linear in m(in FULL QCD…… there is in QQCD) Convergence?

Failure of Convergence of χ P T  +  mπ2 + Nπ c.f. series expansion…. (From thesis: S. V. Wright ) For NJL model, see also: T. Hatsuda, Phys. Rev. Lett., 27 (1991) 455.

Relevance for Lattice data Knowing χ PT , fit with: α + β m2 + γ m3(dashed curve) Best fit with γ as in χ P T Problem: γ = - 0.76 c.f. model independent value -5.6 !! ( From: Leinweber et al., Phys. Rev., D61 (2000) 074502 )

The Solution There is another SCALE in the problem (not natural in dim-regulatedχPT )Λ~ 1 / Size of Source of Goldstone Boson ~ 400 – 500 MeV IF Pion Compton wavelength is smaller than source…..( m≥ 0.4 – 0.5 GeV ; mq ≥ 50-60 MeV)ALL hadron properties are smooth, slowly varying (with mq )and Constituent Quark like ! (Pion loops suppressed like (Λ / m)n ) WHERE EXPANSION FAILS: NEW, EFFECTIVE DEGREE OF FREEDOM TAKES OVER

Model Independent Non-Analytic Behaviour When Pion Compton wavelength larger than pion source: ( i.e. m< 0.4 -0.5 GeV : mq ≤ 50 MeV ) All hadron properties have rapid, model independent, non-analytic behaviour as function of mq : mH (Full QCD) ~ mq3/2 ; mH (QQCD) ~ mq1/2 ; <r2 >ch~ ln mq ; μH ~ mq1/2 ; <r2 >mag ~ 1 / mq1/2

Acceptable Extrapolation Procedure 1. Must respect non-analytic behaviour of χ P T in region m< 400 – 500 MeV (mq ≤ 50 MeV) ………..with correct coefficients! 2. Must suppress chiral behaviour as inverse power of min region m> 400 – 500 MeV 3. No more parameters than lattice data can determine

Extrapolation of Masses At “large m” preserve observed linear (constituent-quark-like) behaviour: MH ~ m2 As m~ 0 : ensure LNA & NLNA behaviour: (BUTmust die as (Λ / m )2 for m> Λ) Hence use: MH = α + β m2 + LNA(m ,Λ)+ NLNA(m,Λ) • Evaluate self-energies with form factor with » 1/Size of Hadron

Behaviour of Hadron Masses with mπ From: Leinweber et al., Phys. Rev., D61 (2000) 074502 » 3M Point of inflection at opening of N channel Lattice data fromCP-PACS & UKQCD » 2M BUT how model dependent is the extrapolation to the physical point?

Evaluation of Self-Energies: Finite Range Regulator • Infrared behaviour is NOT affected by UV cut-off on • Goldstone boson loops. • e.g. for N ! N ! N use sharp cut-off (SC), ( – k) :  ( ,m ) = - 3gA2 / (16 2 f2) [ m3 arctan ( / m) + 3/3 -  m2 ] (/// to “Long Distance Regularization”: Donoghue et al., Phys Rev D59 (1999) 036002) • Coefficient of LNA term !/2 as m! 0 • But coefficient gets rapidly smaller for m ~ (hence hard to determine by naïve fitting procedure • …….. explains “ problem” discussed earlier) •  ~ 1/m2 for m > 

HOW MODEL DEPENDENT? • Quantitative comparison of 6 different regulator schemes • Ask over what range in m2 is there consistency at 1% level? • Use new CP-PACS data from >1 year dedicated running: - Iwasaki gluon action - perturbatively improved clover fermions - use data on two finest lattices (largest ): a = 0.09 & 0.13 fm - follow UKQCD (Phys. Rev. D60 (’99) 034507)in setting physical scale with Sommer scale, r0 = 0.5 fm (because static quark potential insensitive to χ’al physics) - restricted to m2 > 0.3 GeV2 • Also use measured nucleon mass in study of model dependence Young, Leinweber & Thomas, hep-lat/0212031

{ Fit parameters shown in black Regularization Schemes DR: Naïve dimensional regularization MN = c0 + c2m2 + cLNA m3 + c4 m4 + cNLNA m4 ln m+ c6 m6 + ….. BP: Improved dim-reg.... for - loop use correct branch point at m= m4 ln m! (2 – m2)3/2 ln (  + m- [2 – m2]1/2) - /2 (22 -3m2) ln m - for m <  ; ln ! arctan for m >  FRR: Finite Range Regulator – use MONopole, DIPole, GAUssian and Sharp Cutoff in -N and - self-energy integrals: MN = a0 + a2 m2 + a4 m4 + LNA( m, ) + NLNA(m, ) ? Is this more convergent with good choice of FRR ?

Constraint Curves BP DR Dim-Reg curves wrong above last data point All 4 FRR curves indistinguishable. Physicalnucleon mass CP-PACS data

Best fit (bare) parameters N.B. Improved convergence of residual series is dramatic!

Finite Renormalization )Physical Low Energy Constants • True low energy constants, c 0, 2, 4, 6 should not depend on either regularization or renormalization procedure • To check we need formal expansion of LNA and NLNA* : LNA(m,) = b0 + b2 m2 + cLNA m3 + b4 m4 + + … NLNA(m,) = d0 + d2 m2 + d4 m4 + cNLNAm4 ln m4 + … • Hence: c i´ a i + b i + d i and even though each of a i , b i and d i is scheme dependent c i should be scheme independent! * Complete algebraic expressions for di , bi given in hep-lat/0212031: for all regulators

Low Energy Parameters are Model Independent for FRR • Inaccurate higher order coefficients } • SC not as good as other FRR • Note consistency of low energy parameters! } • Note terrible convergence properties of series…..

Unbiased Assessment of Schemes • Take each fit, in turn, as the “exact” data • Then see how well each of the other regulators can reproduce this “data” • Define “goodness of fit”, χ , as area between exact “data” and best fit for given regulator over window m2 (0, mW2) • e.g. with mW2 = 0.5 GeV2,  = 700 MeV2 on average fit is within 1 MeV of “data”

Fits - 1 DIP constraint curve - DR & BP (dim-reg) fail above 0.3 GeV2- all FRR work over entire range! DR constraint curve - all regulators fit well up to 0.4 GeV2

Fits - 2 GAU constraint curve - DR & BP (dim-reg) fail above 0.3 GeV2- all FRR work over entire range! BP constraint curve - all regulators fit well up to 0.4 GeV2

Recovery of Chiral Coefficients Recovery of c0 from fit to BP “data” over window (0,mW2) Region leading to 1% error in MN All regulators work up to 0.7 GeV2 – where BP “data” wrong anyway

Recovery of Chiral Coefficients - 2 Recovery of c0 from fit to DIP “data” over window (0,mW2) Region leading to 1% error in MN DR & BP fail above 0.4 GeV2 : all FRR work over entire range!

Recovery of Chiral Coefficients - 3 Recovery of c2 from fit to BP “data” over window (0,mW2) Region leading to 1% error in MN All regulators work up to 0.7 GeV2 – where BP “data” wrong anyway

Recovery of Chiral Coefficients - 4 Recovery of c2 from fit to DIP “data” over window (0,mW2) Region leading to 1% error in MN DR & BP fail above 0.4 GeV2 : all FRR work over entire range!

Summary : Extraction of Low Energy Constants • For “data” based on DR &BP:all schemes give c0 to <1% for window up to 0.7 GeV2 • BUT dim-reg schemes FAIL at 1% level for FRR once window exceeds 0.5 GeV2 C0: • Similar story for c2:- for “data” based on DR & BP all schemes good enough to • give MNphys to 1% for window up to 0.7 GeV2 - for DIP “data” DR & BP fail above 0.4 GeV2 while all other FRR’s work over entire range (and all except SC give c2 itself to 1% !) C2:

Two-loops : Why SC is not so good • Birse and McGovern* show that at two-loops (in dim-reg)  PT one obtains a term » m5 : _ _ C5 = 3g2 2l4 - 4 (2 d16 –d18) + g2 + 1 --------- ---- --------------- ------ --- 32  f2 f2 g 8 2 f2 8m2 _ _ [Savage & Beane (UW-02-023): -2.6<d16 < - 0.17 ; -1.54 < d18 < -0.51] • BUT (apart from tiny term) they show that its • origin is the Goldberger-Treiman discrepancy i.e. same as difference: g NN (q2=m2) – g NN(0) • FRR : form factor (other than SC, where vanishes) • already accounts for the GT discrepancy at 1-loop – e.g. for MONopole correction goes like g NN (1 – m2/2) * J. McGovern and M. Birse, Phys Lett B446 (’99) 300

Application to lattice extrapolation problem How low do we need to go? • Use DIP curve as the “lattice data” • Take points at 0.05 GeV2intervals from 0.8 GeV2down to mL2 • Then, for each regulator, fit 4 free parameters • Ask how low must mL2 be to determine c0,2,4 ?

Finite Range Regulators Fix c0 Accurately • All FRR work at 2% level; omitting SC they work to better than 1% for mL2 below 0.4 GeV2 ! Dimensional regularization fails at 10% level !

FRR Permit Accurate Determination of c2 Too • DR & BP fail miserably • SC not so good • MON & GAU yield 3% accuracy even for mL2 = 0.4

Does it help dim-reg to lower upper limit? Instead set upper limit at 0.5 GeV2and use “perfect data” at intervals of 0.05 GeV2 : • Dim-reg fails even with data down to mu,d » ms /5 (m2» 0.1 GeV2) • FRR still works to fraction of a percent

Extraction of c2 using smaller interval • DR and BP both introduce error of 40% even with data down to mu,d » ms /5 • FRR show no significant systematic error

Analysis of the Best Available Data Data : CP-PACS Phys Rev D65 ( 2002) Accuracy better than 1% ! Sufficient to determine 4 parameters ……..

Analysis of the Best Available Data

Scheme Dependent Fit Parameters ( Young, Leinweber & Thomas )

Output: Chiral Coefficients, Nucleon Mass and Sigma Commutator ( Young, Leinweber & Thomas ) N.B. Full error analysis to be done and no finite volume corrections applied

Conclusions ♦Study of hadron properties as function of mq in lattice QCD is extremely valuable….. Has given major qualitative & quantitative advance in understanding ! ♦Inclusion of model independent constraints of chiral perturbation theory to get to physical quark mass is essential ♦But radius of convergence of dim-reg χ P T is too small

Conclusions - 2 • Chiral extrapolation problem is solved ! • Use of FRR yields accurate, model independent: - physical nucleon mass - low energy constants • Can use lattice QCD data over entire range m2 up to 0.8 GeV2 • Accurate data point needed at 0.1 GeV2 in order to reduce statistical errors

Conclusions - 3 • Expect similar conclusion will apply to other cases where chiral extrapolation has been successfully applied - Octet magnetic moments - Octet charge radii - Moments of parton distribution functions • Findings suggest new approach to quark models i.e. build Constituent Quark Model where chiral loops are suppressed and make chiral • extrapolation to compare with experimental data(see Cloet et al. , Phys Rev C65 (2002) 062201)

Baryon Masses in Quenched QCD:An Extreme Test of Our Understanding! Chiral behaviour in QQCD quite different from full QCD • ´ is an additional Goldstone Boson , so that: m N = m 0 +c1 m + c2 m2 + cLNA m3 + c4 m4 + cNLNA m4 ln m +..… Contribution from ´ and  LNA term now ~ mq1/2 origin is ´ double pole

Extrapolation Procedure for Nucleon in QQCD Coefficients of non-analytic terms again model independent (Given by: Labrenz & Sharpe, Phys. Rev., D64 (1996) 4595) Let: m N = ´ + ´ m2+QQCD with same  as full QCD

 in QQCD LNA term linear in m ! N  contribution has opposite sign in QQCD (repulsive) Overall  QQCD is repulsive !

Lattice data (from MILC Collaboration) : red triangles • Green boxes: fit evaluating ’s on same finite grid as lattice • Lines are exact, continuum results  (QQCD) • Bullet points  N (QQCD) N From: Young et al., hep-lat/0111041; Phys. Rev. D66 (2002) 094507

Suggests Connection Between QQCD & QCD IF lattice scale is set using static quark potential (e.g. Sommer scale)(insensitive to chiral physics) Suppression of Goldstone loops for m > Λ implies:can determine linear term ( α + β m2) representing “hadronic core” : very similar in QQCD & QCD Can then correct QQCD results by replacing LNA & NLNAbehaviour in QQCD by corresponding terms in full QCD Quenched QCD would then no longer be an “uncontrolled approximation” !

Anthony W. Thomas CSSM