Collapsed Cores in Globular Clusters, Gauge-Boson Couplings, and AASTeX ExamplesS. Djorgovski and Ivan R. KingAstronomy Department, University of California, Berkeley, CA 94720Visiting Astronomer Cerro Tololo Inter-American Observatory.CTIO is operated by AURA Inc. under contract to the National Science Foundation.Society of Fellows, Harvard University.present address: Center for Astrophysics60 Garden Street, Cambridge, MA 02138C. D. BiemesderferNational Optical Astronomy Observatories, Tucson, AZ 85719Visiting Programmer, Space Telescope Science InstitutePatron, Alonso's Bar and Grillaastex-help@aas.orgR. J. HanischSpace Telescope Science Institute, Baltimore, MD 21218Patron, Alonso's Bar and Grill
clusters: globular, peanut—bosons: bozos
This is a preliminary report on surface photometry of the major fraction of known globular clusters, to see which of them show the signs of a collapsed core. We also explore some diversionary mathematics and recreational tables. IntroductionA focal problem today in the dynamics of globular clusters is core collapse. It has been predicted by theory for decades , , , but observation has been less alert to the phenomenon. For many years the central brightness peak in M15 , seemed a unique anomaly. Then suggested a central peak in NGC 6397, and a limited photographic survey of ours found three more cases, including NGC 6624, whose sharp center had often been remarked on . ObservationsAll our observations were short direct exposures with CCD's. At Lick Observatory we used a TI 500\times×500 chip and a GEC 575\times×385, on the 1-m Nickel reflector. The only filter available at Lick was red. At CTIO we used a GEC 575\times×385, with B,V,B,V, and RR filters, and an RCA 512\times×320, with U,B,V,R,U,B,V,R, and II filters, on the 1.5-m reflector. In the CTIO observations we tried to concentrate on the shortest practicable wavelengths; but faintness, reddening, and poor short-wavelength sensitivity often kept us from observing in UU or even in BB. All four cameras had scales of the order of 0.4 arcsec/pixel, and our field sizes were around 3 arcmin.The CCD images are unfortunately not always suitable, for very poor clusters or for clusters with large cores. Since the latter are easily studied by other means, we augmented our own CCD profiles by collecting from the literature a number of star-count profiles , , , , as well as photoelectric profiles , and electronographic profiles . In a few cases we judged normality by eye estimates on one of the Sky Surveys.Helicity AmplitudesIt has been realized that helicity amplitudes provide a convenient means for Feynman diagramFootnotes can be inserted like this. evaluations. These amplitude-level techniques are particularly convenient for calculations involving many Feynman diagrams, where the usual trace techniques for the amplitude squared becomes unwieldy. Our calculations use the helicity techniques developed by other authors ; we briefly summarize below.FormalismA tree-level amplitude in e^{+}e^{-}e+e- collisions can be expressed in terms of fermion strings of the form
\bar{v}(p_{2},\sigma_{2})P_{-\tau}\hat{a}_{1}\hat{a}_{2}\cdots\hat{a}_{n}u(p_{1},\sigma_{1}),v¯(p2,σ2)P-τaˆ1aˆ2⋯
aˆnu(p1,σ1), where pp and \sigmaσ label the initial e^{\pm}e± four-momenta and helicities (\sigma=\pm1)(σ=±1), \hat{a}_{i}=a_{i}^{\mu}\gamma_{\nu}aˆi=aiμγν and P_{\tau}=\frac{1}{2}(1+\tau\gamma_{5})Pτ=12(1+τγ5) is a chirality projection operator (\tau=\pm1)(τ=±1). The a_{i}^{\mu}aiμ may be formed from particle four-momenta, gauge-boson polarization vectors or fermion strings with an uncontracted Lorentz index associated with final-state fermions.Figures 1 and 2 should appear side-by-side in printIn the chiral representation the \gammaγ matrices are expressed in terms of 2\times22×2 Pauli matrices \sigmaσ and the unit matrix 1 as
\gamma^{\mu} & = & \left(\begin{array}{cc}
0 & \sigma_{+}^{\mu}\\
\sigma_{-}^{\mu} & 0
\end{array}\right),\gamma^{5}=\left(\begin{array}{cc}
-1 & 0\\
0 & 1
\end{array}\right),\\
\sigma_{\pm}^{\mu} & = & ({\textbf{1}},\pm\sigma),
γμ=(0σ+μσ-μ0),γ5=(-1001),σ±μ=(1,±σ), giving
\hat{a}=\left(\begin{array}{cc}
0 & (\hat{a})_{+}\\
(\hat{a})_{-} & 0
\end{array}\right),(\hat{a})_{\pm}=a_{\mu}\sigma_{\pm}^{\mu},aˆ=(0(aˆ)+(aˆ)-0),(aˆ)±=aμσ±μ, The spinors are expressed in terms of two-component Weyl spinors as
u=\left(\begin{array}{c}
(u)_{-}\\
(u)_{+}
\end{array}\right),v={\textbf{(}}\vdag_{+}{\textbf{,}}\vdag_{-}{\textbf{)}}.MathML export failed. Please report this as a bug.The Weyl spinors are given in terms of helicity eigenstates \chi_{\lambda}(p)χλ(p) with \lambda=\pm1λ=±1 by u(p,\lambda)_{\pm} & = & (E\pm\lambda|{\textbf{p}}|)^{1/2}\chi_{\lambda}(p),\\
v(p,\lambda)_{\pm} & = & \pm\lambda(E\mp\lambda|{\textbf{p}}|)^{1/2}\chi_{-\lambda}(p)
u(p,λ)±=(E±λ|p|)1/2χλ(p),v(p,λ)±=±λ(E∓λ|p|)1/2χ-λ(p)Floating material and so forthConsider a task that computes profile parameters for a modified Lorentzian of the form
I=\frac{1}{1+d_{1}^{P(1+d_{2})}}I=11+d1P(1+d2) where
d_{1}=\sqrt{\left(\begin{array}{c}
\frac{x_{1}}{R_{maj}}\end{array}\right)^{2}+\left(\begin{array}{c}
\frac{y_{1}}{R_{min}}\end{array}\right)^{2}}d1=(x1Rmaj)2+(y1Rmin)2d_{2}=\sqrt{\left(\begin{array}{c}
\frac{x_{1}}{PR_{maj}}\end{array}\right)^{2}+\left(\begin{array}{c}
\case{y_{1}}{PR_{min}}\end{array}\right)^{2}}MathML export failed. Please report this as a bug.x_{1}=(x-x_{0})\cos\Theta+(y-y_{0})\sin\Thetax1=(x-x0)cosΘ+(y-y0)sinΘy_{1}=-(x-x_{0})\sin\Theta+(y-y_{0})\cos\Thetay1=-(x-x0)sinΘ+(y-y0)cosΘIn these expressions x_{0}x0,y_{0}y0 is the star center, and \ThetaΘ is the angle with the xx axis. Results of this task are shown in table . It is not clear how these sorts of analyses may affect determination of M_{\text{\sun}}M☼, but the assumption is that the alternate results should be less than 90° out of phase with previous values. We have no observations of
. Roughly \nicefrac{4}{5}45 of the electronically submitted abstracts for AAS meetings are error-free. We are grateful to V. Barger, T. Han, and R. J. N. Phillips for doing the math in section . More information on the AASTeX macros package are available at http://www.aas.org/publications/aastex or the AAS ftp site.
IRAF, AIPS, Astropy, ...
Aurière, M. 1982,
, 109, 301 Canizares, C. R., Grindlay, J. E., Hiltner, W. A., Liller, W., and McClintock, J. E. 1978,
, 224, 39 Djorgovski, S., and King, I. R. 1984,
, 277, L49 Hagiwara, K., and Zeppenfeld, D. 1986, Nucl.Phys., 274, 1 Harris, W. E., and van den Bergh, S. 1984,
, 89, 1816 Hénon, M. 1961, Ann.d'Ap., 24, 369 King, I. R. 1966,
, 71, 276 King, I. R. 1975, Dynamics of Stellar Systems, A. Hayli, Dordrecht: Reidel, 1975, 99 King, I. R., Hedemann, E., Hodge, S. M., and White, R. E. 1968,
, 73, 456 Kron, G. E., Hewitt, A. V., and Wasserman, L. H. 1984,
, 96, 198 Lynden-Bell, D., and Wood, R. 1968,
, 138, 495 Newell, E. B., and O'Neil, E. J. 1978,
, 37, 27 Ortolani, S., Rosino, L., and Sandage, A. 1985,
, 90, 473 Peterson, C. J. 1976,
, 81, 617 Spitzer, L. 1985, Dynamics of Star Clusters, J. Goodman and P. Hut, Dordrecht: Reidel, 109
Terribly relevant tabular information.
Star
Height
d_{x}dx
d_{y}dy
nn
\chi^{2}χ2
R_{maj}Rmaj
R_{min}Rmin
PPa
PR_{maj}PRmaj
PR_{min}PRmin
\ThetaΘb
Ref.
1
33472.5
-0.1
0.4
53
27.4
2.065
1.940
3.900
68.3
116.2
-27.639
1,2
2
27802.4
-0.3
-0.2
60
3.7
1.628
1.510
2.156
6.8
7.5
-26.764
3
3
29210.6
0.9
0.3
60
3.4
1.622
1.551
2.159
6.7
7.3
-40.272
4
4
32733.8
-1.2c
-0.5
41
54.8
2.282
2.156
4.313
117.4
78.2
-35.847
5,6
5
9607.4
-0.4
-0.4
60
1.4
1.669c
1.574
2.343
8.0
8.9
-33.417
7
6
31638.6
1.6
0.1
39
315.2
3.433
3.075
7.488
92.1
25.3
-12.052
8
a
Sample footnote for table that was generated with the LaTeX table environmentb
Yet another sample footnote for table c
Another sample footnote for table We can also attach a long-ish paragraph of explanatory material to a table. Use \tablerefs to append a list of references. The following references were from a different table: I've patched them in here to show how they look, but don't take them too seriously—I certainly have not.(1) Barbuy, Spite, & Spite 1985; (2) Bond 1980; (3) Carbon et al. 1987; (4) Hobbs & Duncan 1987; (5) Gilroy et al. 1988: (6) Gratton & Ortolani 1986; (7) Gratton & Sneden 1987; (8) Gratton & Sneden (1988); (9) Gratton & Sneden 1991; (10) Kraft et al. 1982; (11) LCL, or Laird, 1990; (12) Leep & Wallerstein 1981; (13) Luck & Bond 1981; (14) Luck & Bond 1985; (15) Magain 1987; (16) Magain 1989; (17) Peterson 1981; (18) Peterson, Kurucz, & Carney 1990; (19) RMB; (20) Schuster & Nissen 1988; (21) Schuster & Nissen 1989b; (22) Spite et al. 1984; (23) Spite & Spite 1986; (24) Hobbs & Thorburn 1991; (25) Hobbs et al. 1991; (26) Olsen 1983.