# The Millennium Simulation scaled conditional mass function data plotted in # Fig. 2 of Cole, Helly Frenk and Parkinson (astro-ph/07081376) MNRAS accepted # # There are 12 datasets labelled by the values of M2 and z1 and corresponding # to the 12 panels of the previous figure (Fig 1). # See the figure caption and the paper for full details # #M2= 1.000e+12 z1=4.0 # log(nu12) log(f) 0.235 -0.484 0.2761 -0.5074 0.3226 -0.5688 0.3765 -0.6943 0.4415 -0.9912 0.5251 -1.806 0.6467 -3.64 # #M2= 1.000e+12 z1=2.0 # log(nu12) log(f) -0.09469 -0.4992 -0.05359 -0.4461 -0.00715 -0.4175 0.04673 -0.3836 0.1117 -0.3403 0.1953 -0.2832 0.3169 -0.5595 0.5663 -2.465 # #M2= 1.000e+12 z1=1.0 # log(nu12) log(f) -0.434 -0.7614 -0.3929 -0.7052 -0.3464 -0.6717 -0.2926 -0.6366 -0.2275 -0.5803 -0.1439 -0.4736 -0.02234 -0.2108 0.227 -0.5769 # #M2= 1.000e+12 z1=0.5 # log(nu12) log(f) -0.7715 -1.019 -0.7304 -0.9742 -0.6839 -0.9436 -0.6301 -0.9127 -0.5651 -0.8675 -0.4814 -0.793 -0.3598 -0.5496 -0.1105 -0.2337 # #M2= 4.160e+13 z1=4.0 # log(nu12) log(f) 0.1379 -0.5146 0.1643 -0.4554 0.192 -0.4617 0.2211 -0.4815 0.2519 -0.5203 0.2845 -0.5681 0.3194 -0.6323 0.3569 -0.7273 0.3977 -0.859 0.4426 -1.032 0.493 -1.344 0.5508 -1.885 0.6199 -3.019 # #M2= 3.160e+13 z1=2.0 # log(nu12) log(f) -0.1918 -0.6292 -0.1654 -0.5148 -0.1377 -0.4821 -0.1086 -0.4666 -0.07784 -0.4535 -0.0452 -0.4446 -0.01034 -0.4313 0.02719 -0.4275 0.06798 -0.4227 0.1129 -0.4154 0.1632 -0.4023 0.2211 -0.4149 0.2901 -0.4557 0.3779 -0.7146 0.5037 -1.838 # #M2= 3.160e+13 z1=1.0 # log(nu12) log(f) -0.5311 -0.8719 -0.5047 -0.753 -0.477 -0.7253 -0.4479 -0.7049 -0.4171 -0.6903 -0.3845 -0.6715 -0.3496 -0.659 -0.3121 -0.6344 -0.2713 -0.611 -0.2264 -0.5797 -0.1761 -0.5447 -0.1182 -0.4974 -0.04914 -0.43 0.03861 -0.3197 0.1644 -0.2211 0.4179 -1.161 # #M2= 3.160e+13 z1=0.5 # log(nu12) log(f) -0.8686 -1.091 -0.8422 -0.987 -0.8145 -0.9609 -0.7854 -0.9504 -0.7546 -0.9412 -0.722 -0.9291 -0.6871 -0.9123 -0.6496 -0.8974 -0.6088 -0.8715 -0.5639 -0.841 -0.5136 -0.8264 -0.4557 -0.7665 -0.3866 -0.6907 -0.2989 -0.6111 -0.1731 -0.327 0.08042 -0.3758 # #M2= 1.000e+15 z1=4.0 # log(nu12) log(f) 0.1274 -0.5087 0.1515 -0.4823 0.1764 -0.4819 0.2023 -0.5042 0.229 -0.536 0.2568 -0.5723 0.2857 -0.6219 0.3159 -0.6777 0.3473 -0.7445 0.3802 -0.8641 0.4147 -0.9419 0.4511 -1.028 0.4896 -1.368 0.5304 -1.58 0.5741 -1.715 0.6212 -2.584 # #M2= 1.000e+15 z1=2.0 # log(nu12) log(f) -0.2023 -0.621 -0.1782 -0.5472 -0.1533 -0.5177 -0.1275 -0.5022 -0.1007 -0.4971 -0.07291 -0.4885 -0.044 -0.501 -0.01387 -0.4772 0.01758 -0.4651 0.05049 -0.4668 0.08502 -0.4642 0.1214 -0.484 0.1598 -0.5076 0.2007 -0.4885 0.2444 -0.5149 0.2915 -0.5578 0.3429 -0.7354 0.3999 -0.668 0.4645 -0.9019 0.5404 -1.997 # #M2= 1.000e+15 z1=1.0 # log(nu12) log(f) -0.5416 -0.8664 -0.5175 -0.7745 -0.4926 -0.7415 -0.4668 -0.7358 -0.44 -0.7174 -0.4122 -0.7077 -0.3833 -0.7089 -0.3532 -0.6935 -0.3217 -0.6651 -0.2888 -0.6579 -0.2543 -0.633 -0.2179 -0.6259 -0.1795 -0.5817 -0.1386 -0.5715 -0.09491 -0.6172 -0.04778 -0.5624 0.003636 -0.5263 0.06061 -0.391 0.1252 -0.396 0.2011 -0.271 0.2958 -0.3464 0.4284 -0.9995 # #M2= 1.000e+15 z1=0.5 # log(nu12) log(f) -0.8791 -1.085 -0.855 -1.009 -0.8301 -0.9648 -0.8043 -0.9673 -0.7775 -0.9529 -0.7497 -0.9615 -0.7208 -0.9372 -0.6907 -0.9323 -0.6592 -0.9234 -0.6263 -0.8997 -0.5918 -0.8415 -0.5554 -0.893 -0.517 -0.894 -0.4761 -0.8349 -0.4324 -0.8009 -0.3853 -0.971 -0.3339 -0.7226 -0.2769 -0.6751 -0.2123 -0.6177 -0.1364 -0.6087 -0.04176 -0.3675 0.09091 -0.1539 0.3514 -0.8733