Normalized dijet angular distribution for the dijet mass range 1100 to 1400 GeV.

Normalized dijet angular distribution for the dijet mass range 850 to 1100 GeV.

Normalized dijet angular distribution for the dijet mass range 650 to 850 GeV.

Normalized dijet angular distribution for the dijet mass range 500 to 650 GeV.

Normalized dijet angular distribution for the dijet mass range 350 to 500 GeV.

Normalized dijet angular distribution for the dijet mass range 250 to 350 GeV.

The dimuon yield from Z0 decays per unit rapidity and per unit minumum bias event as a function of centrality, and the nuclear modificationfactor RAA derived by using a POWHEG proton-proton reference.

Distribution of the logarithm of the central thrust minor for events with jet transverse momentum > 30 GeV, jet |pseudorapidity| < 1.3 and leading the jet transverse momentum from 125 to 200 GeV/c,.

Distribution of the logarithm of the central transverse thrust for events with jet transverse momentum > 30 GeV, jet |pseudorapidity| < 1.3 and leading the jet transverse momentum from > 200 GeV/c,.

Distribution of the logarithm of the central thrust minor for events with jet transverse momentum > 30 GeV, jet |pseudorapidity| < 1.3 and leading the jet transverse momentum from > 200 GeV/c,.

The simulated electron pair invariant mass distributions for electrons at $8 < p_{T} < 10$ GeV/c

The distribution of the minimum distance $\Delta$Z (cm) between an electron track projection point at the Barrel Electromagnetic Calorimeter (BEMC) and all BEMC clusters along the beam direction from unlike-sign electron candidate pairs, like-sign electron candidate pairs and unlike-minus-like.

The momentum over energy $p/E_0$ distribution ($p$ - momentum, $E_0$ - the energy of the most energetic tower in a Barrel Electromagnetic Calorimeter cluster) from unlike-sign electron candidate pairs, like-sign electron candidate pairs and unlike-minus-like.

Electron identification efficiency of the cuts on number of TPC points, n$\sigma_e$ and Barrel Electromagnetic Calorimeter cuts in the Run2008 analysis. The total efficiency is the product of all individual ones.

Electron identification efficiency of the cuts on number of TPC points, n$\sigma_e$ and Barrel Electromagnetic Calorimeter cuts in the Run2005 analysis. The total efficiency is the product of all individual ones.

n$\sigma_e$ distribution in the Run2008 analysis for unlike-sign, like-sign and unlike-minus-like pairs at $2.5 < p_T < 3.0$ GeV after applying all the electron identification cuts except the n$\sigma_e$ cut.

n$\sigma_e$ distribution in the Run2008 analysis for unlike-sign, like-sign and unlike-minus-like pairs at $8 < p_T < 10$ GeV after applying all the electron identification cuts except the n$\sigma_e$ cut.

The mean and width of the Gaussian fitting functions for pure photonic electron (unlike - minus-like) n$\sigma_e$ distribution as shown in Fig. 4(a) and Fig 4(b) for each $p_T$ bin.

n$\sigma_e$ distribution for inclusive electrons at (a) $2.5 < p_T < 3.0$ GeV/c in the Run2008 analysis, (b) $2.5< p_T < 3.5$ GeV/c in the Run2005 analysis and (c) $8.0 < p_T < 10.0$ GeV/c in the Run2008 analysis after applying all electron identification cuts except the n$\sigma_e$ cut.

Purity of the inclusive electron sample as a function of $p_T$ in data from Run 2008.

Purity of the inclusive electron sample as a function of $p_T$ in data from Run 2005 with High Tower HT1 trigger.

Purity of the inclusive electron sample as a function of $p_T$ in data from Run 2005 with High Tower HT2 trigger.

Derived $p_T$ spectrum for inclusive photons and the uncertainty represented by the region between the spectra of $\pi^0$ and $\eta$ decay photons and inclusive photon with doubled direct photon yield.

Ratio of photon $p_T$ spectra from Fig. 7(a) to inclusive photons $p_T$ spectrum.

Photonic electron reconstruction efficiency as a function of $p_T$ for $\gamma$ conversion, $\pi^0$ and $\eta$ Dalitz decay for the Run2008 analysis, and for their combination for the Run2008 analysis.

Photonic electron reconstruction efficiency as a function of $p_T$ for $\gamma$ conversion for the Run2005 analysis.

The adc0 distribution for high-tower trigger events. The adc0 is the offline ADC value of a BEMC cluster’s most energetic tower which is one of the high-towers responsible for firing a high-tower trigger.

The $\chi^2$ as a function of the adc0 cut.

Raw inclusive electron $p_T$ spectrum from VPD trigger in Run2008 d+Au collisions before (open squares) and after applying the adc0 > 193 cut.

The adc0 distribution for data at $p_T$ = 4.0 − 5.0 GeV/c

The adc0 distribution for simulations at $p_T$ = 4.0 − 5.0 GeV/c

The $p_T$ dependence of high-tower trigger efficiency from VPD data for Run2008 analysis.

The $p_T$ dependence of high-tower trigger efficiency from simulation for Run2008 analysis.

The $p_T$ dependence of high-tower trigger efficiency for combined VPD data and simulation for Run2008 analysis.

Raw inclusive electron $p_T$ spectrum for minimum-bias (MB) and two high-tower triggers, i.e. HT1 and HT2 for Run2005 analysis.

Raw inclusive electron $p_T$ spectrum for high-tower trigge HT1 for Run2005 analysis.

Raw inclusive electron $p_T$ spectrum for high-tower trigge HT2 for Run2005 analysis.

The $p_T$ dependence of trigger efficiency for the high-tower trigger HT1 data for Run2005.

The $p_T$ dependence of trigger efficiency for the high-tower trigger HT2 data for Run2005.

Distribution of the calculated BBC cross section $\sigma_{BBC}$ before and after removing events at the beginning and the end of Run2008.

Invariant cross section of the electron from decays of $J/\psi$.

Invariant cross section of the electron from decays of $\varUpsilon$.

Invariant cross section of the electron from Drell-Yan decays.

Invariant cross section of the electron from decays of light vector mesons ($\rho,\omega, \phi$).

The uncertainty of the $J/\psi$ feeddown.

Ratio of non-photonic to photonic electron yield from the Run2008 analysis.

Ratio of non-photonic to photonic electron yield from the Run2005 analysis.

Invariant cross section for non-photonic electron production $(e^+ + e^-)/2$ in p+p collisions from the Run2008 analysis.

Invariant cross section for non-photonic electron production $(e^+ + e^-)/2$ in p+p collisions from the Run2005 analysis.

Invariant cross section for non-photonic electron production $(e^+ + e^-)/2$ in p+p collisions from the combined Run2005 and 2008 analyses.

Invariant cross section for non-photonic electron production $(e^+ + e^-)/2$ in p+p collisions (update on PRL 98 (2007) 192301).

Ratio of invariant cross section for non-photonic electron production $(e^+ + e^-)/2$ in p+p collisions from the combined Run2005 and 2008 analyses over FONLL.

Ratio of invariant cross section for non-photonic electron production $(e^+ + e^-)/2$ in p+p collisions (update on PRL 98 (2007) 192301) over FONLL.

Invariant cross section for electrons $(e^+ + e^-)/2$ from bottom meson decay, together with the ratio of the measurements to the FONLL predictions.

Invariant cross section for electrons $(e^+ + e^-)/2$ from charm meson decay, together with the ratio of the measurements to the FONLL predictions.

Relative production rates for jets and di-jets in Au+Au collisions of different centralities with respect to d+Au data.

Calculations of the Glauber-based core/corona model that accommodates inclusive hadron suppression and single jet production rate results.

Conditional di-jet survival probability in Au+Au data compared to d+Au reference.

Conditional di-jet survival probability in Au+Au data compared to d+Au reference.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 640 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 720 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 800 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 880 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 960 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1040 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1120 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1200 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1280 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1360 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1440 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1520 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1600 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1680 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1760 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1840 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1920 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 2000 GeV and Neutralino mass 50 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 400 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 480 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 560 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 640 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 720 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 800 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 880 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 960 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1040 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1120 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1200 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1280 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1360 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1440 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1520 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1600 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1680 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1760 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1840 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1920 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 2000 GeV and Neutralino mass 150 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 400 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 480 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 560 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 640 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 720 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 800 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 880 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 960 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1040 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1120 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1200 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1280 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1360 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1440 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1520 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1600 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1680 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1760 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1840 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 1920 GeV and Neutralino mass 500 GeV.

95 PCT CL upper limits to cross section and the GGM acceptance as a function of Gluino mass for Squark mass 2000 GeV and Neutralino mass 500 GeV.

Lower 95 PCT exclusion limits on the squark and gluino masses for a neutralino mass of 50 GeV.

Lower 95 PCT exclusion limits on the squark and gluino masses for a neutralino mass of 150 GeV.

Lower 95 PCT exclusion limits on the squark and gluino masses for a neutralino mass of 500 GeV.

The double differential cross section as a function of the di-jet mass for the range |y_max| = 1.5-2.0, where |y_max| = max(|y1,|y2|) of the two leading jets in the event.

The double differential cross section as a function of the di-jet mass for the range |y_max| = 2.0-2.5, where |y_max| = max(|y1,|y2|) of the two leading jets in the event.