Abstract

Aims. We present an overview of a high-mass star formation region through the major (sub-)mm, and far-infrared cooling lines to gain insight into the physical conditions and the energy budget of the molecular cloud. Methods. We used the KOSMA 3 m telescope to map the core ($10'\times 14'$) of the Galactic star-forming region DR21/DR21 (OH) in the Cygnus X region in the two fine structure lines of atomic carbon ($\ion{C}{i}$ $^3\mathrm{P}_1{-}^3\mathrm{P}_0$ and $^3\mathrm{P}_2{-}^3\mathrm{P}_1$), in four mid-J transitions of CO and 13CO, and in CS $J=7{-}6$. These observations were combined with FCRAO $J=1{-}0$ observations of 13CO and C18O. Five positions, including DR21, DR21 (OH), and DR21 FIR1, were observed with the ISO/LWS grating spectrometer in the [$\ion{O}{i}$] 63 and 145 μm lines, the [$\ion{C}{ii}$] 158 μm line, and four high-J CO lines. We discuss the intensities and line ratios at these positions and apply the local thermal equilibrium (LTE) and non-LTE analysis methods in order to derive physical parameters such as mass, density and temperature. The CO line emission was modeled up to $J=20$. Results. From non-LTE modeling of the low- to high-J CO lines, we identify two gas components, a cold one at temperatures of $T_\mathrm{kin}\sim 30{-}40$ K and one with $T_\mathrm{kin}\sim 80{-}150$ K at a local clump density of about n(H2) ~ $10^4{-}10^6$ cm-3. While the cold quiescent component is massive, typically containing more than 94% of the mass, the warm, dense, and turbulent gas is dominated by mid- and high-J CO line emission and its large line widths. The medium must be clumpy with a volume-filling of a few percent. The CO lines are found to be important in cooling the cold molecular gas, e.g. at DR21 (OH). Near the outflow of the UV-heated source DR21, the gas cooling is dominated by line emission of atomic oxygen and of CO. Atomic and ionised carbon play a minor role.