4.1. Spectra towards each high-mass clump

For each clump, we have extracted an averaged spectrum from the MALT90 datacubes for each of the 16 emission lines. The spectra were created by averaging the spectra in a 3 ×3 pixel ( $27\, \text{arcsec} \times 27\, \text{arcsec}$ ) box around the clump’s dust peak determined from the ATLASGAL catalogues. The size of the averaging box was selected to maximise the signal to noise of the fainter emission and is approximately the angular resolution of MALT90 (for details on the data reduction pipeline, see Jackson et al. Reference Jackson2013). Note that all spectra and Gaussian profile fitting are shown and performed on the T*_A scale. To convert to main-beam brightness temperature (T _mb), the antenna temperature (T*_A) should be divided by the main-beam efficiency ( $\eta _{\text{mb}}$ ) of 0.49 (Ladd et al. Reference Ladd, Purcell, Wong and Robertson2005).

Because some MALT90 maps covered more than one ATLASGAL clump, the total number of clumps observed (3 246) is greater than the number of maps obtained (2 014).

4.2. Additional baseline subtraction

While a first-order baseline subtraction was performed during the automated processing of the data cubes (see Jackson et al. Reference Jackson2013), the reliability of the Gaussian profile fitting was often considerably improved when we performed an additional higher order fit to the baseline. This was necessary because in poorer weather, the MALT90 spectra were often contaminated by non-linear baselines and baseline ripple, especially at the highest frequency band containing N₂H⁺. Consequently, a first-order polynomial was often an inadequate model of the baseline, and the automated routine often failed to properly select signal-free velocity ranges. This additional baseline fit and subtraction was individually performed on each spectrum.

4.3. Noise estimation

The root-mean-square (rms) noise level in each spectrum was calculated from a comparison of the amplitude for each odd-numbered channel with the amplitude in the preceding even-numbered channel via

$$\begin{equation*} \sigma _{{\rm noise}} = 1.067 \sqrt{\frac{\langle (y_{2j+1}-y_{2j})^{2} \rangle _{j}}{2}}, \end{equation*}$$

where y_j is the amplitude in channel j. This assumes Gaussian noise in the presence of a slowly varying spectral signal or baseline variations much broader than the spectral channel spacing. This channel-to-channel estimator of σ_noise is robust against the presence of baseline ripples and line emission signals within the spectrum. As such, it represents a more accurate method to reliably determine, in an automated way, the noise level in a spectrum that may have baseline ripples and/or bright line emission anywhere within it, compared to common methods that first require the line to be identified and masked before then applying a simple standard deviation approach. The factor 1.067 corrects for the slight channel-to-channel correlation introduced by the subtraction of a smoothed reference spectrum in the MALT90 data reduction pipeline, the size of this correlation depends on the size of the smoothing window (the pipeline utilised Hanning smoothing with an 11-channel window, see Jackson et al. Reference Jackson2013).

Figure 9 shows the normalised cumulative distribution of σ_noise derived from the spectra of each emission line. The bold line shows the cumulative distribution for the synthetic spectra (see Section 4.5). The tail at high noise levels arises from spectra near the map edges and those obtained when the weather was marginal for 90 GHz observations. The derived noise distribution from the 16 emission lines follow each other closely, with the exception of HNCO 4(1,3)–3(1,2) which suffered from serious noise spikes and/or band distortions (shown with the dashed line). We examined all possible ‘detections’ of HNCO 4(1,3)–3(1,2) and concluded that there were no credible signals in any of the spectra; the detection flag in the catalogue is always set to ‘N’ for this emission (see Section 2.4.3). For all other emission lines, 90% of the spectra have σ_noise < 0.24 K, while 50% have σ_noise < 0.18 K on the antenna temperature (T*_A) scale.

Figure 9. Normalised cumulative distributions of σ_noise derived from the spectra of each emission line. The bold line shows the cumulative distribution for the synthetic spectra (see Section 4.5). The tail at high noise levels arises from spectra near the map edges and those obtained when the weather was variable. The noise distribution derived from the spectra of each of the 16 lines follow each other closely, with the exception of HNCO 4(1,3)–3(1,2) which suffered from serious band distortions (marked with the dashed line). For all other lines, 90% of the spectra have σ_noise < 0.24 K and 50% have σ_noise < 0.18 K (these σ_noise levels are marked with the dotted lines).

4.4. Gaussian profile fitting

In order to characterise the detected emission towards each clump, we have fit each spectrum with either a single or multiple Gaussian profile(s). These profile fits provide key parameters typically used to describe line emission: peak antenna temperature (T*_A), FWHM (ΔV), and central velocity (V _LSR). In the catalogue, we report the integrated intensity (II) calculated directly from summing T*_A over all channels in the fit range (each channel is independent, with a spectral resolution of $\text{d}v$ ). We choose to calculate II by summing the actual emission, rather than using the derived Gaussian parameters, since the former will also include any component of the line that is non-Gaussian (the exception to this is for C₂H; in this case, we sum under the Gaussian profile fit, since the hyperfine components are well-separated in velocity). The II signal-to-noise ratio, II_SNR, was determined by dividing the II by σ _II , where $\sigma _{II} = \sqrt{N_{{\rm channel}}} \sigma _{{\rm noise}} \text{d}v$ , and N _channel is the number of channels in the fitting region. The antenna temperature signal-to-noise ratio, T _SNR, was defined as T _SNR= T*_A /σ_noise.

The profile fitting was performed on the baseline-subtracted spectra as a two-step process: the first iteration was performed on the most prominent peaks in the HCO⁺, HNC, and N₂H⁺ spectra to determine a ‘consensus’ velocity (V _C), while the second iteration was performed on all 16 lines restricting the velocity range over which to search for emission to be V _C ± 5 km s⁻¹. This two-step method was employed as it resulted in significantly higher detection rates and more reliable fits to the fainter emission.

4.4.5. Opacities

For all clumps in which the N₂H⁺ emission could be fit with a three component Gaussian profile (i.e., in 2256 cases), we have derived an optical depth (τ) of the main hyperfine component (J′F′₁ F′ → JF ₁ F = 123 → 012). Assuming LTE, where the excitation temperatures of the three components are the same, we follow the description outlined in Shirley et al. (Reference Shirley, Nordhaus, Grcevich, Evans, II, Rawlings and Tatematsu2005) and calculate the optical depth of the main hyperfine component by taking the ratios of the observed antenna temperatures of the left and right components to the main component (i.e., the 101-012, 112-012, and 123-012 hyperfine components, respectively; these are labelled by their J′F′₁ F′ → JF ₁ F transitions). The optical depth was determined numerically by finding the minimum of the function:

$$\begin{equation*} f(\tau )=\left(2-\left(\frac{T_{\text{L}}(1-e^{-\tau })}{T_{\text{M}}(1-e^{-r_{\text{L}}\tau })}\right)^2-\left(\frac{T_{\text{R}}(1-e^{-\tau })}{T_{\text{M}}(1-e^{-r_{\text{R}}\tau })}\right)^2\right)^2 \end{equation*}$$

over the range − 3 < τ < 6, where T $_{\text{L}}$ , T $_{\text{M}}$ , and T $_{\text{R}}$ are the fitted T*_A amplitudes for the left, main, and right components, respectively and r $_{\text{L}}$ and r $_{\text{R}}$ are the relative intensities calculated based on each clump’s line width (see Shirley et al. Reference Shirley, Nordhaus, Grcevich, Evans, II, Rawlings and Tatematsu2005 for details).

4.5. Completeness and reliability analysis

To determine the completeness and reliability of the detections reported in the catalogue, we generated a series of synthetic spectra which were passed through the same automated line-fitting procedure as described above. For this analysis, we assume that there is a single Gaussian component in each spectrum (i.e., that there is one velocity component along the line of sight), that all profiles are Gaussian, and that the simulated emission arises from a molecular transition that shows no hyperfine splitting. All values for, or derived from, the synthetic spectra have the subscript ‘syn’.

The synthetic spectra were based on noise spectra drawn randomly from the MALT90 maps for HC¹³CCN, ¹³C³⁴S, and H 41α (these maps were selected since the emission from these transitions were rarely detected). A candidate noise spectrum was generated by averaging spectra in a 3 × 3 pixel box selected randomly according to the distribution of ATLASGAL clump peak positions within the MALT90 maps. The noise spectrum was passed through the baseline subtraction and Gaussian fitting procedure; if a signal was detected with peak amplitude greater than 1.5 times the σ_noise of the spectrum then that noise spectrum was rejected. Amplitudes of an accepted candidate noise spectrum were then multiplied by − 1.0 to produce a final noise spectrum for use in the analysis. The output of this process was an ensemble of 10 000 noise spectra that statistically sampled the maps with the same weighting in relevant parameters (e.g., observing conditions, galactic longitude, and position within the maps) as the spectra extracted towards each clump.

4.5.1. Completeness

To determine the completeness of the reported detections, we superposed Gaussian profiles on the noise spectra and then passed these synthetic spectra through the automated line-fitting procedure. Values for the peak antenna temperature (T _syn) were selected uniformly from 0.0 to 1.0 K; values for the line-width (ΔV _syn) were selected uniformly from 1.6 to 5 km s⁻¹; and values for the central velocity (V _syn) were selected randomly from the range ± 150 km s⁻¹. The V _C was set randomly in the range ± 3 km s⁻¹ around V _syn. These were chosen as they represent the typical values and ranges for these parameters measured within the survey data. We use the same detection criteria for the synthetic spectra as we applied to the real data: a synthetic profile was considered to be ‘detected’ if the II_SNR was > 4, and the T _SNR > 1. We impose one additional criterion for the synthetic spectra: the derived central velocity from the Gaussian profile fit must be within ± 1 km s⁻¹ of the input V _syn.

We used the synthetic spectra to determine the probability of detecting a line (completeness) as a function of our detection criteria. The upper panel of Figure 10 shows completeness as a function of T _{SNR, syn} (i.e., T _syn/σ_noise); the middle panel shows completeness as a function of the ratio of II_{SNR, syn} (i.e., II_syn/σ_noise). In both panels, the dashed curve corresponds to the expanded scale shown on the right. The dotted vertical lines mark a T _{SNR, syn} of 1 and an II_{SNR, syn} of 3 and 4, which correspond to the criteria imposed for detections to be included within the catalogue.

Figure 10. Completeness (probability of detecting a line) as a function of the T _{SNR, syn} (upper panel), II_{SNR, syn} (middle panel), and input T _syn (lower panel). In all panels, the dashed curves correspond to the expanded scale shown on the right axis. The error bars show the statistical uncertainties in the synthetic sample. The vertical dotted lines in the upper and middle panels mark the selection criteria imposed for detections to be included within the catalogue (i.e., T _SNR > 1 and II_SNR > 3 or > 4, for ‘marginal’ and ‘reliable’ detections, respectively). The vertical dotted lines in the lower panel mark the completeness levels. The achieved completeness levels are > 95% for detections with a measured T*_A > 0.4 K and > 99% for detections with a T*_A > 0.6 K.

We find that the completeness versus T _{SNR, syn} rises rapidly, a consequence of the peak-fitting algorithm starting from the highest amplitude channel in the search region. Completeness versus II_{SNR, syn} rises somewhat more slowly, reaching 80% by II_{SNR, syn} = 4 and 99% by II_{SNR, syn} = 8. The lower panel of Figure 10 shows the completeness as a function of T _syn. Since T _syn in these spectra represents the measured T*_A from our data, these results indicate that we achieve a completeness of > 95% for detections with a measured T*_A > 0.4 K and > 99% for detections with a T*_A > 0.6 K.

4.5.2. Reliability

Passing the noise spectra through our standard analysis procedure provided a measure of the reliability of detections, i.e., the probability of an accidental (false-positive) detection, as a function of detection criteria. Figure 11 shows the normalised cumulative distribution in II_SNR determined from the noise spectra (note, this will characterise accidental detections due to noise and baseline fluctuations). The probability of a false-positive detection is < 0.3% for an II_SNR > 3.

Figure 11. Normalised cumulative distributions in II_SNR for the synthetic noise spectra (note, this will characterise accidental detections due to noise and baseline fluctuations). The dashed curves correspond to the expanded scale shown on the right axis. The vertical dotted lines mark the selection criteria imposed for detections to be included within the catalogue: an II_SNR of > 3 for ‘marginal’ and > 4 for ‘reliable’ detections, respectively. We find that the probability of a false-positive detection is < 0.3% for an II_SNR > 3.

By comparing the fitting results with the known characteristics used to generate the synthetic profiles, we have also determined the reliability with which the fitting procedure recovers the Gaussian parameters: amplitude, velocity, line-width, and II, and the accuracy with which it estimates their uncertainties. Figure 12 compares the derived parameters to the input values (panels are amplitude, line-width, velocity, and II, respectively, from upper to lower). For the amplitude, line-width, and II, we calculate the ratio of derived values to input values; for the velocity, we calculate the difference. For input T _syn > 0.24 K, the distributions are close to unity, which indicates that the fitting procedure accurately determines all three Gaussian parameters (amplitude, line width, and II) and introduces no significant bias in its estimations. Indeed, the relative uncertainty in these quantities, as estimated by the standard deviations of the ratios from unity (shown as the error bars), was ~20% for T _syn ~0.24 K and improved to < 5% for T _syn > 1 K.

Figure 12. Reliability with which the derived parameters (amplitude, velocity, line-width, and integrated intensity, upper to lower panels, respectively) are estimated. These reliabilities were determined by comparing the fitting results with the known characteristics used to generate the synthetic profiles (these comparisons are shown as ratios, with the exception of velocity, which are differences). The error bars reflect the uncertainty with which the automated routine estimates their values. The dotted vertical lines mark a T _syn of 0.24 K (90% of the spectra have noise less than this value).

7.1. The MALT90 sample: representative of typical cluster-forming clumps

ATLASGAL was a systematic, unbiased survey of dust continuum emission with the goal of identifying and characterising high-mass clumps within the Galaxy (Schuller et al. Reference Schuller2009). As such, the catalogues derived from this survey represent an excellent database for detailed studies of these clumps.

The MALT90 survey mapped 3 246 clumps that were identified within ATLASGAL (within the Galactic longitude range of − 60 to +20°). To demonstrate that the MALT90-selected clumps are representative of the larger ATLASGAL sample, Figure 13 shows histograms of the 870 μm peak flux from ATLASGAL for the clumps included within MALT90 (thin histogram), along with the ATLASGAL sample for comparison (thick histogram). MALT90 observed almost all (~90%) of the ATLASGAL clumps with fluxes > 1 Jy, and ~60% of the ATLASGAL clumps with fluxes between 0.25 and 1 Jy. Those ATLASGAL clumps that were not included within MALT90 are typically located within the Galaxy’s CMZ or in the first Galactic quadrant: MALT90’s primary goal was to cover clumps within the fourth Galactic quadrant.

Figure 13. Histograms of the 870 μm peak flux for clumps covered by the MALT90 survey (thin histogram). In all panels, clumps from the ATLASGAL survey are shown as thick histograms, while the dotted histograms show the flux distribution of those clumps covered by MALT90 survey and detected in more than the labelled number of lines (i.e. NL ⩾ 1, 4, 6, and 8; upper to lower panels, respectively).

The panels of Figure 13 also shows the 870 μm flux distribution for the MALT90 clumps separated by the number of lines detected towards them (i.e., NL ⩾ 1, 4, 6, and 8, from upper to lower panels, respectively; dotted histograms). The clumps with no detected lines (160 in total) are typically the faintest 870 μm clumps (see the upper panel of Figure 13), while those with multiple lines detected towards them are amongst the brightest 870 μm clumps (see the lower panels in Figure 13).

The trend of brighter 870 μm clumps having a higher number of lines detected towards them is also seen when the MALT90 sample is separated into the IR-based categories (see Figure 14). Regardless of the category, the brightest 870 μm clumps within each group have a higher fraction of lines detected towards them. Moreover, those that have no detected emission tend to be at the fainter end of the ATLASGAL flux distribution.

Figure 14. Histograms of the 870 μm peak flux for clumps covered by the MALT90 survey, separated by the IR-based categories (quiescent, protostellar, $\mathrm{H\,{\scriptstyle {II}}}$ regions, and PDRs, left to right, respectively). In all panels, clumps included within MALT90 are shown as thin histograms, while the dotted histograms show the flux distribution of those clumps covered by MALT90 survey and detected in more than the labelled number of lines (i.e. NL ⩾ 1, 4, 6, and 8; upper to lower panels, respectively).

7.2. Detection statistics

In addition to listing information about the emission lines observed as part of the MALT90 survey, Table 1 also summarises the detection rates for each line.Footnote ³ We find that the detection rates are highest for the four (1–0) molecular transitions of HCO⁺, HNC, N₂H⁺, and HCN (~77–89%). A small number of clumps are detected in the lines of ¹³C³⁴S, HC¹³CCN, and H 41α (8, 8, and 20 respectively); the number of clumps detected in each line is listed in Table 1.

Figure 15 shows that most clumps (~95%) are detected in at least one line. Just over half of the clumps (~53%) are detected in four or more transitions, while only one clump is detected in 13 transitions (AGAL351.444+00.659_S).

Figure 15. Number of clumps plotted as a function of the number of emission lines detected towards each (bar plot; left axis). The dotted line (right axis) shows the percentage of clumps with > n detections in the full survey. Most clumps (~95%) are detected in one or more of the dense gas tracers, ~53% of the clumps have detections from four or more emission lines, while one clump is detected in 13 lines. Also, overlaid are the percentages of quiescent and protostellar clumps with > n detections (right axis; dashed and dot-dashed lines, respectively). Clumps with active star formation (indicated by the ‘protostellar’ curve) have a both a higher percentage of detections and more lines detected towards them compared to the full survey and those clumps that appear to be more quiescent.

Figure 16 shows the normalised cumulative distribution of the T _SNR and II_SNR for each of the emission lines. The vertical dotted lines in all panels mark the cuts used to define detections for inclusion in the catalogue (i.e., T _SNR > 1 and II_SNR > 3, in the case of marginal detections, or T _SNR > 1 and II_SNR > 4 in the case of reliable detections). Flat curves in these plots (e.g., the II_SNR curves for HCO⁺, HNC, N₂H⁺, HCN, SiO, HNCO, CH₃CN, and H 41α) imply that the inclusion or exclusion of detections is insensitive to the exact choice of the selection criteria. In contrast, for curves that rise steeply (e.g., the II_SNR curves for C₂H, H¹³CO⁺, HC₃N, HN¹³C, and ¹³CS), the exact choice of the selection criteria does significantly affect the number of detections that are included in the catalogue. To avoid unnecessary exclusion of possible detections, we mark in the catalogue all detections with a derived 3 < II_SNR < 4 as ‘marginal’. Note that the selection criteria of T _SNR > 1 has little effect, since almost all lines have values greater than this. However, this cut was imposed as part of the selection of reliable detections to avoid the inclusion of very broad lines that have a high II, but are not discernible above the noise in T*_A (i.e., any remaining slowly varying baselines that were inadequately removed).

Figure 16. Normalised cumulative distributions of T _SNR (left panel) and II_SNR (middle and right panels). In all panels, curves are labelled with the name of corresponding emission line. The vertical dotted lines mark the selection criteria imposed for detections to be included within the catalogue: T _SNR > 1 and an II_SNR > 3 for ‘marginal’ or > 4 for ‘reliable’ detections, respectively. Flat curves imply that the inclusion/exclusion of detections is insensitive to the exact choice of the selection criteria (i.e., in the II_SNR plot for HCO⁺, HNC, N₂H⁺, HCN, SiO, HNCO, CH₃CN, and H 41α). In contrast, for curves that rise steeply, the exact choice of the II_SNR (3 or 4) does significantly affect the number of reported detections included in the catalogue (i.e., for C₂H, H¹³CO⁺, HC₃N, HN¹³C, and ¹³CS).

The upper panel of Figure 17 shows the percentage of clumps that were detected in each of the emission lines. As expected, the highest detection rates of the lines covered by MALT90 arise from the (1–0) transitions of HCO⁺, HNC, N₂H⁺, and HCN. Of the isotopologues, H¹³CO⁺ has the highest detection rate, followed by HN¹³C. The molecule C₂H is also frequently detected towards the clumps (~51%).

Figure 17. Detection rates (upper panel; separated by the significance of the detection, ‘Y’ or ‘M’), the number of Gaussian profiles in the best fit for these detections (middle panel; 1, 2, or 3), and the significance of the residuals in the fit range (lower panel; R $_{\text{f}}$ < 1.5, HR = 0 or R $_{\text{f}}$ > 1.5, HR = 1) for all emission lines. Note for HNCO 4(1,3)–3(1,2), since there was no emission detected towards any of the clumps, the percentages in the top two panels are zero; however, the lower panel (which plots the residual in the fit range) shows that all the spectra have low residuals, which is consistent with non-detections in all cases.

The middle panel of Figure 17 shows the percentage of clumps with detections for each emission line, separated out by the number of Gaussian profiles that were fit to the spectrum (i.e., 1, 2, or 3; dark grey, grey, and light grey bars, respectively). In the majority of cases for transitions without hyperfine splitting, the best fit was found when fitting a single Gaussian profile to the emission (dark grey bars). For transitions with hyperfine splitting (N₂H⁺, HCN, and C₂H), the best fit was most often found when it included the known hyperfine structure (light grey bars). However, in a small number of cases, a single Gaussian profile was found to produce the best fit; this occurred when individual hyperfine components could not be easily separated, either due to broad line-widths or low signal to noise (~7%, ~15% and ~2% for N₂H⁺, HCN, and C₂H, respectively).

The lower panel of Figure 17 shows the percentage of clumps with detections for each molecular transition, separated by the significance of the residual that remains after the best-fitting profile(s) are removed. Dark grey bars show the percentage of clumps for which the residuals are low (i.e., HR = 0); light grey bars indicate the percentage where the residuals are high (HR = 1). The spectra from HCO⁺ show the highest percentage of those with HR, which is expected since this molecular transition typically has the highest optical depth of those included in the survey (e.g., Sanhueza et al. Reference Sanhueza, Jackson, Foster, Garay, Silva and Finn2012; Hoq et al. Reference Hoq2013). As such, HCO⁺ is therefore an excellent tracer of outflow and infall motions that give rise to non-Gaussian line profiles.

7.3. Distributions of the derived parameters

To determine whether the various molecular transitions are tracing similar or distinct physical regions, we have plotted in Figure 18 the distribution functions of the ratio of II to the mean II (II/mean(II); left), line-width (ΔV; middle), and the difference between the derived velocity and the V _C (V–V _C; right), for a subset of the detected molecular transitions.

Figure 18. Histograms of the integrated intensity (II, relative to the median, left), line width (ΔV, middle), and V − V _C (right) for most of the emission lines (we only include in these plots those emission lines with more than 50 detections within the survey, see Table 1). The vertical dotted lines mark a value of 1.0 for the ratio of II to median(II), a line-width of 2.8 km s⁻¹, (the mean value derived from N₂H⁺), and a value of 0 for the velocity difference (V − V _C), respectively. They are included for ease of comparison between the panels. Note that the y-axes for the right column are in a logarithmic scale. The error bars show the $\sqrt{N}$ uncertainties.

As might be expected for optically thicker molecular transitions (e.g., HCO⁺, HNC, N₂H⁺, and HCN) show a relatively broader II distribution compared to the optically thinner molecular transitions (e.g., H¹³CO⁺, HN¹³C, and ¹³CS). Since an optically thick transition will trace gas temperature, which will span a broad range, a broad distribution in their integrated intensities would be expected. Moreover, since the rarer isotopologues will be optically thin and, thus, sensitive to column density only, we would expect a narrower range in the distribution in their integrated intensities. The higher excitation lines (i.e., HNCO, CH₃CN, HC₃N, C₂H, and SiO) all show a very broad distribution in their integrated intensities. This likely reflects the very different conditions (e.g., shocks, high excitation temperatures) of the gas within which these molecular lines are excited.

The line widths are in general narrowest for the isotopologues (e.g., H¹³CO⁺, HN¹³C, ¹³CS), compared to the optically thicker transitions (e.g., HCO⁺, HNC, and HCN). Since the optically thick transitions will be tracing material on larger scales compared with the optically thinner transitions, this trend would be expected. Moreover, opacity broadening would also preferentially broaden the line-widths of the higher opacity transitions. The largest linewidths are found for the highest excitation energy transitions, which tend to be excited in regions of active star formation (e.g., CH₃CN, HNCO, and SiO). In particular, SiO has broad line-widths since the molecule is associated with shocks. The broad line widths of HNCO and CH₃CN suggests that these molecular transitions are also shock-tracers. The broadest line-widths, i.e. > 10 km s⁻¹, arise from the subset of clumps located within the Galaxy’s CMZ where high levels of turbulence and shocks dominate.

Finally, the small difference between the derived velocity and the V _C within individual clumps reveals that the molecular emission is generally well centred at the V _C. This implies that the emission from the various molecules arise from the same physical regions. The one exception is CH₃CN, for which the distribution is centred at a velocity about − 4 km s⁻¹ from the derived V _C.Footnote ⁴ The broadest distribution in the derived velocities relative to the V _C also occurs for the transitions with the highest line-widths: CH₃CN, HNCO, and SiO. This may indicate distinctly different velocities of the shocked gas.

7.4. Trends as a function of evolution

We use the IR-based categories to broadly represent three stages in the evolution of a clump with increasing levels of star formation; quiescent clumps represent an early phase before star formation has begun, protostellar clumps show the initial signatures of active star formation, while $\mathrm{H\,{\scriptstyle {II}}}$ regions represent a later stage when young, high-mass stars have already formed. Given the harsh environment and complexity of the chemistry within the Galaxy’s CMZ compared to the Galactic disk, we exclude from the plots and analysis in this section all clumps that fall within ± 10° in Galactic longitude of the Galactic centre.

Also overlaid on Figure 15 are the percentages of quiescent and protostellar clumps with > n detections (right axis; dashed and dot-dashed lines, respectively). For simplicity, we include on this plot only curves for the quiescent and protostellar clumps: the sample of $\mathrm{H\,{\scriptstyle {II}}}$ regions show a similar curve to the protostellar clumps. We find that clumps with active star formation have a higher percentage of the number of lines detected compared to the full survey and those clumps that are more quiescent. Moreover, the protostellar clumps and $\mathrm{H\,{\scriptstyle {II}}}$ regions are detected in four or more lines more frequently (~62 and ~58%, respectively) compared to the full survey (~53%) and the quiescent clumps (~38%). While it may reflect sensitivity biases with detections of both active star formation and line emission with increasing distance, this trend with evolution is expected since the gas is likely hotter and denser in the more evolved star-forming clumps and, thus, more readily detected in the 90 GHz lines. Indeed, a similar trend of increasing dust temperature in these clumps as a function of their evolutionary stage was confirmed in Guzmán et al. (Reference Guzmán, Sanhueza, Contreras, Smith, Jackson, Hoq and Rathborne2015).

Figure 19 shows the detection rates for most emission lines as a function of the IR-based category for each clump. The categories are shown on the x-axis increasing in evolutionary sequence from left to right: quiescent clumps, protostellar clumps, and $\mathrm{H\,{\scriptstyle {II}}}$ regions. Shown as the dotted line in each panel is the percentage of clumps detected within the survey for each of the classifications (19, 22, and 21%, respectively). The detection rates within each category for the four molecular transitions of HCO⁺, HNC, N₂H⁺, and HCN follows well the overall detection rates for the full survey (see the top four panels in Figure 19). In contrast, the isotopologues and the higher excitation lines (e.g., H¹³CO⁺, HN¹³C, HNCO, CH₃CN, HC₃N, and SiO) are typically detected less frequently towards ‘quiescent’ clumps and more frequently towards those that are actively star forming (i.e., the ‘protostellar’ clumps and $\mathrm{H\,{\scriptstyle {II}}}$ regions) compared to the overall survey.

Figure 19. Detection rates for most emission lines as a function of IR-based category (HNCO 4(1,3)–3(1,2) and ¹³C³⁴S were not plotted here since they had 0 and 9 detections within the survey, respectively) for clumps located outside of the CMZ (i.e., ± 10° of the Galactic centre). The dotted line in all panels shows the percentage of clumps detected from the survey as a whole within each of the classifications (19, 22, and 21%, respectively).

These trends are exactly what is expected if these categories reflect the evolution of the clumps: as the level of star-formation activity increases, the gas will become hotter and denser and, thus, the tracers of these conditions will be more readily detected. Indeed, this evolutionary sequence is reinforced by the clear trend in the detection rates for H 41α emission (see the lower panel of Figure 19). Since this emission traces ionised gas, presumably from an embedded high-mass star, it should only be observed when the central high-mass star has turned on, in the later $\mathrm{H\,{\scriptstyle {II}}}$ region phase.

To assess whether the ensemble of properties for the different molecular transitions varies with evolutionary stage, Figure 20 compares ratios of II (left column), ratios of line-widths (middle column), and the differences of the central velocity (right column) for various pairs of transitions as a function of the IR-derived categories for the clump. Since ratios are distance independent, they can be more reliable probes of the ensemble properties of the clumps (compared to detection statistics alone). We include in this plot a selection of pairs of transitions that both show clear trends, and for comparison, several that do not. The latter were included to demonstrate that the trends are related to particular molecules.

Figure 20. Trends as a function of IR-based category for clumps located outside of the CMZ (i.e., ± 10° of the Galactic centre). Left column: median in the distribution of the ratio of integrated intensities (the dotted lines mark the mean value of the plot range and are included to help identify trends). Middle column: median in the distribution of the ratio of derived linewidths (the dotted lines mark the mean value of the plot range and are included to help identify trends). Right column: median in the distribution of the velocity differences (the dotted lines mark the zero point, the plot ranges are symmetric about zero, and labels of ‘R’ and ‘B’ are included to indicate the direction of any red/blue asymmetries). In all plots, the error bars show the uncertainty in the median value as calculated by bootstrap resampling with replacement (e.g., Simpson & Mayer-Hasselwander Reference Simpson and Mayer-Hasselwander1986).

These plots reveal several interesting trends. First, the II ratios of HCO⁺/HNC and HCN/HNC increase with evolutionary stage (left column). These trends probably indicate the fact that HNC is relatively more abundant in colder, less evolved clumps than those that show active star formation (e.g., see Hoq et al. Reference Hoq2013). Second, the II ratios of HCO⁺/N₂H⁺, HNC/N₂H⁺, and C₂H/N₂H⁺ are typically higher in the $\mathrm{H\,{\scriptstyle {II}}}$ region phase, indicating that N₂H⁺ is relatively brighter in the colder earlier stages, and is consistent with the notion that N₂H⁺ resists freezing onto dust grains more effectively than other molecules and its chemical destruction in the warm ISM (Stephens et al. Reference Stephens, Jackson, Sanhueza, Whitaker, Hoq, Rathborne and Foster2015; Sanhueza et al. Reference Sanhueza, Jackson, Foster, Garay, Silva and Finn2012).

The HCO⁺/H¹³CO⁺ and HNC/HN¹³C II ratios also tend to increase with increasing evolutionary stage. We surmise that this trend may indicate either less self-absorption as the clumps evolve or that the optical depth decreases as the clumps evolve. The latter is consistent with both our measurements of τ derived from the N₂H⁺ emission (see Figure 21) and recent results, for example, Guzmán et al. (Reference Guzmán, Sanhueza, Contreras, Smith, Jackson, Hoq and Rathborne2015), which indicate lower clump column densities in the more evolved stages.

Figure 21. Histograms of the measured opacities for clumps located outside of the CMZ (i.e., ± 10° of the Galactic centre). In all panels, the solid histogram shows the distribution derived from the full survey, while the dotted histograms show the distributions for each of the IR-based categories. We find that the distribution of τ from the full survey has a median value of ~0.8. The differences in the overall distributions for the quiescent clumps and $\mathrm{H\,{\scriptstyle {II}}}$ regions indicates a trend of decreasing opacity with increasing evolutionary stage.

The ratios of line-widths show no obvious trends with evolution (middle column). However, differences in the derived velocities (right column) clearly show that the HCO⁺ emission is blueshifted with respect to the emission from the other molecular transitions (e.g., HNC, N₂H⁺, and SiO): the difference is largest at the earliest quiescent stage and monotonically decreases as the clumps evolve. Especially, striking is the trend in the HCO⁺ − H¹³CO⁺ velocities. This result suggests that the optically thickest HCO⁺ emission shows a ‘blue-red asymmetry’ that indicates overall collapse. This trend was noted from a subset of the MALT90 survey data (He et al. Reference He2015). The blue–red asymmetry of the HCO⁺ emission detected from the full survey will be discussed in a future paper (Jackson et al. in preparation).