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1. A low cosmic-ray ionisation rate in the prestellar core Ophiuchus/H-MM1. Mapping of the molecular ions ortho-H2D+, N2H+, and DCO+

Author

Harju, Jorma, Vastel, Charlotte, Sipilae, Olli, Redaelli, Elena, Caselli, Paola, Pineda, Jaime E., Belloche, Arnaud, and Wyrowski, Friedrich

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

(abridged) We have mapped the prestellar core H-MM1 in Ophiuchus in rotational lines of ortho-H2D+ (oH2D+), N2H+, and DCO+ at the wavelength 0.8 mm with the Large APEX sub-Millimeter Array (LAsMA) multibeam receiver of the Atacama Pathfinder EXperiment (APEX) telescope. We also ran a series of chemistry models to predict the abundance distributions of the observed molecules, and to estimate the effect of the cosmic-ray ionisation rate on their abundances. The three line maps show different distributions. The oH2D+ map is extended and outlines the general structure of the core, while N2H+ mainly shows the density maxima, and the DCO+ emission peaks are shifted towards one edge of the core where a region of enhanced desorption has been found previously. According to the chemical simulation, the fractional oH2D+ abundance remains relatively high in the centre of the core, and its column density correlates strongly with the cosmic-ray ionisation rate. Simulated line maps constrain the cosmic-ray ionisation rate per hydrogen molecule to be low, between 5e-18/s and 1e-17/s in the H-MM1 core. This estimate agrees with the gas temperature measured in the core. Modelling line emission of oH2D+ provides a straightforward method of determining the cosmic-ray ionisation rate in dense clouds, where the primary ion, H3+, is not observable., Comment: accepted for publication in Astronomy & Astrophysics

Published
2024
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2. Nuclear spin ratios of deuterated ammonia in prestellar cores. LAsMA observations of H-MM1 and Oph D

Author

Harju, Jorma, Pineda, Jaime E., Sipilä, Olli, Caselli, Paola, Belloche, Arnaud, Wyrowski, Friedrich, Riedel, Wiebke, Redaelli, Elena, and Vasyunin, Anton I.

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

We determine the ortho/para ratios of NH2D and NHD2 in two dense, starless cores, where their formation is supposed to be dominated by gas-phase reactions, which, in turn, is predicted to result in deviations from the statistical spin ratios. The Large APEX sub-Millimeter Array (LAsMA) multibeam receiver of the Atacama Pathfinder EXperiment (APEX) telescope was used to observe the prestellar cores H-MM1 and Oph D in Ophiuchus in the ground-state lines of ortho and para NH2D and NHD2. The fractional abundances of these molecules were derived employing 3D radiative transfer modelling, using different assumptions about the abundance profiles as functions of density. We also ran gas-grain chemistry models with different scenarios concerning proton or deuteron exchanges and chemical desorption from grains to find out if one of these models can reproduce the observed spin ratios. The observationally deduced ortho/para ratios of NH2D and NHD2 are in both cores within 10% of their statistical values 3 and 2, respectively, and taking 3-sigma limits, deviations from these of about 20% are allowed. Of the chemistry models tested here, the model that assumes proton hop (as opposed to full scrambling) in reactions contributing to ammonia formation, and a constant efficiency of chemical desorption, comes nearest to the observed abundances and spin ratios. The nuclear spin ratios derived here are in contrast with spin-state chemistry models that assume full scrambling in proton donation and hydrogen abstraction reactions leading to deuterated ammonia. The efficiency of chemical desorption influences strongly the predicted abundances of NH3, NH2D, and NHD2, but has a lesser effect on their ortho/para ratios. For these the proton exchange scenario in the gas is decisive. We suggest that this is because of rapid re-processing of ammonia and related cations by gas-phase ion-molecule reactions., Comment: accepted for publication in Astronomy & Astrophysics

Published
2023

3. Initial conditions of star formation at $\lesssim$2000 au: physical structure and NH$_{3}$ depletion of three early-stage cores

Author

Lin, Yuxin, Spezzano, Silvia, Pineda, Jaime E., Harju, Jorma, Schmiedeke, Anika, Jiao, Sihan, Liu, Hauyu Baobab, and Caselli, Paola

Subjects
Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics
Abstract

Pre-stellar cores represent a critical evolutionary phase in low-mass star formation. We aim to unveil the detailed thermal structure and density distribution of three early-stage cores, starless core L1517B, and prestellar core L694-2 and L429, with the high angular resolution observations of the NH$_{3}$ (1,1) and (2,2) inversion transitions obtained with VLA and GBT. In addition, we explore where/if NH$_{3}$ depletes in the central regions. Applying the mid-infrared extinction method to the $\textit{Spitzer}$ 8$~\mu$m map we obtain a high angular resolution hydrogen column density map, and derive the gas density profile to assess the variation of NH$_{3}$ abundance as a function of gas volume density. The measured temperature profiles of L429 and L1517B show a minor decrease towards the core center, dropping from $\sim$9\~K to below 8\~K, and $\sim$11 K to 10 K, while L694-2 has a rather uniform temperature distribution around $\sim$9 K. Among the three cores, L429 has the highest central gas density, close to sonic velocity line-width, and largest localised velocity gradient, all indicative of an advanced evolutionary stage. We resolve that the abundance of NH$_{3}$ becomes two times lower in the central region of L429, occurring around a gas density of 4.4$\times$10$^{4}$$~cm^{-3}$. Compared to Ophiuchus/H-MM1 which shows an even stronger drop of the NH$_{3}$ abundance at 2$\times$10$^{5}$$~cm^{-3}$, the abundance variations of the three cores plus Ophiuchus/H-MM1 suggest a progressive NH$_{3}$ depletion with increasing central density of the core., Comment: 23 pages, 23 figures incl. appendix; A&A accepted

Published
2023

4. An Interferometric View of H-MM1. I. Direct Observation of NH3 Depletion

Author

Pineda, Jaime E., Harju, Jorma, Caselli, Paola, Sipilä, Olli, Juvela, Mika, Vastel, Charlotte, Rosolowsky, Erik, Burkert, Andreas, Friesen, Rachel K., Shirley, Yancy, Maureira, María José, Choudhury, Spandan, Segura-Cox, Dominique M., Güsten, Rolf, Punanova, Anna, Bizzocchi, Luca, and Goodman, Alyssa A.

Subjects
Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics
Abstract

Spectral lines of ammonia, NH$_3$, are useful probes of the physical conditions in dense molecular cloud cores. In addition to advantages in spectroscopy, ammonia has also been suggested to be resistant to freezing onto grain surfaces, which should make it a superior tool for studying the interior parts of cold, dense cores. Here we present high-resolution NH$_3$ observations with the Very Large Array (VLA) and Green Bank Telescope (GBT) towards a prestellar core. These observations show an outer region with a fractional NH$_3$ abundance of X(NH$_3$) = (1.975$\pm$0.005)$\times 10^{-8}$ ($\pm 10\%$ systematic), but it also reveals that after all, the X(NH$_3$) starts to decrease above a H$_2$ column density of $\approx 2.6 \times 10^{22}$ cm$^{-2}$. We derive a density model for the core and find that the break-point in the fractional abundance occurs at the density n(H$_2$) $\sim 2\times10^5$ cm$^{-3}$, and beyond this point the fractional abundance decreases with increasing density, following the power law $n^{-1.1}$. This power-law behavior is well reproduced by chemical models where adsorption onto grains dominates the removal of ammonia and related species from the gas at high densities. We suggest that the break-point density changes from core to core depending on the temperature and the grain properties, but that the depletion power law is anyway likely to be close to $n^{-1}$ owing to the dominance of accretion in the central parts of starless cores., Comment: Accepted for publication in AJ. 18 Pages, 16 Figures, 3 Tables

Published
2022
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5. The Central 1000 au of a Pre-stellar Core Revealed with ALMA. II. Almost Complete Freeze-out

Author

Caselli, Paola, Pineda, Jaime E., Sipilä, Olli, Zhao, Bo, Redaelli, Elena, Spezzano, Silvia, Maureira, Maria José, Alves, Felipe, Bizzocchi, Luca, Bourke, Tyler L., Chacón-Tanarro, Ana, Friesen, Rachel, Galli, Daniele, Harju, Jorma, Jiménez-Serra, Izaskun, Keto, Eric, Li, Zhi-Yun, Padovani, Marco, Schmiedeke, Anika, Tafalla, Mario, and Vastel, Charlotte

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies
Abstract

Pre-stellar cores represent the initial conditions in the process of star and planet formation. Their low temperatures ($<$10 K) allow the formation of thick icy dust mantles, which will be partially preserved in the future protoplanetary disks, ultimately affecting the chemical composition of planetary systems. Previous observations have shown that carbon- and oxygen-bearing species, in particular CO, are heavily depleted in pre-stellar cores due to the efficient molecular freeze-out onto the surface of cold dust grains. However, N-bearing species such as NH$_3$ and, in particular, its deuterated isotopologues, appear to maintain high abundances where CO molecules are mainly in solid phase. Thanks to ALMA, we present here the first clear observational evidence of NH$_2$D freeze-out toward the L1544 pre-stellar core, suggestive of the presence of a"complete-depletion zone" within a $\simeq$1800 au radius, in agreement with astrochemical pre-stellar core model predictions. Our state-of-the-art chemical model coupled with a non-LTE radiative transfer code demonstrates that NH$_2$D becomes mainly incorporated in icy mantles in the central 2000 au and starts freezing-out already at $\simeq$7000 au. Radiative transfer effects within the pre-stellar core cause the NH$_2$D(1$_{11}$-1$_{01}$) emission to appear centrally concentrated, with a flattened distribution within the central $\simeq$3000 au, unlike the 1.3 mm dust continuum emission which shows a clear peak within the central $\simeq$1800 au. This prevented NH$_2$D freeze-out to be detected in previous observations, where the central 1000 au cannot be spatially resolved., Comment: accepted for publication in The Astrophysical Journal

Published
2022
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6. Chemical exploration of Galactic cold cores

Author

Zhou, Chenlin, Vastel, Charlotte, Montillaud, Julien, Ceccarelli, Cecilia, Demyk, Karine, Harju, Jorma, Juvela, Mika, Ristorcelli, Isabelle, and Liu, Tie

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

A solar-type system starts from an initial molecular core that acquires organic complexity as it evolves. The so-called prestellar cores that can be studied are rare, which has hampered our understanding of how organic chemistry sets in and grows. Aims. We selected the best prestellar core targets from the cold core catalogue that represent a diversity in terms of their environment to explore their chemical complexity: 1390 (in the compressed shell of Lambda Ori), 869 (in the MBM12 cloud), and 4149 (in the California nebula). We obtained a spectral survey with the IRAM 30 m telescope in order to explore the molecular complexity of the cores. We carried out a radiative transfer analysis of the detected transitions in order to place some constraints on the physical conditions of the cores and on the molecular column densities. We also used the molecular ions in the survey to estimate the cosmic-ray ionisation rate and the S/H initial elemental abundance using a gas-phase chemical model to reproduce their abundances. We found large differences in the molecular complexity (deuteration, complex organic molecules, sulphur, carbon chains, and ions) and compared their chemical properties with a cold core and two prestellar cores. The chemical diversity we found in the three cores seems to be correlated with their chemical evolution: two of them are prestellar (1390 and 4149), and one is in an earlier stage (869). The influence of the environment is likely limited because cold cores are strongly shielded from their surroundings. The high extinction prevents interstellar UV radiation from penetrating deeply into the cores. Higher spatial resolution observations of the cores are therefore needed to constrain the physical structure of the cores, as well as a larger-scale distribution of molecular ions to understand the influence of the environment on their molecular complexity., Comment: 26 pages, 13 figures, accepted in A&A in January 2022

Published
2022
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7. Methanol Mapping in Cold Cores: Testing Model Predictions

Author

Punanova, Anna, Vasyunin, Anton, Caselli, Paola, Howard, Alexander, Spezzano, Silvia, Shirley, Yancy, Scibelli, Samantha, and Harju, Jorma

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

Chemical models predict that in cold cores gas-phase methanol is expected to be abundant at the outer edge of the CO depletion zone, where CO is actively adsorbed. CO adsorption correlates with volume density in cold cores, and, in nearby molecular clouds, the catastrophic CO freeze-out happens at volume densities above 10$^4$ cm$^{-3}$. The methanol production rate is maximized there and its freeze-out rate does not overcome its production rate, while the molecules are shielded from UV destruction by gas and dust. Thus, in cold cores, methanol abundance should generally correlate with visual extinction that depends both on volume and column density. In this work, we test the most basic model prediction that maximum methanol abundance is associated with a local $A_V\simeq$4 mag in dense cores and constrain the model parameters with the observational data. With the IRAM 30 m antenna, we mapped the CH$_3$OH (2-1) and (3-2) transitions toward seven dense cores in the L1495 filament in Taurus to measure the methanol abundance. We use the Herschel/SPIRE maps to estimate visual extinction, and the C$^{18}$O(2-1) maps from Tafalla & Hacar (2015) to estimate CO depletion. We explored the observed and modeled correlations between the methanol abundances, CO depletion, and visual extinction varying the key model parameters. The modeling results show that hydrogen surface diffusion via tunneling is crucial to reproduce the observed methanol abundances, and the needed reactive desorption efficiency matches the one deduced from laboratory experiments., Comment: Accepted for publication in ApJ

Published
2021
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8. Search for H$_3^+$ isotopologues toward CRL 2136 IRS 1

Author

Goto, Miwa, Geballe, T. R., Harju, Jorma, Caselli, Paola, Sipilä, Olli, Menten, Karl M., and Usuda, Tomonori

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Astrophysics of Galaxies
Abstract

Deuterated interstellar molecules frequently have abundances relative to their main isotopologues much higher than the overall elemental D-to-H ratio in the cold dense interstellar medium. The H$_3^+$ and its isotopologues play a key role in the deuterium fractionation; however, the abundances of these isotopologues have not been measured empirically with respect to H$_3^+$ to date. Our aim was to constrain the relative abundances of H$_2$D$^+$ and D$_3^+$ in the cold outer envelope of the hot core CRL 2136 IRS 1. We carried out three observations targeting H$_3^+$ and its isotopologues using the spectrographs CRIRES at the VLT, iSHELL at IRTF, and EXES on board SOFIA. In addition, the CO overtone band at 2.3 $\mu$m was observed by iSHELL to characterize the gas on the line of sight. The H$_3^+$ ion was detected toward CRL 2136 IRS 1 as in previous observations. Spectroscopy of lines of H$_2$D$^+$ and D$_3^+$ resulted in non-detections. The 3$\sigma$ upper limits of $N({\rm H_2D^+})/N({\rm H_3^+})$ and $N({\rm D_3^+})/N({\rm H_3^+})$ are 0.24 and 0.13, respectively. The population diagram for CO is reproduced by two components of warm gas with the temperatures 58 K and 530 K, assuming a local thermodynamic equilibrium (LTE) distribution of the rotational levels. Cold gas ($<$20 K) makes only a minor contribution to the CO molecular column toward CRL 2136 IRS 1. The critical conditions for deuterium fractionation in a dense cloud are low temperature and CO depletion. Given the revised cloud properties, it is no surprise that H$_3^+$ isotopologues are not detected toward CRL 2136 IRS 1. The result is consistent with our current understanding of how deuterium fractionation proceeds., Comment: 9 pages, 3 tables, 8 figures, accepted for publication at A&A

Published
2019
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9. Cloud G074.11+00.11: a stellar cluster in formation

Author

Saajasto, Mika, Harju, Jorma, Juvela, Mika, Tie, Liu, Zhang, Qizhou, Liu, Sheng-Yuan, Hirano, Naomi, Wu, Yuefang, Kim, Kee-Tae, Tatematsu, Ken'ichi, Wang, Ke, and Thompson, Mark

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

We present molecular line and dust continuum observations of a Planck-detected cold cloud, G074.11+00.11. The cloud consists of a system of curved filaments and a central star-forming clump. The clump is associated with several infrared sources and H2O maser emission. We aim to determine the mass distribution and gas dynamics within the clump, to investigate if the filamentary structure seen around the clump repeats itself on a smaller scale, and to estimate the fractions of mass contained in dense cores and filaments. The velocity distribution of pristine dense gas can be used to investigate the global dynamical state of the clump, the role of filamentary inflows, filament fragmentation and core accretion. We use molecular line and continuum observations from single dish observatories and interferometric facilities to study the kinematics of the region. The molecular line observations show that the central clump may have formed as a result of a large-scale filament collision. The central clump contains three compact cores. Assuming a distance of 2.3 kpc, based on Gaia observations and a three-dimensional extinction method of background stars, the mass of the central clump exceeds 700 solar masses, which is roughly 25% of the total mass of the cloud. Our virial analysis suggests that the central clump and all identified substructures are collapsing. We find no evidence for small-scale filaments associated with the cores. Our observations indicate that the clump is fragmented into three cores with masses in the range [10,50] solar masses and that all three are collapsing. The presence of an H2O maser emission suggests active star formation. However, the CO lines show only weak signs of outflows. We suggest that the region is young and any processes leading to star formation have just recently begun., Comment: 17 pages, 19 figures, 3 tables

Published
2019
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10. Deuterated forms of H${_3^+}$ and their importance in astrochemistry

Author

Caselli, Paola, Sipilä, Olli, and Harju, Jorma

Subjects
Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics
Abstract

At the low temperatures ($\sim$10 K) and high densities ($\sim$100,000 H$_2$ molecules per cc) of molecular cloud cores and protostellar envelopes, a large amount of molecular species (in particular those containing C and O) freeze-out onto dust grain surfaces. It is in these regions that the deuteration of H$_3^+$ becomes very efficient, with a sharp abundance increase of H$_2$D$^+$ and D$_2$H$^+$. The multi-deuterated forms of H$_3^+$ participate in an active chemistry: (i) their collision with neutral species produces deuterated molecules such as the commonly observed N$_2$D$^+$, DCO$^+$ and multi-deuterated NH$_3$; (ii) their dissociative electronic recombination increases the D/H atomic ratio by several orders of magnitude above the D cosmic abundance, thus allowing deuteration of molecules (e.g. CH$_3$OH and H$_2$O) on the surface of dust grains. Deuterated molecules are the main diagnostic tools of dense and cold interstellar clouds, where the first steps toward star and protoplanetary disk formation take place. Recent observations of deuterated molecules are reviewed and discussed in view of astrochemical models inclusive of spin-state chemistry. We present a new comparison between models based on complete scrambling (to calculate branching ratio tables for reactions between chemical species that include protons and/or deuterons) and models based on non-scrambling (proton hop) methods, showing that the latter best agree with observations of NH$_3$ deuterated isotopologues and their different nuclear spin symmetry states., Comment: accepted for publication in the Philosophical Transactions A of the Royal Society

Published
2019

11. Efficient methanol production on the dark side of a prestellar core

Author

Harju, Jorma, Pineda, Jaime E., Vasyunin, Anton I., Caselli, Paola, Offner, Stella S. R., Goodman, Alyssa A., Juvela, Mika, Sipilae, Olli, Faure, Alexandre, Gal, Romane Le, Hily-Blant, Pierre, Alves, Joao, Bizzocchi, Luca, Burkert, Andreas, Chen, Hope, Friesen, Rachel K., Guesten, Rolf, Myers, Philip C., Punanova, Anna, Rist, Claire, Rosolowsky, Erik, Schlemmer, Stephan, Shirley, Yancy, Spezzano, Silvia, Vastel, Charlotte, and Wiesenfield, Laurent

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

We present ALMA maps of the starless molecular cloud core Ophiuchus/H-MM1 in the lines of deuterated ammonia (ortho-NH2D), methanol (CH3OH), and sulphur monoxide (SO). The dense core is seen in NH2D emission, whereas the CH3OH and SO distributions form a halo surrounding the core. Because methanol is formed on grain surfaces, its emission highlights regions where desorption from grains is particularly efficient. Methanol and sulphur monoxide are most abundant in a narrow zone that follows the eastern side of the core. This side is sheltered from the stronger external radiation field coming from the west. We show that photodissociation on the illuminated side can give rise to an asymmetric methanol distribution, but that the stark contrast observed in H-MM1 is hard to explain without assuming enhanced desorption on the shaded side. The region of the brightest emission has a wavy structure that rolls up at one end. This is the signature of Kelvin-Helmholtz instability occurring in sheared flows. We suggest that in this zone, methanol and sulphur are released as a result of grain-grain collisions induced by shear vorticity., Comment: Accepted for publication in the Astrophysical Journal

Published
2019
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12. Magnetic Field Structure of Dense Cores using Spectroscopic Methods

Author

Auddy, Sayantan, Myers, Philip C., Basu, Shantanu, Harju, Jorma, Pineda, Jaime E., and Friesen, Rachel K.

Subjects
Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics
Abstract

We develop a new ''core field structure'' (CFS) model to predict the magnetic field strength and magnetic field fluctuation profile of dense cores using gas kinematics. We use spatially resolved observations of the nonthermal velocity dispersion from the Green Bank Ammonia survey along with column density maps from SCUBA-2 to estimate the magnetic field strength across seven dense cores located in the L1688 region of Ophiuchus. The CFS model predicts the profile of the relative field fluctuation, which is related to the observable dispersion in direction of the polarization vectors. Within the context of our model we find that all the cores have a transcritical mass-to-flux ratio., Comment: 18 pages, 13 figures, to appear in ApJ

Published
2019
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13. $^{14}$N/$^{15}$N ratio measurements in prestellar cores with N$_2$H$^+$: new evidence of $^{15}$N-antifractionation

Author

Redaelli, Elena, Bizzocchi, Luca, Caselli, Paola, Harju, Jorma, Chacón-Tanarro, Ana, Dore, Luca, and Leonardo, Elvira

Subjects
Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics
Abstract

Context: The $^{15}$N fractionation has been observed to show large variations among astrophysical sources, depending both on the type of target and on the molecular tracer used. These variations cannot be reproduced by the current chemical models. Aims: Until now, the $^{14}$N/$^{15}$N ratio in N$_2$H$^+$ has been accurately measured in only one prestellar source, L1544, where strong levels of fractionation, with depletion in $^{15}$N, are found ($^{14}$N/$^{15}$N$\: \approx 1000$). In this paper we extend the sample to three more bona fide prestellar cores, in order to understand if the antifractionation in N$_2$H$^+$ is a common feature of this kind of sources. Methods: We observed N$_2$H$^+$,N$^{15}$NH$^+$ and $^{15}$NNH$^+$ in L183, L429 and L694-2 with the IRAM 30m telescope. We modeled the emission with a non-local radiative transfer code in order to obtain accurate estimates of the molecular column densities, including the one for the optically thick N$_2$H$^+$. We used the most recent collisional rate coefficients available, and with these we also re-analysed the L1544 spectra previously published. Results: The obtained isotopic ratios are in the range $630-770$ and significantly differ with the value, predicted by the most recent chemical models, of $\approx 440$, close to the protosolar value. Our prestellar core sample shows high level of depletion of $^{15}$N in diazenylium, as previously found in L1544. A revision of the N chemical networks is needed in order to explain these results., Comment: Accepted for publication in A&A

Published
2018
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14. Radio interferometric observation of an asteroid occultation

Author

Harju, Jorma, Lehtinen, Kimmo, Romney, Jonathan, Petrov, Leonid, Granvik, Mikael, Muinonen, Karri, Bach, Uwe, and Poutanen, Markku

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The occultation of the radio galaxy 0141+268 by the asteroid (372) Palma on 2017 May 15 was observed using six antennas of the Very Long Baseline Array (VLBA). The shadow of Palma crossed the VLBA station at Brewster, Washington. Owing to the wavelength used, and the size and the distance of the asteroid, a diffraction pattern in the Fraunhofer regime was observed. The measurement retrieves both the amplitude and the phase of the diffracted electromagnetic wave. This is the first astronomical measurement of the phase shift caused by diffraction. The maximum phase shift is sensitive to the effective diameter of the asteroid. The bright spot at the shadow's center, the so called Arago--Poisson spot, is clearly detected in the amplitude time-series, and its strength is a good indicator of the closest angular distance between the center of the asteroid and the radio source. A sample of random shapes constructed using a Markov chain Monte Carlo algorithm suggests that the silhouette of Palma deviates from a perfect circle by 26+-13%. The best-fitting random shapes resemble each other, and we suggest their average approximates the shape of the silhouette at the time of the occultation. The effective diameter obtained for Palma, 192.1+-4.8 km, is in excellent agreement with recent estimates from thermal modeling of mid-infrared photometry. Finally, our computations show that because of the high positional accuracy, a single radio interferometric occultation measurement can reduce the long-term ephemeris uncertainty by an order of magnitude., Comment: 13 pages, 10 figures, to appear in the Astronomical Journal

Published
2018
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15. Detection of interstellar ortho-D2H+ with SOFIA

Author

Harju, Jorma, Sipilä, Olli, Brünken, Sandra, Schlemmer, Stephan, Caselli, Paola, Juvela, Mika, Menten, Karl M., Stutzki, Jürgen, Asvany, Oskar, Kaminski, Tomasz, Okada, Yoko, and Higgins, Ronan

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

We report on the detection of the ground-state rotational line of ortho-D2H+ at 1.477 THz (203 micron) using the German REceiver for Astronomy at Terahertz frequencies (GREAT) onboard the Stratospheric Observatory For Infrared Astronomy (SOFIA). The line is seen in absorption against far-infrared continuum from the protostellar binary IRAS 16293-2422 in Ophiuchus. The para-D2H+ line at 691.7 GHz was not detected with the APEX telescope toward this position. These D2H+ observations complement our previous detections of para-H2D+ and ortho-H2D+ using SOFIA and APEX. By modeling chemistry and radiative transfer in the dense core surrounding the protostars, we find that the ortho-D2H+ and para-H2D+ absorption features mainly originate in the cool (T<18 K) outer envelope of the core. In contrast, the ortho-H2D+ emission from the core is significantly absorbed by the ambient molecular cloud. Analyses of the combined D2H+ and H2D+ data result in an age estimate of ~500 000 yr for the core, with an uncertainty of ~200 000 yr. The core material has probably been pre-processed for another 500 000 years in conditions corresponding to those in the ambient molecular cloud. The inferred time scale is more than ten times the age of the embedded protobinary. The D2H+ and H2D+ ions have large and nearly equal total (ortho+para) fractional abundances of ~$10^{-9}$ in the outer envelope. This confirms the central role of H3+ in the deuterium chemistry in cool, dense gas, and adds support to the prediction of chemistry models that also D3+ should be abundant in these conditions., Comment: 19 pages, 12 figures, accepted for publication in The Astrophysical Journal

Published
2017
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16. Chemical differentiation in a prestellar core traces non-uniform illumination

Author

Spezzano, Silvia, Bizzocchi, Luca, Caselli, Paola, Harju, Jorma, and Brünken, Sandra

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

Dense cloud cores present chemical differentiation due to the different distribution of C-bearing and N-bearing molecules, the latter being less affected by freeze-out onto dust grains. In this letter we show that two C-bearing molecules, CH$_3$OH and $c$-C$_3$H$_2$, present a strikingly different (complementary) morphology while showing the same kinematics toward the prestellar core L1544. After comparing their distribution with large scale H$_2$ column density N(H$_2$) map from the Herschel satellite, we find that these two molecules trace different environmental conditions in the surrounding of L1544: the $c$-C$_3$H$_2$ distribution peaks close to the southern part of the core, where the surrounding molecular cloud has a N(H$_2$) sharp edge, while CH$_3$OH mainly traces the northern part of the core, where N(H$_2$) presents a shallower tail. We conclude that this is evidence of chemical differentiation driven by different amount of illumination from the interstellar radiation field: in the South, photochemistry maintains more C atoms in the gas phase allowing carbon chain (such as $c$-C$_3$H$_2$) production; in the North, C is mainly locked in CO and methanol traces the zone where CO starts to freeze out significantly. During the process of cloud contraction, different gas and ice compositions are thus expected to mix toward the central regions of the core, where a potential Solar-type system will form. An alternative view on carbon-chain chemistry in star-forming regions is also provided., Comment: Accepted for publication in A&A Letters

Published
2016
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17. Deuteration of ammonia in the starless core Ophiuchus/H-MM1

Author

Harju, Jorma, Daniel, Fabien, Sipilä, Olli, Caselli, Paola, Pineda, Jaime E., Friesen, Rachel K., Punanova, Anna, Güsten, Rolf, Wiesenfeld, Laurent, Myers, Philip C., Faure, Alexandre, Hily-Blant, Pierre, Rist, Claire, Rosolowsky, Erik, Schlemmer, Stephan, and Shirley, Yancy L.

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

Ammonia and its deuterated isotopologues probe physical conditions in dense molecular cloud cores. With the aim of testing the current understanding of the spin-state chemistry of these molecules, we observed spectral lines of NH3, NH2D, NHD2, ND3, and N2D+ towards a dense, starless core in Ophiuchus with the APEX, GBT, and IRAM 30-m telescopes. The observations were interpreted using a gas-grain chemistry model combined with radiative transfer calculations. The chemistry model distinguishes between the different nuclear spin states of light hydrogen molecules, ammonia, and their deuterated forms. High deuterium fractionation ratios with NH2D/NH3=0.4, NHD2/NH2D=0.2, and ND3/NHD2=0.06 were found in the core. The observed ortho/para ratios of NH2D and NHD2 are close to the corresponding nuclear spin statistical weights. The chemistry model can approximately reproduce the observed abundances, but predicts uniformly too low ortho/para-NH2D, and too large ortho/para-NHD2 ratios. The longevity of N2H+ and NH3 in dense gas, which is prerequisite to their strong deuteration, can be attributed to the chemical inertia of N2 on grain surfaces. The discrepancies between the chemistry model and the observations are likely to be caused by the fact that the model assumes complete scrambling in principal gas-phase deuteration reactions of ammonia, which means that all the nuclei are mixed in reactive collisions. If, instead, these reactions occur through proton hop/hydrogen abstraction processes, statistical spin ratios are to be expected. The present results suggest that while the deuteration of ammonia changes with physical conditions and time, the nuclear spin ratios of ammonia isotopologues do not probe the evolutionary stage of a cloud., Comment: to appear in Astronomy & Astrophysics

Published
2016
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18. Determination of the far-infrared dust opacity in a prestellar core

Author

Suutarinen, Aleksi, Haikala, Lauri K., Harju, Jorma, Juvela, Mika, Andre, Philippe, Kirk, Jason M., Könyves, Vera, and White, Glenn J.

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

(abridged) We correlated near-infrared stellar H-Ks colour excesses of background stars from NTT/SOFI with the far-IR optical depth map, tauFIR, derived from Herschel 160, 250, 350, and 500 um data. The Herschel maps were also used to construct a model for the cloud to examine the effect of temperature gradients on the estimated optical depths and dust absorption cross-sections. A linear correlation is seen between the colour H-Ks and tauFIR up to high extinctions (AV ~ 25). The correlation translates to the average extinction ratio A250um/AJ = 0.0014 +/- 0.0002, assuming a standard near-infrared extinction law and a dust emissivity index beta=2. Using an empirical NH/AJ ratio we obtain an average absorption cross-section per H nucleus of sigmaH(250um) = (1.8 +/- 0.3) * 10^(-25) cm^2 / H-atom, corresponding to a cross-section per unit mass of gas kappaG(250 um) = 0.08 +/- 0.01 cm^2 / g. The cloud model however suggests that owing to the bias caused by temperature changes along the line-of-sight these values underestimate the true cross-sections by up to 40% near the centre of the core. Assuming that the model describes the effect of the temperature variation on tauFIR correctly, we find that the relationship between H-Ks and tauFIR agrees with the recently determined relationship between sigmaH and NH in Orion A. The derived far-IR cross-section agrees with previous determinations in molecular clouds with moderate column densities, and is not particularly large compared with some other cold cores. We suggest that this is connected to the core not beng very dense (the central density is likely to be ~10^5 cm^-3) and judging from previous molecular line data, it appears to be at an early stage of chemical evolution., Comment: 10 pages, 10 figures

Published
2013
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19. A (sub)millimetre study of dense cores in Orion B9

Author

Miettinen, Oskari, Harju, Jorma, Haikala, Lauri K., and Juvela, Mika

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

We aim to further constrain the properties and evolutionary stages of dense cores in Orion B9. The central part of Orion B9 was mapped at 350 micron with APEX/SABOCA. A sample of nine cores in the region were observed in C17O(2-1), H13CO+(4-3) (towards 3 sources), DCO+(4-3), N2H+(3-2), and N2D+(3-2) with APEX/SHFI. These data are used in conjunction with our previous APEX/LABOCA 870-micron dust continuum data. Many of the LABOCA cores show evidence of substructure in the higher-resolution SABOCA image. In particular, we report on the discovery of multiple very low-mass condensations in the prestellar core SMM 6. Based on the 350-to-870 micron flux density ratios, we determine dust temperatures of ~7.9-10.8 K, and dust emissivity indices of ~0.5-1.8. The CO depletion factors are in the range ~1.6-10.8. The degree of deuteration in N2H+ is ~0.04-0.99, where the highest value (seen towards the prestellar core SMM 1) is, to our knowledge, the most extreme level of N2H+ deuteration reported so far. The level of HCO+ deuteration is about 1-2%. We also detected D2CO towards two sources. The detection of subcondensations within SMM 6 shows that core fragmentation can already take place during the prestellar phase. The origin of this substructure is likely caused by thermal Jeans fragmentation of the elongated parent core. A low depletion factor and the presence of gas-phase D2CO in SMM 1 suggest that the core chemistry is affected by the nearby outflow. The very high N2H+ deuteration in SMM 1 is likely to be remnant of the earlier CO-depleted phase., Comment: 20 pages, 10 figures, 10 tables. Accepted for publication in Astronomy and Astrophysics

Published
2011
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20. Mapping the prestellar core Ophiuchus D (L1696A) in ammonia

Author

Ruoskanen, Jukka, Harju, Jorma, Juvela, Mika, Miettinen, Oskari, Liljeström, Anne, Väisälä, Miikka, Lunttila, Tuomas, and Kontinen, Samu

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

The gas kinetic temperature in the centres of starless, high-density cores is predicted to fall as low as 5-6 K. The aim of this study was to determine the kinetic temperature distribution in the low-mass prestellar core Oph D where previous observations suggest a very low central temperature. The densest part of the Oph D core was mapped in the NH3(1,1) and (2,2) inversion lines using the Very Large Array (VLA). The physical quantities were derived from the observed spectra by fitting the hyperfine structure of the lines, and subsequently the temperature distribution of Oph D was calculated using the standard rotational temperature techniques. A physical model of the cores was constructed, and the simulated spectra after radiative transfer calculations with a 3D Monte Carlo code were compared with the observed spectra. Temperature, density, and ammonia abundance of the core model were tuned until a satisfactory match with the observation was obtained. The high resolution of the interferometric data reveals that the southern part of Oph D comprises of two small cores. The gas kinetic temperatures, as derived from ammonia towards the centres of the southern and northern core are 7.4 and 8.9 K, respectively. The observed masses of the cores are only 0.2 M_Sun. Their potential collapse could lead to formation of brown dwarfs or low-mass stars., Comment: Accepted for publication in A&A; 10 pages, 9 figures

Published
2011
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21. CH abundance gradient in TMC-1

Author

Suutarinen, Aleksi, Geppert, Wolf Dietrich, Harju, Jorma, Heikkilä, Arto, Hotzel, Stephan, Juvela, Mika, Millar, Tom J., Walsh, Catherine, and Wouterloot, Jan Gerard Amos

Subjects
Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Astrophysics of Galaxies
Abstract

We observed the 9-cm Lambda-doubling lines of CH along the dense filament of TMC-1. The CH column densities were compared with the total H2 column densities derived using the 2MASS NIR data and previously published SCUBA maps and with OH column densities derived using previous observations with Effelsberg. We also modelled the chemical evolution of TMC-1 adopting physical conditions typical of dark clouds using the UMIST Database for Astrochemistry gas-phase reaction network to aid the interpretation of the observed OH/CH abundance ratios. The CH column density has a clear peak in the vicinity of the cyanopolyyne maximum of TMC-1. The fractional CH abundance relative to H2 increases steadily from the northwestern end of the filament where it lies around 1.0e-8, to the southeast where it reaches a value of 2.0e-8. The OH and CH column densities are well correlated, and we obtained OH/CH abundance ratios of ~ 16 - 20. These values are clearly larger than what has been measured recently in diffuse interstellar gas and is likely to be related to C to CO conversion at higher densities. The good correlation between CH and OH can be explained by similar production and destruction pathways. We suggest that the observed CH and OH abundance gradients are mainly due to enhanced abundances in a low-density envelope which becomes more prominent in the southeastern part and seems to continue beyond the dense filament. An extensive envelope probably signifies an early stage of dynamical evolution, and conforms with the detection of a large CH abundance in the southeastern part of the cloud. The implied presence of other simple forms of carbon in the gas phase provides a natural explanation for the observation of "early-type" molecules in this region., Comment: 12 pages, 16 figures

Published
2011
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22. Physical properties of dense cores in Orion B9

Author

Miettinen, Oskari, Harju, Jorma, Haikala, Lauri K., and Juvela, Mika

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

We aim to determine the physical and chemical properties of dense cores in Orion B9. We observed the NH3(1,1) and (2,2), and the N2H+(3-2) lines towards the submm peak positions. These data are used in conjunction with our LABOCA 870 micron dust continuum data. The gas kinetic temperature in the cores is between ~9.4-13.9 K. The non-thermal velocity dispersion is subsonic in most of the cores. The non-thermal linewidth in protostellar cores appears to increase with increasing bolometric luminosity. The core masses are very likely drawn from the same parent distribution as the core masses in Orion B North. Starless cores in the region are likely to be gravitationally bound, and thus prestellar. Some of the cores have a lower radial velocity than the systemic velocity of the region, suggesting that they are members of the "low-velocity part" of Orion B. The observed core-separation distances deviate from the corresponding random-like model distributions. The distances between the nearest-neighbours are comparable to the thermal Jeans length. The fractional abundances of NH3 and N2H+ in the cores are ~1.5-9.8x10^{-8} and ~0.2-5.9x10^{-10}, respectively. The NH3 abundance appears to decrease with increasing H2 column and number densities. The NH3/N2H+ column density ratio is larger in starless cores than in cores with embedded protostars. The core population in Orion B9 is comparable in physical properties to those in nearby low-mass star-forming regions. It is unclear if the origin of cores could be explained by turbulent fragmentation. On the other hand, many of the core properties conform with the picture of dynamic core evolution. The Orion B9 region has probably been influenced by the feedback from the nearby Ori OB 1b group, and the fragmentation of the parental cloud into cores could be caused by gravitational instability., Comment: 17 pages, 11 figures, 7 tables. Accepted for publication in Astronomy and Astrophysics. Version 2: minor language corrections added

Published
2010
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23. LABOCA mapping of the infrared dark cloud MSXDC G304.74+01.32

Author

Miettinen, Oskari and Harju, Jorma

Subjects
Astrophysics - Astrophysics of Galaxies
Abstract

Infrared dark clouds (IRDCs) likely represent very early stages of high-mass star/star cluster formation. In this study, we aim to determine the physical properties and spatial distribution of dense clumps in the IRDC MSXDC G304.74+01.32 (G304.74), and bring these characteristics into relation to theories concerning the origin of IRDCs and their fragmentation into clumps and star-forming cores. G304.74 was mapped in the 870 $\mu$m dust continuum with the LABOCA bolometer on APEX. Archival MSX and IRAS infrared data were used to study the nature and properties of the submillimetre clumps within the cloud. There are 8 clumps within G304.74 which are not associated with mid-infrared (MIR) emission. Some of them are candidates for being/harbouring high-mass starless cores (HMSCs). We compared the clump masses and their spatial distribution in G304.74 with those in several other recently studied IRDCs. There is a high likelihood that the clump mass distributions in G304.74 and in several other IRDCs represent the samples of the same parent distribution. In most cases the spatial distributions of clumps in IRDCs do not deviate significantly from random distributions. This is consistent with the idea that the origin of IRDCs, and their further sub-fragmentation down to scales of clumps is caused by supersonic turbulence in accordance with results from giant molecular clouds., Comment: 15 pages, 8 figures, accepted for publication in Astronomy and Astrophysics

Published
2010
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24. Toward a European Facility for Ground-Based Radar Observations of Near-Earth Objects

Author

Pupillo, Giuseppe, primary, Righini, Simona, additional, Orosei, Roberto, additional, Bortolotti, Claudio, additional, Maccaferri, Giuseppe, additional, Roma, Mauro, additional, Mastrogiuseppe, Marco, additional, Pisanu, Tonino, additional, Schirru, Luca, additional, Cicalò, Stefano, additional, Tripodo, Antonio, additional, Harju, Jorma, additional, Penttilä, Antti, additional, Virkki, Anne K., additional, Bach, Uwe, additional, Kraus, Alexander, additional, Margheri, Alessio, additional, Ghiani, Riccardo, additional, Iacolina, Maria N., additional, Valente, Giuseppe, additional, Koschny, Detlef, additional, Moissl, Richard, additional, and Sessler, Gunther, additional

Published
2023
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25. Toward a European Facility for Ground-Based Radar Observations of Near-Earth Objects.

Author

Pupillo, Giuseppe, Righini, Simona, Orosei, Roberto, Bortolotti, Claudio, Maccaferri, Giuseppe, Roma, Mauro, Mastrogiuseppe, Marco, Pisanu, Tonino, Schirru, Luca, Cicalò, Stefano, Tripodo, Antonio, Harju, Jorma, Penttilä, Antti, Virkki, Anne K., Bach, Uwe, Kraus, Alexander, Margheri, Alessio, Ghiani, Riccardo, Iacolina, Maria N., and Valente, Giuseppe

Subjects
NEAR-Earth objects, RADAR, BISTATIC radar, ASTROMETRY, RADIO telescopes, TRANSMITTING antennas
Abstract

In this work, we present the preliminary results of radar observations of Near-Earth Objects (NEOs) carried out by European radio telescopes in the framework of the European Space Agency (ESA) project "NEO observation concepts for radar systems", aimed at deriving the functional requirements of a planetary radar system, evaluating the available European assets to perform NEO radar observations, and carrying out test radar campaigns. In the first part of the project, we executed the performance analysis of a possible European planetary radar system. Instrumental features, as much as issues like the impact of weather conditions on signal propagation at different radio frequencies, were considered. This paper focused on the test campaigns, performed in the years 2021–2022 in collaboration with the Jet Propulsion Laboratory (JPL), which led to the observation of several asteroids including 2021 AF8, (4660) Nereus, and 2005 LW3, which allowed us to derive astrometric measurements, as well as to measure physical properties, such as rotation periods, and observe how one of the targets is actually a binary asteroid. The obtained results demonstrated that European radio astronomical dishes, although employed only as receivers (in bistatic or multistatic configurations) and for a limited amount of time, are able to provide a significant contribution to the constitution of a European network to increase the opportunities for NEO monitoring and studies, if a transmitting antenna—equipped with a suitable high-power transmitter—were made available. [ABSTRACT FROM AUTHOR]

Published
2024
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26. An Interferometric View of H-MM1. I. Direct Observation of NH3 Depletion

Author

Pineda, Jaime E., primary, Harju, Jorma, additional, Caselli, Paola, additional, Sipilä, Olli, additional, Juvela, Mika, additional, Vastel, Charlotte, additional, Rosolowsky, Erik, additional, Burkert, Andreas, additional, Friesen, Rachel K., additional, Shirley, Yancy, additional, Maureira, María José, additional, Choudhury, Spandan, additional, Segura-Cox, Dominique M., additional, Güsten, Rolf, additional, Punanova, Anna, additional, Bizzocchi, Luca, additional, and Goodman, Alyssa A., additional

Published
2022
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27. The Central 1000 au of a Prestellar Core Revealed with ALMA. II. Almost Complete Freeze-out

Author

Caselli, Paola, primary, Pineda, Jaime E., additional, Sipilä, Olli, additional, Zhao, Bo, additional, Redaelli, Elena, additional, Spezzano, Silvia, additional, Maureira, Maria José, additional, Alves, Felipe, additional, Bizzocchi, Luca, additional, Bourke, Tyler L., additional, Chacón-Tanarro, Ana, additional, Friesen, Rachel, additional, Galli, Daniele, additional, Harju, Jorma, additional, Jiménez-Serra, Izaskun, additional, Keto, Eric, additional, Li, Zhi-Yun, additional, Padovani, Marco, additional, Schmiedeke, Anika, additional, Tafalla, Mario, additional, and Vastel, Charlotte, additional

Published
2022
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30. [D.sup.+] observations give an age of at least one million years for a cloud core forming sun-like stars

Author

Brunken, Sandra, Sipila, Olli, Chambers, Edward T., Harju, Jorma, Casellr, Paola, Asvany, Oskar, Honingh, Cornelia E., Kaminski, Tomasz, Menten, Karl M., Stutzki, Jurgen, and Schlemmer, Stephan

Subjects
Star formation -- Observations, Astronomical research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The age of dense interstellar cloud cores, where stars and planets form, is a crucial parameter in star formation and difficult to measure. Some models predict rapid collapse (1,2), whereas others predict timescales of more than one million years (ref. 3). One possible approach to determining the age is through chemical changes as cloud contraction occurs, in particular through indirect measurements of the ratio of the two spin isomers (ortho/para) of molecular hydrogen, [H.sub.2], which decreases monotonically with age (4-6). This has been done for the dense cloud core L183, for which the deuterium fractionation of diazenylium ([N.sub.2][H.sup.+]) was used as a chemical clock to infer (7) that the core has contracted rapidly (on a timescale of less than 700,000 years). Among astronomically observable molecules, the spin isomers of the deuterated trihydrogen cation, ortho-[H.sub.2][D.sup.+] and para-[H.sub.2][D.sup.+], have the most direct chemical connections to [H.sub.2] (refs 8-12) and their abundance ratio provides a chemical clock that is sensitive to greater cloud core ages. So far this ratio has not been determined because para-[H.sub.2][D.sup.+] is very difficult to observe. The detection of its rotational ground-state line has only now become possible thanks to accurate measurements of its transition frequency in the laboratory (13), and recent progress in instrumentation technology (14,15). Here we report observations of ortho- and para-[H.sub.2][D.sup.+] emission and absorption, respectively, from the dense cloud core hosting IRAS 16293-2422 A/B, a group of nascent solar-type stars (with ages of less than 100,000 years). Using the ortho/para ratio in conjunction with chemical models, we find that the dense core has been chemically processed for at least one million years. The apparent discrepancy with the earlier [N.sub.2][H.sup.+] work (7) arises because that chemical clock turns off sooner than the [H.sub.2][D.sup.+] clock, but both results imply that star-forming dense cores have ages of about one million years, rather than 100,000 years., We detected the ground-state rotational transition of the para spin isomer of the deuterated trihydrogen cation (para-[H.sub.2][D.sup.+]) at 1.370085 THz (ref. 13) (wavelength λ = 219 µm) towards IRAS 16293-2422 [...]

Published
2014

31. ESA P3-NEO-XXII-TN2: NEO Observation Concepts for Radar Systems - Technical Note 2

Author

Cicalò, Stefano, Bernardi, Fabrizio, PUPILLO, Giuseppe, OROSEI, Roberto, RIGHINI, SIMONA, MASTROGIUSEPPE, MARCO, PISANU, Tonino, SCHIRRU , LUCA, Harju, Jorma, Penttilä, Antti, ITA, FIN, Sessler, Guther - Koschny, Detlef - Doelling, Ernesto (ESA-ESOC), and Sessler, Gunther (ESA-ESOC Technical Officer)

Abstract

Technical Note 2 is a deliverable of the ESA project SSA-P3-NEO-XXII and it concerns the Work Package 2000 (WP2000): “Available Radar Assets for Performing NEO Observations”. The WP2000 is dedicated to the study of potential NEOs and ground stations to be involved, focusing on European and ESA stations, including radar, satellite tracking, radio astronomy, and possibly suggesting areas of upgrade. The WP2000 is divided into the sub-packages: - WP2100: NEO Population Analysis for Radar Observations. To identify which NEOs could be observed by a ground-based radar system, according to the probability distribution of NEOs size and distance from Earth. - WP2200: Radar Systems for NEO Observations. To identify a list of ground stations that could be used or upgraded for NEO observations, typically radars, satellite tracking and radio astronomy stations, focusing on European and ESA ground stations, but including also non-European/non-ESA ones. - WP2300: Performances and Possible Improvements. To summarize the main characteristics of the stations identified in the previous items, assessing possible areas of upgrade (e.g. possible new bistatic applications, best frequency bands, etc.); to derive a radar budget in terms of observational strategies and possible upgrades, typically in bistatic mode, in order to be able to observe several NEOs per year, and possibly including a rough estimate of the upgrade complexity and costs.

Published
2021

32. ESA P3-NEO-XXII-TN3: NEO Observation Concepts for Radar Systems - Technical Note 3

Author

Cicalò, Stefano, PUPILLO, Giuseppe, OROSEI, Roberto, RIGHINI, SIMONA, PISANU, Tonino, SCHIRRU , LUCA, Harju, Jorma, Penttilä, Antti, Virkki, Anne, ITA, FIN, Sessler, Guther - Koschny, Detlef - Doelling, Ernesto (ESA-ESOC), and Sessler, Gunther (ESA-ESOC Technical Officer)

Abstract

Technical Note 3 is a deliverable of the ESA project SSA-P3-NEO-XXII and it concerns the Work Package 3000 (WP3000): “Radar observation campaign”. WP3000 is dedicated to the Task 3 of the SoW: the design and realization of a measurement campaign with existing radar systems, including data processing. The WP3000 is divided into the sub-packages: - WP3100: Definition of a Radar Observation Campaign (responsible: INAF) To suggest and define a real NEO observation campaign using radar systems, involving European sensors. - WP3200: Realization of a Radar Observation Campaign (responsible: INAF) To contribute in the realization of the radar observation campaign previously defined. - WP3300: Data Analysis – Orbit Determination (responsible: SpaceDys) To gather and process the data of the radar observation campaign, for orbit determination. - WP3400: Data Analysis – Radar Imaging (responsible: University of Helsinki) To gather and process the data of the radar observation campaign, for radar imaging.

Published
2021

34. Efficient Methanol Production on the Dark Side of a Prestellar Core

Author

Harju, Jorma, Pineda, Jaime E., Vasyunin, Anton, I, Caselli, Paola, Offner, Stella S. R., Goodman, Alyssa A., Juvela, Mika, Sipilae, Olli, Faure, Alexandre, Le Gal, Romane, Hily-Blant, Pierre, Alves, Joao, Bizzocchi, Luca, Burkert, Andreas, Chen, Hope, Friesen, Rachel K., Guesten, Rolf, Myers, Philip C., Punanova, Anna, Rist, Claire, Rosolowsky, Erik, Schlemmer, Stephan, Shirley, Yancy, Spezzano, Silvia, Vastel, Charlotte, Wiesenfeld, Laurent, Harju, Jorma, Pineda, Jaime E., Vasyunin, Anton, I, Caselli, Paola, Offner, Stella S. R., Goodman, Alyssa A., Juvela, Mika, Sipilae, Olli, Faure, Alexandre, Le Gal, Romane, Hily-Blant, Pierre, Alves, Joao, Bizzocchi, Luca, Burkert, Andreas, Chen, Hope, Friesen, Rachel K., Guesten, Rolf, Myers, Philip C., Punanova, Anna, Rist, Claire, Rosolowsky, Erik, Schlemmer, Stephan, Shirley, Yancy, Spezzano, Silvia, Vastel, Charlotte, and Wiesenfeld, Laurent

Abstract

We present Atacama Large Millimeter/submillimeter Array maps of the starless molecular cloud core Ophiuchus/H-MM1 in the lines of deuterated ammonia (ortho-NH2D), methanol (CH3OH), and sulfur monoxide (SO). The dense core is seen in NH2D emission, whereas the CH3OH and SO distributions form a halo surrounding the core. Because methanol is formed on grain surfaces, its emission highlights regions where desorption from grains is particularly efficient. Methanol and sulfur monoxide are most abundant in a narrow zone that follows the eastern side of the core. This side is sheltered from the stronger external radiation field coming from the west. We show that photodissociation on the illuminated side can give rise to an asymmetric methanol distribution but that the stark contrast observed in H-MM1 is hard to explain without assuming enhanced desorption on the shaded side. The region of the brightest emission has a wavy structure that rolls up at one end. This is the signature of Kelvin-Helmholtz instability occurring in sheared flows. We suggest that in this zone, methanol and sulfur are released as a result of grain-grain collisions induced by shear vorticity.

Published
2020

35. Efficient Methanol Production on the Dark Side of a Prestellar Core

Author

Harju, Jorma, primary, Pineda, Jaime E., additional, Vasyunin, Anton I., additional, Caselli, Paola, additional, Offner, Stella S. R., additional, Goodman, Alyssa A., additional, Juvela, Mika, additional, Sipilä, Olli, additional, Faure, Alexandre, additional, Le Gal, Romane, additional, Hily-Blant, Pierre, additional, Alves, João, additional, Bizzocchi, Luca, additional, Burkert, Andreas, additional, Chen, Hope, additional, Friesen, Rachel K., additional, Güsten, Rolf, additional, Myers, Philip C., additional, Punanova, Anna, additional, Rist, Claire, additional, Rosolowsky, Erik, additional, Schlemmer, Stephan, additional, Shirley, Yancy, additional, Spezzano, Silvia, additional, Vastel, Charlotte, additional, and Wiesenfeld, Laurent, additional

Published
2020
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38. Cloud G074.11+00.11: a stellar cluster in formation

Author

Saajasto, Mika, primary, Harju, Jorma, additional, Juvela, Mika, additional, Tie, Liu, additional, Zhang, Qizhou, additional, Liu, Sheng-Yuan, additional, Hirano, Naomi, additional, Wu, Yuefang, additional, Kim, Kee-Tae, additional, Tatematsu, Ken’ichi, additional, Wang, Ke, additional, and Thompson, Mark, additional

Published
2019
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41. Detection of Interstellar Ortho-D2H+ with SOFIA

Author

University of Helsinki, Department of Physics, Harju, Jorma, Sipilä, Olli, Brunken, Sandra, Schlemmer, Stephan, Caselli, Paola, Juvela, Mika, Menten, Karl M., Stutzki, Juergen, Asvany, Oskar, Kaminski, Tomasz, Okada, Yoko, Higgins, Ronan, University of Helsinki, Department of Physics, Harju, Jorma, Sipilä, Olli, Brunken, Sandra, Schlemmer, Stephan, Caselli, Paola, Juvela, Mika, Menten, Karl M., Stutzki, Juergen, Asvany, Oskar, Kaminski, Tomasz, Okada, Yoko, and Higgins, Ronan

Abstract

We report on the detection of the ground-state rotational line of ortho-D2H+ at 1.477 THz (203 mu m) using the German REceiver for Astronomy at Terahertz frequencies (GREAT) on. board the Stratospheric Observatory For Infrared Astronomy (SOFIA). The line is seen in absorption against. far-infrared continuum from the protostellar binary IRAS 16293-2422 in Ophiuchus. The para-D2H+ line at 691.7 GHz was not detected with the APEX telescope toward this position. These D2H+ observations complement our previous detections of para-H2D+ and ortho-H2D+ using SOFIA and APEX. By modeling chemistry and radiative transfer in the dense core surrounding the protostars, we find that the ortho-D2H+ and para-H2D+ absorption features mainly originate in the cool (T <18 K) outer envelope of the core. In contrast, the ortho-H2D+ emission from the core is significantly absorbed by the ambient molecular cloud. Analyses of the combined D2H+ and H2D+ data result in an age estimate of similar to 5. x. 10(5) yr for the core, with an uncertainty of similar to 2. x. 10(5) yr. The core material has probably been pre-processed for another 5. x. 10(5) years in conditions corresponding to those in the ambient molecular cloud. The inferred timescale is more than 10 times the age of the embedded protobinary. The D2H+ and H2D+ ions have large and nearly equal total (ortho+ para) fractional abundances of similar to 10(-9) in the outer envelope. This confirms the central role of H-3 + in the deuterium chemistry in cool, dense gas, and adds support to the prediction of chemistry models that also D-3(+) should be abundant in these conditions.

Published
2017

42. Detection of Interstellar Ortho-D2H+with SOFIA

Author

Harju, Jorma, primary, Sipilä, Olli, additional, Brünken, Sandra, additional, Schlemmer, Stephan, additional, Caselli, Paola, additional, Juvela, Mika, additional, Menten, Karl M., additional, Stutzki, Jürgen, additional, Asvany, Oskar, additional, Kamiński, Tomasz, additional, Okada, Yoko, additional, and Higgins, Ronan, additional

Published
2017
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45. H2D+ observations give an age of at least one million years for a cloud core forming Sun-like stars

Author

Bruenken, Sandra, Sipilae, Olli, Chambers, Edward T., Harju, Jorma, Caselli, Paola, Asvany, Oskar, Honingh, Cornelia E., Kaminski, Tomasz, Menten, Karl M., Stutzki, Juergen, Schlemmer, Stephan, Bruenken, Sandra, Sipilae, Olli, Chambers, Edward T., Harju, Jorma, Caselli, Paola, Asvany, Oskar, Honingh, Cornelia E., Kaminski, Tomasz, Menten, Karl M., Stutzki, Juergen, and Schlemmer, Stephan

Abstract

The age of dense interstellar cloud cores, where stars and planets form, is a crucial parameter in star formation and difficult to measure. Some models predict rapid collapse(1,2), whereas others predict timescales of more than one million years (ref. 3). One possible approach to determining the age is through chemical changes as cloud contraction occurs, in particular through indirect measurements of the ratio of the two spin isomers (ortho/para) of molecular hydrogen, H-2, which decreases monotonically with age(4-6). This has beendone for the dense cloud core L183, for which the deuterium fractionation of diazenylium(N2H+) was used as a chemical clock to infer(7) that the core has contracted rapidly (on a timescale of less than 700,000 years). Among astronomically observable molecules, the spin isomers of the deuterated trihydrogen cation, ortho-H2D+ and para-H2D+, have the most direct chemical connections to H-2 (refs 8-12) and their abundance ratio provides a chemical clock that is sensitive to greater cloud core ages. So far this ratio has not been determined because para-H2D+ is very difficult to observe. The detection of its rotational ground-state line has only now become possible thanks to accurate measurements of its transition frequency in the laboratory(13), and recent progress in instrumentation technology(14,15). Here we report observations of ortho-and para-H2D+ emission and absorption, respectively, from the dense cloud core hosting IRAS 16293-2422 A/B, a group of nascent solar-type stars (with ages of less than 100,000 years). Using the ortho/para ratio in conjunction with chemical models, we find that the dense core has been chemically processed for at least one million years. The apparent discrepancy with the earlier N2H+ work(7) arises because that chemical clock turns off sooner than the H2D+ clock, but both results imply that star-forming dense cores have ages of about one million years, rather than 100,000 years.

Published
2014

46. Tähtipöly ja elämän reunaehdot

Author

Harju, Jorma

Subjects
Artikkelit, kosmologia, tähtitiede
Abstract

Suurin osa tuntemamme maailmankaikkeuden aineesta on vetyä (1H) ja heliumia (4He), joiden suhteelliset runsaudet vallalla olevan kosmologisen teorian mukaan määräytyivät jo muutaman ensimmäisen minuutin aikana suuren alkuräjähdyksen jälkeen. Vedyn ja heliumin ja näiden harvinaisten isotooppien, deuteriumin (D tai 2H), tritiumin (3H), ja heliumin isotoopin 3He, lisäksi alkuräjähdyksessä uskotaan syntyneen pieni määrä järjestysluvultaan kolmatta alkuainetta litiumia (7Li).

Published
1998

48. H2D+ observations give an age of at least one million years for a cloud core forming Sun-like stars.

Author

Brünken, Sandra, Chambers, Edward T., Asvany, Oskar, Honingh, Cornelia E., Stutzki, Jürgen, Schlemmer, Stephan, Sipilä, Olli, Harju, Jorma, Caselli, Paola, Kamiński, Tomasz, and Menten, Karl M.

Subjects
STELLAR evolution, INTERSTELLAR medium, MATHEMATICAL models, RADIATIVE transfer, ISOMER synthesis
Abstract

The age of dense interstellar cloud cores, where stars and planets form, is a crucial parameter in star formation and difficult to measure. Some models predict rapid collapse, whereas others predict timescales of more than one million years (ref. 3). One possible approach to determining the age is through chemical changes as cloud contraction occurs, in particular through indirect measurements of the ratio of the two spin isomers (ortho/para) of molecular hydrogen, H2, which decreases monotonically with age. This has been done for the dense cloud core L183, for which the deuterium fractionation of diazenylium (N2H+) was used as a chemical clock to infer that the core has contracted rapidly (on a timescale of less than 700,000 years). Among astronomically observable molecules, the spin isomers of the deuterated trihydrogen cation, ortho-H2D+ and para-H2D+, have the most direct chemical connections to H2 (refs 8, 9, 10, 11, 12) and their abundance ratio provides a chemical clock that is sensitive to greater cloud core ages. So far this ratio has not been determined because para-H2D+ is very difficult to observe. The detection of its rotational ground-state line has only now become possible thanks to accurate measurements of its transition frequency in the laboratory, and recent progress in instrumentation technology. Here we report observations of ortho- and para-H2D+ emission and absorption, respectively, from the dense cloud core hosting IRAS 16293-2422 A/B, a group of nascent solar-type stars (with ages of less than 100,000 years). Using the ortho/para ratio in conjunction with chemical models, we find that the dense core has been chemically processed for at least one million years. The apparent discrepancy with the earlier N2H+ work arises because that chemical clock turns off sooner than the H2D+ clock, but both results imply that star-forming dense cores have ages of about one million years, rather than 100,000 years. [ABSTRACT FROM AUTHOR]

Published
2014
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49. Huonekalutehtaan raaka-ainehäviöt alkukoneistuksessa

Author

Teknillinen korkeakoulu, Helsinki University of Technology, Puunjalostusosasto, Kivimaa, Eero, Harju, Jorma, Teknillinen korkeakoulu, Helsinki University of Technology, Puunjalostusosasto, Kivimaa, Eero, and Harju, Jorma

Published
1973

50. Magnetic Phenomena of the Interstellar Medium in Theory and Observation

Author

Väisälä, Miikka, University of Helsinki, Faculty of Science, Department of Physics, Division of Particle Physics and Astrophysics, Aalto University, School of Science, Department of Computer Science, ReSoLVE Centre of Excellence, Helsingin yliopisto, matemaattis-luonnontieteellinen tiedekunta, fysiikan laitos, Helsingfors universitet, matematisk-naturvetenskapliga fakulteten, institutionen för fysik, Mac Low, Mordecai-Mark, Käpylä, Maarit, Harju, Jorma, and Juvela, Mika

Subjects
Magnetohydrodynamics, Interstellar medium, Polarization, Star formation, Galactic dynamo, GPGPU
Abstract

Magnetic fields and turbulent flows pervade the interstellar medium on all scales. The magnetic turbulence that emerges on the large scales cascades towards the small scales where it influences molecular cloud structure, and star formation within the densest and coldest clumps of the clouds. Active star formation results in supernovae, and the supernova-driven turbulence takes part in the galactic dynamo process leading to the inverse cascade of turbulent energy. Such a process is one example of self-organisatory processes in the interstellar medium where order arises from chaos. Supernovae also induce and influence other important processes in the galactic disks, and this thesis examines some of them. Differentially rotating disk systems, such as galaxies, are prone to magnetorotational instability, where weak magnetic fields destabilise the otherwise hydrodynamically stable disk system, and lead to angular momentum transport outwards. However, magnetorotational instability can be quenched or even damped by another source of turbulence such as supernovae. As both magnetorotational instability and supernovae are capable of producing dynamo effects, the galactic large-scale magnetic fields are proposed to arise as an interplay of these two effects. In addition, supernovae are observed to be able to generate and sustain large-scale flows in galaxies through the anisotropic kinetic alpha effect. Thermodynamical effects have a significant influence on the properties of turbulence. Due to baroclinicity, the supernova-driven turbulence is highly vortical in nature. These types of flows produce a narrow, non-Gaussian velocity distribution with extended wings and an exponential magneti field distribution. Such effects should be taken into account when interstellar turbulence is parametrized in the form of initial conditions and forcing functions for the purpose of making smaller scale models of molecular cloud formation. The Gaussianity of the magnetic field fluctuations is a common assumption, for example, when fitting magnetic field models to explain large-scale polarization maps of the interstellar dust, and our results suggest that such assumptions should require more examination. To study these phenomena, a combination of numerical approaches and observational methods are needed. Exploring physics of turbulence requires the tools of high-performance computing and precise, high-order numerical schemes. Because of the rapidly increasing demands of computation, novel approaches have to be investigated. To improve computational efficiency this thesis shows how the sixth-order finite difference method can be accelerated with the help of graphics processing units. The properties of the interstellar medium can be examined best by the emission of atomic/molecular gas and by the emission, absorption and scattering of interstellar dust. Looking at small-scale phenomena, molecular line emission from cold prestellar cores is explored. More large-scale effects are examined with the help of polarized dust emission, by combining radiative transfer calculations with the results of a supernova-driven model of the interstellar medium, including a realistic multiphase structure and dynamo-generated small- and large-scale magnetic fields. This thesis contains seven papers. Of these, three papers examine the processes driving turbulence in differentially rotating disks via numerical modelling, while one paper looks into how graphics processing units can accelerate such calculations. Observationally, two papers study cold cores and early stages of star formation with the help of radio telescopes, and one paper examines how supernova-driven turbulence is reflected in the large-scale emission of diffuse interstellar dust. Keywords: Magnetohydrodynamics, interstellar medium, galactic dynamo, polarization, star formation, GPGPU Magneettikentät ja turbulenttiset virtaukset ovat osallisina tähtienvälisen aineen kaikissa mittakaavoissa. Sellaisen magneettisen turbulenssin vaikutus, joka lähtee liikkeelle suurissa mittakaavoissa, ryöppyää pieniin mittakaavoihin ja siten vaikuttaa sekä molekyylipilvien muodostumiseen että tähtien syntymiseen näiden pilvien tiheissä ja kylmissä ytimissä. Tähtien synty johtaa supernoviin ja supernovien ajama turbulenssi ottaa osaa galaktisen dynamon toimintaan, mikä siirtää energiaa pienestä mittakaavasta suureen. Sellaiset prosessit ovat esimerkki ilmiöistä tähtienvälisessä aineessa, joissa kaoottiset olosuhteet synnyttävät järjestyneitä rakenteita. Supernovat myös vaikuttavat muihin prosesseihin galaksien kiekkojen sisällä, ja tämä väitöskirja tarkastelee joitakin niistä. Differentiaalisesti pyörivät kiekkojärjestelmät, kuten galaksit, voivat muuttua epävakaiksi heikon magneettikentän aiheuttamien jännitysten johdosta. Heikot magneettikentät pyörivissä kiekoissa tekevät muuten virtauksiltaan vakaan kiekon epävakaaksi, mikä johtaa liikemäärämomentin siirtymiseen kiekon ulko-osiin ja turbulenssin kasvuun. Kuitenkin tämä ilmiö saattaa vaimeta tai jopa sammua kokonaan, jos jokin toinen turbulenssin lähde on paikalla - kuten vaikka yllä mainitut supernovat. Koska sekä tämä magnetorotationaalinen epätasapaino että supernovat kykenevät aikaansaamaan dynamoilmiön, syntyvät galaktiset suuren mittakaavan magneettikentät mahdollisesti molempien ilmiöiden vuorovaikutuksen yhdistelmänä. Tämän lisäksi supernovaräjähdysten havaintaan luovan ja ylläpitävän suuren mittakaavan virtauksia epäisotrooppisen kineettisen alfaefektin kautta. Termodynaamisilla efekteillä on merkittävä vaikutus turbulenssin ominaisuuksiin. Väitöskirjassa esitetty tutkimus osoittaa, että supernovien ajama turbulenssi on luonteeltaan voimakkaan pyörteistä, kun lämpöenergian tarkastelu otetaan asianmukaisesti huomioon. Sellaiset virtaukset tuottavat kapean, leveäsiipisen nopeusjakauman ja eksponentiaalisen muotoisen magneettikentän jakauman, mikä olisi hyvä ottaa huomioon, kun tähtienvälistä turbulenssia asetetaan simulaatioiden alkuehdoiksi, pakkovoimafunktioksi molekyylipilvimalleissa, tai käytetään olettamaan magneettikentän fluktuaatioiden jakaumaa havaintoja analysoidessa. Ilmiöiden tutkimiseen vaaditaan yhdistelmä laskennallisia malleja ja erilaisia havaintomenetelmiä. Magnetohydrodynaamisten simulaatioiden lisäksi, laskennan tehostamisen vuoksi, tässä työssä esitetään, kuinka kuudennen kertaluvun erottelumenetelmää voidaan tehostaa grafiikkaprosessorien avulla virtausmekaniikassa. Havaintojen tasolla, pienissä mittakaavoissa tutkitaan kylmien molekyylipilviytimien säteilyä radioteleskoopeilla. Suurissa mittakaavoissa tarkastellaan tähtienvälisien pölyn polarisaatiota yhdistämällä säteilynkuljetussimulaatioita supernovien ajaman, turbulenttisen tähtienvälisen aineen malliin. Mainittuja aiheita käsitellään kokonaisuudessaan seitsemän julkaisun verran. Avainsanat: Magnetohydrodynamiikka, tähtienvälinen aine, galaktinen dynamo, polarisaatio, tähtien synty, GPGPU

Published
2017

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