Your search keyword '"Pulsar"' showing total 229 results

1. Vortices in Andreev–Bashkin Superfluids.

Author

Melnikovsky, L. A.

Subjects

*VORTEX motion, *SUPERFLUIDITY, *HYDRODYNAMICS, *PULSARS

Abstract

Andreev–Bashkin entrainment makes the hydrodynamics of the binary superfluid solution particularly interesting. We investigate stability and motion of quantum vortices in such system. [ABSTRACT FROM AUTHOR]

Published

2024

2. Multiomics-Based Outcome Prediction in Personalized Ultra-Fractionated Stereotactic Adaptive Radiotherapy (PULSAR).

Author

Zhang, Haozhao, Dohopolski, Michael, Stojadinovic, Strahinja, Schmitt, Luiza Giuliani, Anand, Soummitra, Kim, Heejung, Pompos, Arnold, Godley, Andrew, Jiang, Steve, Dan, Tu, Wardak, Zabi, Timmerman, Robert, and Peng, Hao

Subjects

*PREDICTION models, *RADIOTHERAPY, *RECEIVER operating characteristic curves, *MULTIOMICS, *RADIOMICS, *TREATMENT effectiveness, *DECISION making in clinical medicine, *RETROSPECTIVE studies, *MAGNETIC resonance imaging, *DESCRIPTIVE statistics, *METASTASIS, *COMPUTERS in medicine, *MACHINE learning, *BRAIN tumors

Abstract

Simple Summary: Each patient responds uniquely to treatment, which makes personalized ultra-fractionated stereotactic adaptive radiotherapy (PULSAR) a promising strategy that delivers high-dose radiation at extended intervals for tailored adaptation. Currently, treatment modifications mainly rely on physicians' assessments of tumor size changes. Our study aims to develop a more objective multiomics-based approach for predicting treatment outcomes in PULSAR, including radiomics, dosiomics, and delta features. By leveraging multiomics analysis and machine learning, we intend to transition the adaptation and decision-making process from empirical judgments to a more data-informed strategy, allowing clinicians to swiftly respond to changes in tumor behavior and provide more personalized treatment for each patient. Objectives: This retrospective study aims to develop a multiomics approach that integrates radiomics, dosiomics, and delta features to predict treatment responses in brain metastasis (BM) patients undergoing PULSAR. Methods: A retrospective study encompassing 39 BM patients with 69 lesions treated with PULSAR was undertaken. Radiomics, dosiomics, and delta features were extracted from both pre-treatment and intra-treatment MRI scans alongside dose distributions. Six individual models, alongside an ensemble feature selection (EFS) model, were evaluated. The classification task focused on distinguishing between two lesion groups based on whether they exhibited a volume reduction of more than 20% at follow-up. Performance metrics, including sensitivity, specificity, accuracy, precision, F1 score, and the area under the receiver operating characteristic (ROC) curve (AUC), were assessed. Results: The EFS model integrated the features from pre-treatment radiomics, pre-treatment dosiomics, intra-treatment radiomics, and delta radiomics. It outperformed six individual models, achieving an AUC of 0.979, accuracy of 0.917, and F1 score of 0.821. Among the top nine features of the EFS model, six features came from post-wavelet transformation and three from original images. Conclusions: The study demonstrated the feasibility of employing a data-driven multiomics approach to predict treatment outcomes in BM patients receiving PULSAR treatment. Integrating multiomics with intra-treatment decision support in PULSAR shows promise for optimizing patient management and reducing the risks of under- or over-treatment. [ABSTRACT FROM AUTHOR]

Published

2024

3. Serendipitous Discovery of a 431 ms Pulsar in the Background of Westerlund 1.

Author

Piga, Viviana, Burgay, Marta, Possenti, Andrea, Ridolfi, Alessandro, Pilia, Maura, Rea, Nanda, Perna, Rosalba, Colpi, Monica, and Israel, Gianluca

Subjects

*ELECTRON density, *RADIO telescopes, *PULSARS, *DISPERSION (Chemistry), PULSAR detection

Abstract

We report the discovery of PSR J1646−4545, a 431 ms isolated pulsar, in the direction of the young massive cluster Westerlund 1. The pulsar was found in data taken between the years 2005 and 2010 with the "Murriyang" Parkes radio telescope in Australia. Thanks to the numerous detections of the pulsar, we were able to derive a phase-connected timing solution spanning the whole data set. This allowed us to precisely locate the pulsar at the border of the cluster and to measure its spin-down rate. The latter implies a characteristic age of ∼25 Myr, about twice as large as the estimated age of Westerlund 1. The age of PSR J1646−4545, together with its dispersion measure of ∼1029 pc cm−3, more than twice the value predicted by the two main galactic electron density models for Westerlund 1, makes the association of the pulsar with the cluster highly unlikely. We also report on ramifications from the presence of a magnetar in Westerlund 1 and the apparent lack of ordinary radio pulsars. [ABSTRACT FROM AUTHOR]

Published

2024

4. On the overall properties of young neutron stars: an application to the Crab pulsar.

Author

Bernal, Cristian G., Frajuca, Carlos, Hirsch, Henrique D., Minari, Beatriz, Magalhaes, Nadja S., Selbach, Lucas B., Wen-Cong Chen, and Popov, Sergey

Subjects

*NEUTRON stars, *CRABS, *MAGNETIC fields, *SUPERNOVAE, *BINARY pulsars

Abstract

In this brief report, we present a model that complements the well-established canonical model for the spin evolution of rotation-powered pulsars, which is typically used to estimate ages, spin-down luminosity, and surface magnetic fields of middle-aged pulsars. We analytically explore the growth of the magnetic field during a pulsar's early history, a period shortly after supernova explosion from which the neutron star forms, encompassing the hypercritical phase and subsequent reemergence of the magnetic field. We analyze the impact of such growth on the early dynamics of the pulsar. Investigations into a pulsar's magnetic evolution are not new, and we expand the knowledge in this area by examining the evolutionary implications in a scenario governed by growth functions. The proposed growth functions, calibrated with data from the Crab pulsar, exhibit satisfactory physical behaviors. [ABSTRACT FROM AUTHOR]

Published

2024

5. Decoding the Nature of Coherent Radio Emission in Pulsars I: Observational Constraints.

Author

Mitra, Dipanjan, Basu, Rahul, and Melikizde, George I.

Subjects

*PULSARS, *CIRCULAR polarization, *PLASMA flow, *STAR formation, *COHERENT radiation, *SOLAR radio emission, *QUANTUM plasmas

Abstract

Radio observations from normal pulsars indicate that the coherent radio emission is excited by curvature radiation from charge bunches. In this review, we provide a systematic description of the various observational constraints on the radio emission mechanism. We have discussed the presence of highly polarized time samples where the polarization position angle follow two orthogonal well-defined tracks across the profile that closely match the rotating vector model in an identical manner. The observations also show the presence of circular polarization, with both the right and left handed circular polarization seen across the profile. Other constraints on the emission mechanism are provided by the detailed measurements of the spectral index variation across the profile window, where the central part of the profile, corresponding to the core component, has a steeper spectrum than the surrounding cones. Finally, the detailed measurements of the subpulse drifting behaviour can be explained by considering the presence of non-dipolar field on the stellar surface and the formation of the partially screened gap (PSG) above the polar cap region. The PSG gives rise to a non-stationary plasma flow that has a multi-component nature, consisting of highly energetic primary particles, secondary pair plasma, and iron ions discharged from the surface, with large fragmentation resulting in dense plasma clouds and lower-density inter-cloud regions. The physical properties of the outflowing plasma and the observational constraints lead us to consider coherent curvature radiation as the most viable explanation for the emission mechanism in normal pulsars, where propagation effects due to adiabatic walking and refraction are largely inconsequential. [ABSTRACT FROM AUTHOR]

Published

2024

6. Comprehensive Measurement of Position and Velocity in the Transverse Direction Using the Crab Pulsar.

Author

Feng, Yuan, Zhang, Huanzi, Chen, Jianfeng, Liu, Jin, and Ma, Xin

Subjects

PULSARS, VELOCITY measurements, CRABS, ORBITS (Astronomy), VELOCITY, MOTION

Abstract

Traditional X-ray pulsar ranging and velocity measurement methods only estimate the radial position and velocity information of the pulsar. For non-linear orbits, errors in the transverse position and velocity of the pulsar lead to errors in the radial velocity of the pulsar, leading to distortion of the X-ray pulsar profile. Based on this, we propose using the distortion of the pulsar profile to infer the transverse position and velocity information of the pulsar. First, a model of the distortion of the pulsar profile due to errors in the transverse position and velocity is established, and the observable directions of the transverse position and velocity are given separately. Then, considering that the distortions in the pulsar profile caused by errors in the transverse position and velocity are indistinguishable, we establish a reactive motion state measure related to the observable directions for the transverse position and velocity errors as a new observable measure in X-ray pulsar navigation. The experimental results show that the precision of the reactive motion state measure reaches 0.57, equivalent to a position error of 284.50 m or a velocity error of 0.57 m/s. [ABSTRACT FROM AUTHOR]

Published

2024

7. A discovery of two slow pulsars with FAST: "Ronin" from the globular cluster M15.

Author

Zhou, Dengke, Wang, Pei, Li, Di, Fang, Jianhua, Miao, Chenchen, Freire, Paulo C. C., Zhang, Lei, Zhang, Dandan, Chen, Huaxi, Feng, Yi, Xiao, Yifan, Xie, Jintao, Zhang, Xu, Jin, Chenwu, Wang, Han, Ke, Yinan, Guo, Xuerong, Zhao, Rushuang, Niu, Chenhui, and Zhu, Weiwei

Abstract

Globular clusters harbor numerous millisecond pulsars, but long-period pulsars (P ≳ 100 ms) are rarely found. In this study, we employed a fast folding algorithm to analyze observational data from multiple globular clusters obtained by the Five-hundred-meter Aperture Spherical radio Telescope (FAST), aiming to detect the existence of long-period pulsars. We estimated the impact of the median filtering algorithm in eliminating red noise on the minimum detectable flux density (Smin) of pulsars. Subsequently, we successfully discovered two isolated long-period pulsars in M15 with periods approximately equal to 1.928451 and 3.960716 s, respectively. On the P − P ˙ diagram, both pulsars are positioned below the spin-up line, suggesting a possible history of partial recycling in X-ray binary systems disrupted by dynamical encounters later on. According to timing results, these two pulsars exhibit remarkably strong magnetic fields. If the magnetic fields were weakened during the accretion process, then a short duration of accretion might explain the strong magnetic fields of these pulsars. [ABSTRACT FROM AUTHOR]

Published

2024

8. Planetary Nebulae and Supernovae Remnants

Author

Dire, James, Hubbell, Gerald R., Series Editor, and Dire, James

Published

2024

9. Pulsar Wind Nebulae

Author

Mitchell, A. M. W., Gelfand, J., Bambi, Cosimo, editor, and Santangelo, Andrea, editor

Published

2024

10. Investigating pulsar emission variability using the MeerKAT radio telescope

Author

Song, Xiaoxi, Keith, Michael, and Weltevrede, Patrick

Subjects

Pulsar

Abstract

Since the discovery of pulsars more than 50 years ago, pulsars have revealed complicated radio emission phenomena on short timescales of a few single pulses, on timescales comparable to the length of observations, or even longer. As pulsars are weak radio sources, pulsar studies have been aided by ever larger radio telescopes, such as provided by interferometers with numerous single dishes. Effectively scheduling pulsar observations has become increasingly important with ever larger telescopes, and their ability to form subarrays provides further opportunities. Therefore, we develop a simple scheme to find an optimal observing time for a given pulsar. The designed scheme guarantees a long enough observing time to obtain a high fidelity pulse profile. This ensures sufficient precision to, for example, characterise pulse shape variations in different observations and to perform pulsar timing experiments. We test the scheme with data obtained from the MeerKAT radio telescope. The method is used for the Thousand-Pulsar-Array (TPA) long-term timing project, for which we find that using two 32-dish MeerKAT subarrays is the most efficient observing strategy to monitor a large number of pulsars. However, different subarray configurations can be beneficial for other observing programmes. In addition to the pulsar monitoring campaign, the TPA project obtained one-off high quality and signal-to-noise ratio (S/N) data for over 1000 pulsars. These data are particularly suitable for single pulse studies. We adopt a systematic approach with a semi-automated pipeline to study the subpulse modulation properties of 1198 pulsars, representing a large fraction of the known pulsar population. We find that many pulsars show periodic pulse shape variability in the form of drifting subpulses, and demonstrate that this phenomenon is common such that it is detectable in 60% of all pulsars if sufficient S/N is available. This unprecedented large systematic study allows the evolution of drifting subpulses to be studied over the lifetime of pulsars. In particular it is found that the modulation period P_3 is evolving in a non-monotonic way. This can be naturally explained if aliasing occurs for young pulsars, who have intrinsically the fastest modulation. Although this explanation is opposite to the prediction of the standard drifting subpulse model, it can be reconciled if the polar cap physics is driving a beat frequency. Pulsar timing has revealed rotational instabilities in most pulsars. The spin-down rate often reveals a quasi-periodic behaviour and the integrated pulse profile of some pulsars is seen to switch between different stable forms. Remarkably, the changes in the spin-down rate and pulse shape are correlated for a small number of pulsars, and therefore are both thought to be driven by the same magnetospheric process. One of these pulsars, PSR J0742-2822, is studied in detail. An enhanced correlation between the spin-down rate evolution and pulse profile variations is seen after a large glitch. Our analysis uses an extended dataset, and Principal Component Analysis to quantify profile variability. The correlation is found to become irregular after another glitch, making it unclear if and how the spin-down rate evolution, pulse shape variations and glitches are associated. We show that the relation between spin down and profile variability is more complicated than previously reported, and cannot be explained by a two-state magnetospheric switching model.

Published

2023

11. Shanghai Tianma Radio Telescope and Its Role in Pulsar Astronomy.

Author

Yan, Zhen, Shen, Zhiqiang, Wu, Yajun, Zhao, Rongbing, Liu, Jie, Huang, Zhipeng, Wang, Rui, Wang, Xiaowei, Liu, Qinghui, Li, Bin, Wang, Jinqing, Zhong, Weiye, Jiang, Wu, and Xia, Bo

Subjects

*ASTRONOMY, *RADIO telescopes, *TEST design, *ON-site evaluation, *BASEBAND, *INTERFEROMETRY

Abstract

After two phases of on-site construction and testing (2010–2013 and 2013–2017), the Shanghai Tianma Radio Telescope (TMRT) can work well, with efficiencies better than 50% from 1.3 to 50.0 GHz, mainly benefiting from its low-noise cryogenic receivers and active surface system. Pulsars were chosen as important targets of research at the TMRT because of their important scientific and applied values. To meet the demands of pulsar-related observations, TMRT is equipped with some necessary backends, including a digital backend system (DIBAS) supporting normal pulsar observation modes, a real-time fast-radio-burst-monitoring backend, and baseband backends for very-long-baseline interferometry (VLBI) observations. Utilizing its high sensitivity and simultaneous dual-frequency observation capacity, a sequence of pulsar research endeavors has been undertaken, such as long-term pulsar timing, magnetar monitoring, multi-frequency (or high-frequency) observations, interstellar scintillation, pulsar VLBI, etc. In this paper, we give a short introduction about pulsar observation systems at the TMRT and briefly review the results obtained by these pulsar research projects. [ABSTRACT FROM AUTHOR]

Published

2024

12. Rethinking the potential role of dose painting in personalized ultra-fractionated stereotactic adaptive radiotherapy.

Author

Hao Peng, Jie Deng, Jiang, Steve, and Timmerman, Robert

Subjects

STEREOTACTIC radiotherapy, RADIOTHERAPY, TUMOR microenvironment, PULSARS, RADIOBIOLOGY

Abstract

Fractionated radiotherapy was established in the 1920s based upon two principles: (1) delivering daily treatments of equal quantity, unless the clinical situation requires adjustment, and (2) defining a specific treatment period to deliver a total dosage. Modern fractionated radiotherapy continues to adhere to these century-old principles, despite significant advancements in our understanding of radiobiology. At UT Southwestern, we are exploring a novel treatment approach called PULSAR (Personalized Ultra-Fractionated Stereotactic Adaptive Radiotherapy). This method involves administering tumoricidal doses in a pulse mode with extended intervals, typically spanning weeks or even a month. Extended intervals permit substantial recovery of normal tissues and afford the tumor and tumor microenvironment ample time to undergo significant changes, enabling more meaningful adaptation in response to the evolving characteristics of the tumor. The notion of dose painting in the realm of radiation therapy has long been a subject of contention. The debate primarily revolves around its clinical effectiveness and optimal methods of implementation. In this perspective, we discuss two facets concerning the potential integration of dose painting with PULSAR, along with several practical considerations. If successful, the combination of the two may not only provide another level of personal adaptation ("adaptive dose painting"), but also contribute to the establishment of a timely feedback loop throughout the treatment process. To substantiate our perspective, we conducted a fundamental modeling study focusing on PET-guided dose painting, incorporating tumor heterogeneity and tumor control probability (TCP). [ABSTRACT FROM AUTHOR]

Published

2024

13. On the overall properties of young neutron stars: an application to the Crab pulsar

Author

Cristian G. Bernal, Carlos Frajuca, Henrique D. Hirsch, Beatriz Minari, Nadja S. Magalhaes, and Lucas B. Selbach

Subjects

pulsar, neutron star, spin-down, magnetic field, braking index, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

In this brief report, we present a model that complements the well-established canonical model for the spin evolution of rotation-powered pulsars, which is typically used to estimate ages, spin-down luminosity, and surface magnetic fields of middle-aged pulsars. We analytically explore the growth of the magnetic field during a pulsar’s early history, a period shortly after supernova explosion from which the neutron star forms, encompassing the hypercritical phase and subsequent reemergence of the magnetic field. We analyze the impact of such growth on the early dynamics of the pulsar. Investigations into a pulsar’s magnetic evolution are not new, and we expand the knowledge in this area by examining the evolutionary implications in a scenario governed by growth functions. The proposed growth functions, calibrated with data from the Crab pulsar, exhibit satisfactory physical behaviors.

Published

2024

14. Non‐symmetrical sparking may hint "zits" on a pulsar surface.

Author

Wang, Zhengli, Lu, Jiguang, Jiang, Jingchen, Cao, Shunshun, Wang, Weiyang, Liang, Enwei, and Xu, Renxin

Subjects

*PARTICLE physics, *RADIO telescopes, *STANDARD model (Nuclear physics), *SURFACES (Physics), *NEUTRON stars, *PULSARS, *PROBLEM solving

Abstract

Pulsar electrodynamics could be relevant to the physics of stellar surface, which remains poorly understood for more than half a centenary and is difficult to probe due to the absence of direct and clear observational evidence. Nevertheless, highly sensitive telescopes (e.g., China's Five‐hundred‐meter Aperture Spherical radio Telescope, FAST) may play an essential role to solve the problem since the predicted surface condition would have quite different characteristics in some models of pulsar structure, especially after the establishment of the standard model of particle physics. For instance, small hills (or "zits") may exist on solid strangeon star surface with rigidity, preferential discharge, that is, gap sparking, may occur around the hills in the polar cap region. In this work, with the 110‐min polarization observation of PSR B0950+$$ + $$08 targeted by FAST, we report that the gap sparking is significantly non‐symmetrical to the meridian plane on which the rotational and magnetic axes lie. It is then speculated that this asymmetry could be the result of preferential sparking around zits which might rise randomly on pulsar surface. Some polarization features of both single pulses and the mean pulse, as well as the cross‐correlation function of different emission regions, have also been presented. [ABSTRACT FROM AUTHOR]

Published

2024

15. A short review of the pulsar magnetic inclination angles (II).

Author

Li, Biao‐Peng, Ma, Wen‐Qi, and Gao, Zhi‐Fu

Subjects

*MAGNETIC structure, *GRAVITATIONAL waves, *ANGLES, *MAGNETIC fields, *SUPERFLUIDITY, *PULSARS

Abstract

The pulsar magnetic inclination angle is a key parameter for pulsar physics. It influences the observable properties of pulsars, such as the pulse beam width, braking index, polarization, and emission geometry. In this study, we give a brief overview of the current state of knowledge and research on this parameter and its implications for the internal physics of pulsars. We use the observed pulsar data of magnetic inclination angle and braking index to constrain the star's number of precession cycles, ξ$$ \xi $$, which reflects the interaction between superfluid neutrons and other particles inside a neutron star (NS). We apply the method proposed by Cheng et al. (Cheng, Q., Zhang, S. N., Zheng, X. P., & Fan, X. L., 2019, Phys. Rev. D, 99, 083011) to analyze the data of PSR J2013 + 3845 and obtain the constraints for ξ$$ \xi $$ ranging from 2.393×105$$ 2.393\times 1{0}^5 $$ to 1.268×106$$ 1.268\times 1{0}^6 $$. And further analysis suggests that the internal magnetic field structure of PSR J2013 + 3845 is likely dominated by toroidal components. This study may help us understand the process of internal viscous dissipation and the related evolution of the inclination angles of pulsars, and may have important implications for the study of continuous gravitational wave emissions from NS. [ABSTRACT FROM AUTHOR]

Published

2024

16. Repeating fast radio bursts reveal the secret of pulsar magnetospheric activity.

Author

Xu, Renxin and Wang, Weiyang

Subjects

*SOLAR radio bursts, *PULSARS, *COHERENT radiation, *MAGNETIC fields, *NEUTRON stars, *MAGNETOSPHERE

Abstract

The puzzling mechanism of coherent radio emission remains unknown, but fortunately, repeating fast radio bursts (FRBs) provide a precious opportunity, with extremely bright subpulses created in a clear and vacuum‐like pulsar magnetosphere. FRBs are millisecond‐duration signals that are highly dispersed at distant galaxies but with uncertain physical origin(s). Coherent curvature radiation by bunches has already been proposed for repeating FRBs. The charged particles are created during central star's quakes, which can form bunches streaming out along curved magnetic field lines, so as to trigger FRBs. The nature of narrow‐band radiation with time‐frequency drifting can be a natural consequence that bunches could be observed at different times with different curvatures. Additionally, high linear‐polarization can be seen if the line of sight is confined to the beam angle, whereas the emission could be highly circular‐polarized if off‐beam. It is also discussed that pulsar surface may be full of small hills (i.e., zits) which would help producing bulk of energetic bunches for repeating FRBs as well as for rotation‐powered pulsars. [ABSTRACT FROM AUTHOR]

Published

2024

17. Comparative Evaluation of Java Virtual Machine-Based Message Queue Services: A Study on Kafka, Artemis, Pulsar, and RocketMQ.

Author

Chy, Md Showkat Hossain, Arju, Muhammad Ashfakur Rahman, Tella, Sri Manjusha, and Cerny, Tomas

Subjects

REFUSE collection, VIRTUAL machine systems, RESEARCH personnel

Abstract

Message Queue (MQ) services play a vital role in modern distributed systems as they enable asynchronous communication between services and facilitate the decoupling of various components of the system. Among the many MQ services available, Kafka, Apache Pulsar, Artemis, and RocketMQ are popular choices, each offering unique features and capabilities. As the adoption of MQ services continues to grow, choosing the appropriate service that can meet the requirements of the system has become increasingly challenging. Therefore, a comprehensive comparison of these services is crucial to determine the most suitable one for a specific use-case. This research paper presents a thorough evaluation of these MQ services based on critical metrics such as CPU utilization, memory usage, garbage collection, latency, and throughput. Based on our extensive review, no other research has delved into such a detailed evaluation, thereby establishing our work as a cornerstone in this field. The results of our study offer valuable insights into the strengths and limitations of each service. Our findings indicate that each message queue behaves differently inside the Java Virtual Machine (JVM). This work aims to assist developers and researchers in strategically deploying and optimizing MQ services based on specific system and use-case requirements. In addition to providing machine metrics, our results demonstrate the performance of each message queue under different load scenarios, making it a valuable resource for those seeking to ensure the effective functioning of their MQ services. [ABSTRACT FROM AUTHOR]

Published

2023

18. Serendipitous Discovery of a 431 ms Pulsar in the Background of Westerlund 1

Author

Viviana Piga, Marta Burgay, Andrea Possenti, Alessandro Ridolfi, Maura Pilia, Nanda Rea, Rosalba Perna, Monica Colpi, and Gianluca Israel

Subjects

Westerlund 1, pulsar, PSR J1646−4545, Elementary particle physics, QC793-793.5

Abstract

We report the discovery of PSR J1646−4545, a 431 ms isolated pulsar, in the direction of the young massive cluster Westerlund 1. The pulsar was found in data taken between the years 2005 and 2010 with the “Murriyang” Parkes radio telescope in Australia. Thanks to the numerous detections of the pulsar, we were able to derive a phase-connected timing solution spanning the whole data set. This allowed us to precisely locate the pulsar at the border of the cluster and to measure its spin-down rate. The latter implies a characteristic age of ∼25 Myr, about twice as large as the estimated age of Westerlund 1. The age of PSR J1646−4545, together with its dispersion measure of ∼1029 pc cm−3, more than twice the value predicted by the two main galactic electron density models for Westerlund 1, makes the association of the pulsar with the cluster highly unlikely. We also report on ramifications from the presence of a magnetar in Westerlund 1 and the apparent lack of ordinary radio pulsars.

Published

2024

19. Comprehensive Measurement of Position and Velocity in the Transverse Direction Using the Crab Pulsar

Author

Yuan Feng, Huanzi Zhang, Jianfeng Chen, Jin Liu, and Xin Ma

Subjects

pulsar, position, velocity, comprehensive measurement, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

Traditional X-ray pulsar ranging and velocity measurement methods only estimate the radial position and velocity information of the pulsar. For non-linear orbits, errors in the transverse position and velocity of the pulsar lead to errors in the radial velocity of the pulsar, leading to distortion of the X-ray pulsar profile. Based on this, we propose using the distortion of the pulsar profile to infer the transverse position and velocity information of the pulsar. First, a model of the distortion of the pulsar profile due to errors in the transverse position and velocity is established, and the observable directions of the transverse position and velocity are given separately. Then, considering that the distortions in the pulsar profile caused by errors in the transverse position and velocity are indistinguishable, we establish a reactive motion state measure related to the observable directions for the transverse position and velocity errors as a new observable measure in X-ray pulsar navigation. The experimental results show that the precision of the reactive motion state measure reaches 0.57, equivalent to a position error of 284.50 m or a velocity error of 0.57 m/s.

Published

2024

20. Decoding the Nature of Coherent Radio Emission in Pulsars I: Observational Constraints

Author

Dipanjan Mitra, Rahul Basu, and George I. Melikizde

Subjects

pulsar, non-thermal emission, radio emission mechanism, Elementary particle physics, QC793-793.5

Abstract

Radio observations from normal pulsars indicate that the coherent radio emission is excited by curvature radiation from charge bunches. In this review, we provide a systematic description of the various observational constraints on the radio emission mechanism. We have discussed the presence of highly polarized time samples where the polarization position angle follow two orthogonal well-defined tracks across the profile that closely match the rotating vector model in an identical manner. The observations also show the presence of circular polarization, with both the right and left handed circular polarization seen across the profile. Other constraints on the emission mechanism are provided by the detailed measurements of the spectral index variation across the profile window, where the central part of the profile, corresponding to the core component, has a steeper spectrum than the surrounding cones. Finally, the detailed measurements of the subpulse drifting behaviour can be explained by considering the presence of non-dipolar field on the stellar surface and the formation of the partially screened gap (PSG) above the polar cap region. The PSG gives rise to a non-stationary plasma flow that has a multi-component nature, consisting of highly energetic primary particles, secondary pair plasma, and iron ions discharged from the surface, with large fragmentation resulting in dense plasma clouds and lower-density inter-cloud regions. The physical properties of the outflowing plasma and the observational constraints lead us to consider coherent curvature radiation as the most viable explanation for the emission mechanism in normal pulsars, where propagation effects due to adiabatic walking and refraction are largely inconsequential.

Published

2024

21. Constraints on non-local gravity from binary pulsars gravitational emission

Author

Amodio Carleo

Subjects

Non-locality, Pulsar, General relativity, Binary system, Physics, QC1-999

Abstract

Non-local theories of gravity are considered extended theories of gravity, meaning that when the non-local terms are canceled out, the limit of General Relativity (GR) is obtained. Several reasons have led us to consider this theory with increasing interest, but primarily non-locality emerges in a natural way as a ‘side’ effect of the introduction of quantum corrections to GR, the purpose of which was to cure the singularity problem, both at astrophysical and cosmological level. In this paper we studied a peculiar case of the so called Deser-Woodard theory consisting in the addition of a non-local term of the form R□−1R to the Hilbert-Einstein lagrangian, where R is the Ricci scalar, and derived, for the first time, constraints on the dimensionaless non-local parameter A by exploiting the predicted gravitational wave emission in three binary pulsars, namely PSR J1012+5307, PSR J0348+0432 and PSR J1738+0333. We discovered that the instantaneous flux strongly depends on A and that the best constraints (0.12

Published

2024

22. Periodic interstellar scintillation variations of PSRs J0613–0200 and J0636+5128 associated with the Local Bubble shell.

Author

Liu, Yulan, Main, Robert A., Verbiest, Joris P. W., Wu, Ziwei, Ambalappat, Krishnakumar M., Lu, Jiguang, Champion, David J., Cognard, Ismaël, Guillemot, Lucas, Liu, Kuo, McKee, James W., Porayko, Nataliya, Shaifullah, Golam M., and Theureau, Gilles

Abstract

Annual variations of interstellar scintillation can be modelled to constrain parameters of the ionized interstellar medium. If a pulsar is in a binary system, then investigating the orbital parameters is possible through analysis of the orbital variation of scintillation. In observations carried out from 2011 to 2020 by the European Pulsar Timing Array radio telescopes, PSRs J0613–0200 and J0636+5128 show strong annual variations in their scintillation velocity, while the former additionally exhibits an orbital fluctuation. Bayesian theory and Markov-chain-Monte-Carlo methods are used to interpret these periodic variations. We assume a thin and anisotropic scattering screen model, and discuss the mildly and extremely anisotropic scattering cases. PSR J0613–0200 is best described by mildly anisotropic scattering, while PSR J0636+5128 exhibits extremely anisotropic scattering. We measure the distance, velocity, and degree of anisotropy of the scattering screen for our two pulsars, finding that scattering screen distances from Earth for PSRs J0613–0200 and J0636+5128 are 316−20+28 pc and 262−38+96 pc, respectively. The positions of these scattering screens are coincident with the shell of the Local Bubble towards both pulsars. These associations add to the growing evidence of the Local Bubble shell as a dominant region of scattering along many sightlines. [ABSTRACT FROM AUTHOR]

Published

2023

23. Spin Equilibrium of Rapidly Spinning Neutron Stars via Transient Accretion.

Author

Bhattacharyya, Sudip

Subjects

SPIN crossover, NEUTRON stars, ACCRETION disks, MASS transfer, PULSARS, MAGNETOSPHERE, X-ray binaries

Abstract

The concept of spin equilibrium due to an interaction between the stellar magnetosphere and a thin, Keplerian accretion disk, and a well-known formula of the corresponding equilibrium spin frequency, provide a key understanding of spin evolution and the distribution of rapidly spinning neutron stars, viz., millisecond pulsars. However, this concept and formula are for stable accretion, but the mass transfer to most accreting millisecond pulsars is transient and the accretion rate evolves by orders of magnitude during an outburst. In this short and focussed review, we briefly discuss a relatively new concept of the spin equilibrium condition and a new formula for the equilibrium spin frequency for transiently accreting millisecond pulsars. We also review a new method to estimate this equilibrium spin frequency for observed transiently accreting millisecond pulsars, even when a pulsar has not yet attained the spin equilibrium. These will be crucial to probe the spin evolution and distribution of millisecond pulsars, and should also be applicable to all magnetic stars transiently accreting via a thin, Keplerian accretion disk. [ABSTRACT FROM AUTHOR]

Published

2023

24. Shanghai Tianma Radio Telescope and Its Role in Pulsar Astronomy

Author

Zhen Yan, Zhiqiang Shen, Yajun Wu, Rongbing Zhao, Jie Liu, Zhipeng Huang, Rui Wang, Xiaowei Wang, Qinghui Liu, Bin Li, Jinqing Wang, Weiye Zhong, Wu Jiang, and Bo Xia

Subjects

pulsar, magnetar, timing, scintillation, VLBI, Elementary particle physics, QC793-793.5

Abstract

After two phases of on-site construction and testing (2010–2013 and 2013–2017), the Shanghai Tianma Radio Telescope (TMRT) can work well, with efficiencies better than 50% from 1.3 to 50.0 GHz, mainly benefiting from its low-noise cryogenic receivers and active surface system. Pulsars were chosen as important targets of research at the TMRT because of their important scientific and applied values. To meet the demands of pulsar-related observations, TMRT is equipped with some necessary backends, including a digital backend system (DIBAS) supporting normal pulsar observation modes, a real-time fast-radio-burst-monitoring backend, and baseband backends for very-long-baseline interferometry (VLBI) observations. Utilizing its high sensitivity and simultaneous dual-frequency observation capacity, a sequence of pulsar research endeavors has been undertaken, such as long-term pulsar timing, magnetar monitoring, multi-frequency (or high-frequency) observations, interstellar scintillation, pulsar VLBI, etc. In this paper, we give a short introduction about pulsar observation systems at the TMRT and briefly review the results obtained by these pulsar research projects.

Published

2024

25. Investigation of Accuracy of TOA and SNR of Radio Pulsar Signals for Vehicles Navigation.

Author

Kabakchiev, Hristo, Behar, Vera, Kabakchieva, Dorina, Kisimov, Valentin, and Stefanova, Kamelia

Subjects

*PULSARS, *TIME-of-arrival estimation, *TRACKING radar, *SURFACE of the earth, *NAVIGATION (Astronautics), *RECEIVING antennas

Abstract

It is known that X-ray and gamma-ray pulsars can only be observed by spacecraft because signals from these pulsars are impossible to be detected on the Earth's surface due to their strong absorption by the Earth's atmosphere. The article is devoted to the theoretical aspects regarding the development of an autonomous radio navigation system for transport with a small receiving antenna, using radio signals from pulsars, similar to navigation systems for space navigation. Like GNSS systems (X-ray and radio), they use signals from four suitable pulsars to position the object. These radio pulsars (out of 50) are not uniformly distributed but are grouped in certain directions (at least 6 clusters can be determined). When using small antennas (with an area of up to tens of square meters) for pulsar navigation, the energy of the pulsar signals received within a few minutes is extremely insufficient to obtain the required level of SNR at the output of the receiver to form TOA estimation, ensuring positioning accuracy up to tens of kilometers. This is one of the scientific tasks that is solved in the paper by studying the relationship between the SNR of the receiver output, which depends on the size of the antenna, the type of signal processing, and the magnitude of the TOA accuracy estimate. The second scientific task that is solved in the paper is the adaptation of all the possible approaches and algorithms suggested in the statistical theory of radars in the suggested signal algorithm for antenna processing and to evaluate the parameters of the TOA and DS pulsar signals, in order to increase the SNR ratio at the receiver output, while preserving the dimensions of the antenna. In this paper, the functional structure of signal processing in a pulsar transport navigation system is proposed, and the choice of the observed second and millisecond pulsars for obtaining a more accurate TOA estimate is discussed. The proposed estimates of positioning accuracy (TOA only, no phase) in an autonomous pulsar vehicle navigation system would only be suitable for the navigation of large vehicles (sea, air, or land) that do not require accurate navigation at sea, air, or desert. Large-sized antennas with an area of tens of square meters to hundreds of square meters can be installed in such vehicles. [ABSTRACT FROM AUTHOR]

Published

2023

26. Statistical Properties of Pulsars with the Gigahertz-Peaked Spectra.

Author

Li, Jinyi, Cai, Hongbing, Chen, Li, and Wang, Beibei

Subjects

*INTERSTELLAR medium, *FREQUENCY spectra, *MAGNETIC fields, *PULSARS

Abstract

Pulsars with the Gigahertz-Peaked Spectra (GPS) are named GPS pulsars, which means that spectra of the pulsars in the radio band turn over near 1 GHz. These pulsars are also called high-frequency inversion spectra pulsars. There are total 33 GPS pulsars discovered so far. The reason causing the turned-over spectra may be due to the free–free absorption of radio emission by the interstellar medium. We carry out the statistical research on the peak frequencies of inversion spectra, spectral indices, dispersion measure, and magnetic fields of these GPS pulsars. We find that the peak frequencies of most GPS pulsars are mainly in 0.5–1.0 GHz, the spectral indices of these GPS pulsars seems to have a bimodal distribution, which means that these GPS pulsars are possibly composed by two types of pulsars. A strong positive correlation between the periods and dispersion measure (DM) of GPS pulsars is first found. [ABSTRACT FROM AUTHOR]

Published

2023

27. Cosmic baby and the detection of a new compact star – the "Triaxial Star": a possibility.

Author

Parui, Ramen Kumar

Subjects

*COMPACT objects (Astronomy), *MAGNETARS, *NOVAE (Astronomy), *MAGNETIC dipoles, *MAGNETIC fields, *MAGNETIC cores

Abstract

The "Triaxial Star", first proposed by S. Chandrasekhar in 1969, has not yet been detected. The recently detected Cosmic Baby, i.e., Swift J1818.0-1607 is the youngest magnetar observed so far. Its characteristic age is ∼300 years, with a superfast spin period ∼1.36 s and a strong surface dipole magnetic field ∼ 3 × 10 14 G . Considering the three facts in the interior of the magnetar core: i) the ambipolar diffusion, ii) negligible field decay as long as the core temperature is a few times 10 8 K and iii) the strong coupling between internal magnetic field decay and cooling in the early phase we estimate the ellipticity (ϵ ) and the core magnetic field ( B internal ) of this newly born magnetar are ∼ 9 × 10 − 3 and 8.9424 × 10 17 G , respectively. Based on our estimated result we suggest Swift J1818.0-1607 is a triaxial magnetar, i.e., simply a Triaxial Star. We discuss the significance of our result and encourage the GW community to search the triaxial stars through electromagnetic counterparts during their observation. [ABSTRACT FROM AUTHOR]

Published

2023

28. Detection of Two New RRATs at 111 MHz.

Author

Samodurov, V. A., Tyul'bashev, S. A., Toropov, M. O., Dolgushev, A. V., Oreshko, V. V., and Logvinenko, S. V.

Subjects

*RADIO telescopes, *PULSARS, *DATA analysis

Abstract

At the LPA LPI radio telescope, a search was conducted for pulse signals in a specific area with declinations . The processing involved ten months of observations recorded in six frequency channels, each with a channel width of 415 kHz and a total bandwidth of 2.5 MHz. The analysis of the data revealed 22 000 events, exhibiting a pronounced dispersion delay of signals over the frequency channels, which are indicative of pulsar pulses. These pulses were found to belong to four known pulsars and two new rotating radio transients (RRAT). Additional pulse search was carried out in 32-channel data with a channel width of 78 kHz. This led to the discovery of 8 pulses for the transient J0249+52 and 7 pulses for the transient J0744+55. No periodic emission of transients was detected. The analysis of the observations indicates a high probability that the identified RRATs are pulsars with nullings, where the fraction of nullings is greater than 99.9%. [ABSTRACT FROM AUTHOR]

Published

2023

29. Introduction: What Is Radio Astronomy?

Author

Lauterbach, Thomas and Lauterbach, Thomas

Published

2022

30. MeerKAT discovery of 13 new pulsars in Omega Centauri.

Author

Chen, W, Freire, P C C, Ridolfi, A, Barr, E D, Stappers, B, Kramer, M, Possenti, A, Ransom, S M, Levin, L, Breton, R P, Burgay, M, Camilo, F, Buchner, S, Champion, D J, Abbate, F, Venkatraman Krishnan, V, Padmanabh, P V, Gautam, T, Vleeschower, L, and Geyer, M

Subjects

*PULSARS, *GLOBULAR clusters, *BINARY pulsars, *STELLAR populations, *MEERKAT, *RADIO telescopes

Abstract

The most massive globular cluster in our Galaxy, Omega Centauri, is an interesting target for pulsar searches, because of its multiple stellar populations and the intriguing possibility that it was once the nucleus of a galaxy that was absorbed into the Milky Way. The recent discoveries of pulsars in this globular cluster and their association with known X-ray sources was a hint that, given the large number of known X-ray sources, there is a much larger undiscovered pulsar population. We used the superior sensitivity of the MeerKAT radio telescope to search for pulsars in Omega Centauri. In this paper, we present some of the first results of this survey, including the discovery of 13 new pulsars; the total number of known pulsars in this cluster currently stands at 18. At least half of them are in binary systems and preliminary orbital constraints suggest that most of the binaries have light companions. We also discuss the ratio between isolated and binaries pulsars, and how they were formed in this cluster. [ABSTRACT FROM AUTHOR]

Published

2023

31. Pulsar

Author

Prantzos, Nikos, Gargaud, Muriel, editor, Irvine, William M., editor, Amils, Ricardo, editor, Claeys, Philippe, editor, Cleaves, Henderson James, editor, Gerin, Maryvonne, editor, Rouan, Daniel, editor, Spohn, Tilman, editor, Tirard, Stéphane, editor, and Viso, Michel, editor

Published

2023

32. High-performance computing for SKA transient search: Use of FPGA-based accelerators.

Author

Aafreen, R., Abhishek, R., Ajithkumar, B., Vaidyanathan, Arunkumar M., Barve, Indrajit V., Bhattramakki, Sahana, Bhat, Shashank, Girish, B. S., Ghalame, Atul, Gupta, Y., Hayatnagarkar, Harshal G., Kamini, P. A., Karastergiou, A., Levin, L., Madhavi, S., Mekhala, M., Mickaliger, M., Mugundhan, V., Naidu, Arun, and Oppermann, J.

Subjects

*REAL-time computing, *RADIO telescopes, *TECHNOLOGICAL innovations, *ELECTRIC transients, *ANTENNAS (Electronics), *PULSARS, PULSAR detection

Abstract

This paper presents high-performance computing efforts with FPGA for the accelerated pulsar/transient search for the square kilometre array (SKA). Case studies are presented from within SKA and pathfinder telescopes highlighting future opportunities. It reviews the scenario that has shifted from offline processing of the radio telescope data to digitizing several hundreds/thousands of antenna outputs over huge bandwidths, forming several hundreds of beams, and processing the data in the SKA real-time pulsar search pipelines. A brief account of the different architectures of the accelerators, primarily, the new generation field programmable gate array-based accelerators, showing their critical roles to achieve high-performance computing and in handling the enormous data volume problems of the SKA is presented here. It also presents power-performance efficiency of this emerging technology and presents potential future scenarios. [ABSTRACT FROM AUTHOR]

Published

2023

33. Search for Pulsars in an Area with Coordinates 3h < α < 4h and +21° < δ < +42°.

Author

Tyul'bashev, S. A. and Tyul'basheva, G. E.

Subjects

*POWER spectra, *ACTINIC flux, *PULSARS, *ANTENNAS (Electronics), PULSAR detection

Abstract

The search for pulsars outside the plane of the galaxy in an area of 300 sq. deg. was carried out with the LPA LPI antenna at 111 MHz, with a sensitivity 5 to 10 times better than that of previous surveys. The search was performed in the summed power spectra. With an accumulation time equivalent to 100 hours of continuous observations for each point of the area, 5 known pulsars were found with a signal-to-noise ratio (S/N) from 20 to 1300 in the first harmonic of the spectrum. Average profiles are obtained for the detected pulsars. Estimates are given for the peak and integrated flux densities of the found pulsars for individual sessions and for power spectra summed over 5.5 years, using the developed method based on measurements of harmonic heights in the power spectrum. No new pulsars were found in the area. Apparently, when searching for pulsars in the area, we approached the lower limit of the luminosity of second pulsars. The survey completeness is at the level of 0.5 mJy. [ABSTRACT FROM AUTHOR]

Published

2023

34. Spun-Up Rotation-Powered Magnetized White Dwarfs in Close Binaries as Possible Gamma-ray Sources: Signatures of Pulsed Modulation from AE Aquarii and AR Scorpii in Fermi-LAT Data.

Author

Meintjes, Pieter J., Madzime, Spencer T., Kaplan, Quinton, and van Heerden, Hendrik J.

Subjects

PAIR production, RELATIVISTIC electrons, STELLAR magnetic fields, PARTICLE acceleration, PARTICLE accelerators, MAGNETOSPHERE, HADRONIC atoms, MEERKAT

Abstract

In this paper, the possibility of periodic pulsar-like gamma-ray emission from the white dwarfs in AE Aquarii and AR Scorpii is investigated. We show that the white dwarf magnetospheres in AE Aquarii and AR Scorpii can possibly induce potentials to accelerate charged particles to energies in excess of one tera electronvolt (TeV) with associated gamma-ray emission through processes such as curvature radiation, inverse Compton, and hadronic processes such as neutral pion decay. We report here pulsed gamma-ray signatures at or close to the spin period of white dwarfs in both AE Aquarii and AR Scorpii in the Fermi-LAT dataset. This may indicate that both these white dwarfs possibly contain a particle accelerator that can produce relativistic electrons and ions and associated high energy radiation. The possibility of pair production is also investigated, which could provide a source for relativistic e ± pairs in the magnetosphere. This could possibly be a driver for other forms of lepton-induced multi-wavelength pulsar-like emission from these two systems as well, for example, to explain the recently detected pulsed radio emission from AE Aquarii and R Scorpii in MeerKAT observations at the spin period of the white dwarf. The possibility of future detection of AE Aquarii and AR Scorpii with the Cherenkov Telescope Array (CTA) is also discussed. The future Vera Rubin Observatory will make a revolutionary contribution to time-domain astrophysics, which may lead to the discovery of thousands of new transient sources, possibly also many more close binaries with highly spun-up magnetized white dwarfs such as AE Aquarii and AR Scorpii for future investigation. [ABSTRACT FROM AUTHOR]

Published

2023

35. Neutron star versus neutral star: On the 90th anniversary of Landau's publication in astrophysics.

Author

Xu, Renxin

Subjects

*ASTROPHYSICS, *COMPACT objects (Astronomy), *QUANTUM theory, *DARK matter, *ASTRONOMY, *NUCLEAR astrophysics

Abstract

In the late age of developing quantum mechanics, Lev Landau made great efforts to understand the nature of matter, even stellar matter, by applying the quantum theory. Ninety years ago, he published his idea of "neutron" star, which burst upon him during his visit over Europe in the previous year. The key point that motivated Landau to write the paper is to make a state with lower energy for "gigantic nucleus", avoiding extremely high kinematic energy of electron due to the new Fermi–Dirac statistics at that time. Landau had no alternative but to neutralize by "combining a proton and an electron" before the discovery of neutron. However, our understanding of the nature has fundamentally improved today, and another way (strangeonization) could also embody neutralization and thus a low‐energy state that Landau had in mind, which could further make unprecedented opportunities in this multi‐messenger era of astronomy. Strangeon matter in "old" physics may impact dramatically today's physics, from compact stars initiated by Landau, to cosmic rays and dark matter. In this essay, we are making briefly the origin and development of neutron star concept to reform radically, to remember Landau's substantial contribution to astrophysics and to recall those peculiar memories. [ABSTRACT FROM AUTHOR]

Published

2023

36. Quasiperiodic and chaotic behaviours in time evolution of pulsar spin.

Author

Deruni, Berc and Dogan, Mustafa

Abstract

In this article, dynamical behaviour of pulsar spin-down is analysed with the presence of time-dependent external torques. The model incorporates nonlinear superfluidity of the core of pulsar. The spin-down rate of the crust becomes perturbed whenever a glitch occurs. An abrupt increase appears in the pulsar spin-down rate for a short period of time. Although there are several mechanisms proposed to understand those glitches, the exact mechanism is still unknown. The fluctuations in pulsar spin-down cannot be predicted either from time series analysis or governing equations for rotational dynamics. Long-term irregularities in pulsar spin-down give clues about some spiking activity or intermittency in the governing dynamics, which immediately enforce one to think about chaotic dynamics that may this trigger glitch behaviour. With this motivation behind, we modified an existing model known as vortex creep model to figure out the stochasticity in the dynamics of the system. The new model exhibits very interesting dynamical features. First of all, it is able to demonstrate glitch-like behaviour for suitable parameters. With the applied modification in the equations of motion, the system is showing different dynamical regimes from periodicity to quasiperiodicity and also chaotic dynamics become obvious for special parameter settings. The rich dynamical feature of the system is shown with the aid of nonlinear tools such as phase portraits, bifurcation diagrams, Lyapunov exponents and Poincaré sections. [ABSTRACT FROM AUTHOR]

Published

2022

37. The specifics of pulsar radio emission

Author

Losovsky Boris Ya.

Subjects

pulsar, giant pulses, scattering time scale, dispersion measure, braking index glitches, gamma-ray flares, Astronomy, QB1-991

Abstract

A characteristic property of pulsars is pulsed periodic radio emission, which has a high stability of periods. Despite the high stability of the emission periods of pulsars, monitoring the time of arrival of pulses (timing) shows the presence of different types of irregularities: variations of residual deviations, changes in the shape of the pulse, switching on and off of radio emission, and rotation discontinuities. Numerous observations of the radio emission of pulsars indicate that they are caused mainly by processes occurring in the pulsar’s magnetosphere. The special interest causes the observations of a pulsar in the Crab Nebula, performed, in particular, at Jodrell Bank and Pushchino Radio Astronomy Observatory of Lebedev Physical Institute. The connection between the scattering of radio pulses and the measure of the pulsar dispersion, which was established earlier in Pushchino together with Jodrell Bank, has been confirmed. The observed variations in the scattering of radio pulses and their partial correlation with the dispersion measure are explained by the eclipse of the pulsar by plasma clouds with electron density fluctuations significantly exceeding the corresponding fluctuations in the interstellar medium. The question of a possible connection between glitches, dispersion measure variations, radio pulses scattering, and gamma-ray flares is discussed.

Published

2022

38. Spin Equilibrium of Rapidly Spinning Neutron Stars via Transient Accretion

Author

Sudip Bhattacharyya

Subjects

accretion, neutron star, pulsar, rotation, spin equilibrium, X-ray binary, Astronomy, QB1-991

Abstract

The concept of spin equilibrium due to an interaction between the stellar magnetosphere and a thin, Keplerian accretion disk, and a well-known formula of the corresponding equilibrium spin frequency, provide a key understanding of spin evolution and the distribution of rapidly spinning neutron stars, viz., millisecond pulsars. However, this concept and formula are for stable accretion, but the mass transfer to most accreting millisecond pulsars is transient and the accretion rate evolves by orders of magnitude during an outburst. In this short and focussed review, we briefly discuss a relatively new concept of the spin equilibrium condition and a new formula for the equilibrium spin frequency for transiently accreting millisecond pulsars. We also review a new method to estimate this equilibrium spin frequency for observed transiently accreting millisecond pulsars, even when a pulsar has not yet attained the spin equilibrium. These will be crucial to probe the spin evolution and distribution of millisecond pulsars, and should also be applicable to all magnetic stars transiently accreting via a thin, Keplerian accretion disk.

Published

2023

39. Observations of Magnetar SGR J1830–0645 and Pulsar J0250+5854 at 111 MHz.

Author

Losovsky, B. Ya. and Glushak, A. P.

Subjects

*ACTINIC flux, *PHASED array antennas, *RADIO control, *ASTRONOMICAL observatories, *RADIO astronomy

Abstract

Search observations of radio signals from the new magnetar SGR J1830–0645 have been carried out since January 2021 and up to the present at the Pushchino Radio Astronomy Observatory of the Lebedev Physics Institute of Russian Academy of Sciences (PRAO LPI) at a frequency of 111 MHz with the Large Phased Array (LPA). According to results of processing observations for 2021, periodic or pulsed radio signals were not detected. The upper limit for estimating the radio flux density of SGR J1830–0645 at 111 MHz is 500 mJy. The 23.5 s radio pulsar J0250+5854 was used as a control radio source. Its flux density at 111 MHz was measured to be 9.6 ± 1.6 mJy. We performed pulse timing, measured and calculated the parameters of J0250+5854. [ABSTRACT FROM AUTHOR]

Published

2022

40. The Evolving Interplay of SBRT and the Immune System, along with Future Directions in the Field.

Author

Miljanic, Mihailo, Montalvo, Steven, Aliru, Maureen, Song, Tidie, Leon-Camarena, Maria, Innella, Kevin, Vujovic, Dragan, Komaki, Ritsuko, and Iyengar, Puneeth

Subjects

*COMPUTERS in medicine, *IMMUNE checkpoint inhibitors, *IMMUNE system, *RADIATION doses, *RADIOSURGERY, *TUMORS, *TUMOR antigens, *RADIOTHERAPY, *IMMUNOTHERAPY, *DEXTRAN

Published

2022

41. PULSAR Effect: Revealing potential synergies in combined radiation therapy and immunotherapy via differential equations.

Author

Rouf S, Moore C, Saha D, Nguyen D, Bleile M, Timmerman R, Peng H, and Jiang S

Abstract

PULSAR (personalized ultrafractionated stereotactic adaptive radiotherapy) is a form of radiotherapy method where a patient is given a large dose or "pulse" of radiation a couple of weeks apart rather than daily small doses. The tumor response is then monitored to determine when the subsequent pulse should be given. Pre-clinical trials have shown better tumor response in mice that received immunotherapy along with pulses spaced 10 days apart. However, this was not the case when the pulses were 1 or 4 days apart. Therefore, a synergistic effect between immunotherapy and PULSAR is observed when the pulses are spaced out by a certain number of days. In our study, we aimed to develop a mathematical model that can capture the synergistic effect by considering a time-dependent weight function that takes into account the spacing between pulses. We determined feasible parameters by fitting murine tumor volume data of six treatment groups via simulated annealing algorithm. Applying these parameters to the model we simulated 4000 trials with varying sequencing of pulses. These simulations indicated that if pulses were spaced apart by at least 9 days the tumor volume was about 200 mm 3 to 250 mm 3 smaller when treated with PULSAR combined with immunotherapy. We successfully demonstrate that our model is simple to implement and can generate tumor volume data that is consistent with the pre-clinical trial data. Our model has the potential to aid in the development of clinical trials of PULSAR therapy., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

42. Gamma-ray pulsar halos in the Galaxy

Author

Kun Fang

Subjects

cosmic rays, cosmic ray propagation, supernova remnants, pulsar, pulsar wind nebulae, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

Pulsar halos are extended gamma-ray structures generated by electrons and positrons escaping from pulsar wind nebulae (PWNe), considered a new class of gamma-ray sources. They are ideal indicators for cosmic-ray propagation in localized regions of the Galaxy and particle escape process from PWNe. The cosmic-ray diffusion coefficient inferred from pulsar halos is more than two orders of magnitude smaller than the average value in the Galaxy, which has been arousing extensive discussion. We review the recent advances in the study of pulsar halos, including the characteristics of this class of sources, the known pulsar halos, the possible mechanisms of the extremely slow diffusion, the critical roles of pulsar halos in the studies of cosmic-ray propagation and electron injection from PWNe, and the implications on the problems of the cosmic positron excess and the diffuse TeV gamma-ray excess. Finally, we give prospects for the study in this direction based on the expectation of a larger sample of pulsar halos and deeper observations for bright sources.

Published

2022

43. Investigation of Accuracy of TOA and SNR of Radio Pulsar Signals for Vehicles Navigation

Author

Hristo Kabakchiev, Vera Behar, Dorina Kabakchieva, Valentin Kisimov, and Kamelia Stefanova

Subjects

pulsar, radar, GPS, signal processing, navigation, Chemical technology, TP1-1185

Abstract

It is known that X-ray and gamma-ray pulsars can only be observed by spacecraft because signals from these pulsars are impossible to be detected on the Earth’s surface due to their strong absorption by the Earth’s atmosphere. The article is devoted to the theoretical aspects regarding the development of an autonomous radio navigation system for transport with a small receiving antenna, using radio signals from pulsars, similar to navigation systems for space navigation. Like GNSS systems (X-ray and radio), they use signals from four suitable pulsars to position the object. These radio pulsars (out of 50) are not uniformly distributed but are grouped in certain directions (at least 6 clusters can be determined). When using small antennas (with an area of up to tens of square meters) for pulsar navigation, the energy of the pulsar signals received within a few minutes is extremely insufficient to obtain the required level of SNR at the output of the receiver to form TOA estimation, ensuring positioning accuracy up to tens of kilometers. This is one of the scientific tasks that is solved in the paper by studying the relationship between the SNR of the receiver output, which depends on the size of the antenna, the type of signal processing, and the magnitude of the TOA accuracy estimate. The second scientific task that is solved in the paper is the adaptation of all the possible approaches and algorithms suggested in the statistical theory of radars in the suggested signal algorithm for antenna processing and to evaluate the parameters of the TOA and DS pulsar signals, in order to increase the SNR ratio at the receiver output, while preserving the dimensions of the antenna. In this paper, the functional structure of signal processing in a pulsar transport navigation system is proposed, and the choice of the observed second and millisecond pulsars for obtaining a more accurate TOA estimate is discussed. The proposed estimates of positioning accuracy (TOA only, no phase) in an autonomous pulsar vehicle navigation system would only be suitable for the navigation of large vehicles (sea, air, or land) that do not require accurate navigation at sea, air, or desert. Large-sized antennas with an area of tens of square meters to hundreds of square meters can be installed in such vehicles.

Published

2023

44. The physics of pulsar halos: Research progress and prospect.

Subjects

*PULSARS, *INTERSTELLAR medium, *PHYSICS, *COSMIC rays, *GALACTIC halos, *POSITRONS

Abstract

Diffusive TeV gamma-ray emissions have been recently discovered extending beyond the pulsar wind nebulae of a few middle-aged pulsars, implying that energetic electron/ positron pairs are escaping from the pulsar wind nebulae and radiating in the ambient interstellar medium. It has been suggested that these extended emissions constitute a distinct class of nonthermal sources, termed "pulsar halos". In this paper, I will review the research progress on pulsar halos and discuss our current understanding on their physics, including the multiwavelength observations, different theoretical models, as well as implications for the origin of cosmic-ray positron excess and Galactic diffuse gamma-ray emission. [ABSTRACT FROM AUTHOR]

Published

2022

45. Pulsar Candidate Recognition Using Deep Neural Network Model.

Author

Yin, Qian, Wang, Yan, Zheng, Xin, and Zhang, Jikai

Subjects

ARTIFICIAL neural networks, FEEDFORWARD neural networks, PULSARS, RADIO telescopes, AUTOREGRESSIVE models

Abstract

With an improvement in the performance of radio telescopes, the number of pulsar candidates has increased rapidly, which makes selecting valuable pulsar signals from the candidates challenging. It is imperative to improve the recognition efficiency of pulsars. Therefore, we solved this problem from the perspective of intelligent image processing and a deep neural network model AR_Net was proposed in this paper. A single time–phase-subgraph or frequency-phase-subgraph was used as the judgment basis in the recognition model. The convolution blocks can be obtained by combining the attention mechanism module, feature extractor and residual connection. Then, different convolution blocks were superimposed to constitute the AR_Net to screen pulsars. The attention mechanism module was used to calculate the weight through an additional feedforward neural network and the important features in the sample were identified by weight, so the ability of the model to learn pivotal information was improved. The feature extractor was used to gain the high-dimensional features in the samples and the residual connection was introduced to alleviate the problem of network degradation and intensify feature reuse. The experimental results show that AR_Net has higher F1-score, recall and accuracy, and our method produces a competitive result compared with previous methods. [ABSTRACT FROM AUTHOR]

Published

2022

46. TOWARDS A UNIFIED FRAMEWORK IN TREATING IMBALANCED DATASETS. APPLICATION TO THE PULSAR CANDIDATE SELECTION PROBLEM BASED ON THE HTRU2 DATASET. PART II: OVERSAMPLING VERSUS UNDERSAMPLING - A CRITICAL COMPARISON.

Author

Diaconu, Bogdan, Anghelescu, Lucica, Cruceru, Mihai, and Popa, Marius-Eremia Vlaicu

Subjects

RANDOM forest algorithms, SAMPLING methods, LOGISTIC regression analysis, PULSARS

Abstract

This paper will discuss several methods of dealing with unbalanced datasets with application to High Time Resolution Universe Survey dataset. HTRU2 is a labelled dataset with a ratio of positive to negative instances of approximately 0.1. Under sampling and oversampling methods are discussed and tested and the results are compared. It was found that Synthetic Minority Oversampling Technique provides the best performance, assessed by means of the ROC-AUC parameter. Further improvement is expected by combining oversampling and under sampling. [ABSTRACT FROM AUTHOR]

Published

2022

47. TOWARDS A UNIFIED FRAMEWORK IN TREATING IMBALANCED DATASETS. APPLICATION TO THE PULSAR CANDIDATE SELECTION PROBLEM BASED ON THE HTRU2 DATASET. PART I – PULSAR CANDIDATE SELECTION PROBLEM.

Author

Diaconu, Bogdan, Anghelescu, Lucica, Cruceru, Mihai, and Popa, Marius-Eremia Vlaicu

Subjects

PULSARS, GRAVITATIONAL waves

Abstract

Pulsars are a class of astronomic objects that emit periodic radiation pulses with a highly stable frequency. Each pulsar has its’ own, unique emission pattern (frequency and waveform); for this reason, pulsars can be used as beacons for navigation. However, the real importance of the pulsars is their emission can be used to detect gravitational waves. Therefore, there is a high interest to identify and map new pulsars. Identifying new pulsars consists in discrimination between radio emission from genuine pulsars and from sources that are not pulsars. It is a difficult task due to the large number of spurious signals both from space and from terrestrial sources. This two-part paper will present several approaches to deal with an imbalanced labelled pulsar candidate dataset HTRU2, consisting of eight features (statistical parameters) derived from the radio spectrum. [ABSTRACT FROM AUTHOR]

Published

2022

48. Fast radio bursts at the dawn of the 2020s.

Author

Petroff, E., Hessels, J. W. T., and Lorimer, D. R.

Subjects

*TWENTY twenties, *MAGNETARS, *GLOBULAR clusters, *GALAXIES, *INFORMATION resources, *RADIO astronomy

Abstract

Since the discovery of the first fast radio burst (FRB) in 2007, and their confirmation as an abundant extragalactic population in 2013, the study of these sources has expanded at an incredible rate. In our 2019 review on the subject, we presented a growing, but still mysterious, population of FRBs—60 unique sources, 2 repeating FRBs, and only 1 identified host galaxy. However, in only a few short years, new observations and discoveries have given us a wealth of information about these sources. The total FRB population now stands at over 600 published sources, 24 repeaters, and 19 host galaxies. Higher time resolution data, sustained monitoring, and precision localisations have given us insight into repeaters, host galaxies, burst morphology, source activity, progenitor models, and the use of FRBs as cosmological probes. The recent detection of a bright FRB-like burst from the Galactic magnetar SGR 1935 + 2154 provides an important link between FRBs and magnetars. There also continue to be surprising discoveries, like periodic modulation of activity from repeaters and the localisation of one FRB source to a relatively nearby globular cluster associated with the M81 galaxy. In this review, we summarise the exciting observational results from the past few years. We also highlight their impact on our understanding of the FRB population and proposed progenitor models. We build on the introduction to FRBs in our earlier review, update our readers on recent results, and discuss interesting avenues for exploration as the field enters a new regime where hundreds to thousands of new FRBs will be discovered and reported each year. [ABSTRACT FROM AUTHOR]

Published

2022

49. Adaboost-DSNN: an adaptive boosting algorithm based on deep self normalized neural network for pulsar identification.

Author

Tariq, Irfan, Meng, Qiao, Yao, Shunyu, Liu, Wei, Zhou, Chenye, Ahmed, Adnan, and Spanakis-Misirlis, Apostolos

Subjects

*BOOSTING algorithms, *PULSARS, *SELF, PULSAR detection

Abstract

A modern pulsar survey generates a large number of pulsar candidates. Filtering these pulsar candidates in a large astronomical data set is an important step towards discovering new pulsars. In this paper, a novel adaptive boosting algorithm based on deep self normalized neural network (Adaboost-DSNN) is proposed to accurately classify pulsar and non-pulsar signals. To train the proposed method on a highly imbalanced data set, the Synthetic Minority Oversampling TEchnique (SMOTE) was initially employed for balancing the data set. Then, a deep ensemble network combined with a deep self-normalized neural network and adaptive boosting was developed to train and learn the processed pulsar data. The design of the proposed Adaboost-DSNN method significantly reduced the computational time when dealing with large astronomical data sets, while also improving the classification performance. The scaled exponential liner units activation function was used to normalize the data. Considering their neighbour information and the special dropout technique (α-dropout), Adaboost-DSNN displayed good pulsar classification performance, while preserving the data properties across subsequent layers. The proposed Adaboost-DSNN method was tested on the High Time Resolution Universe Survey data sets (HTRU-1 and HTRU-2). According to experimental results, Adaboost-DSNN outperform other state-of-the-art methods with respect to training time and F1-score. The training time of the Adaboost-DSNN model is 10x times faster compared to other models of this kind. [ABSTRACT FROM AUTHOR]

Published

2022

50. Coronal Density Measurements Using Giant Radio Pulses of the Crab Pulsar at the Cycle 24/25 Minimum.

Author

Tokumaru, Munetoshi, Maeda, Ryuya, Tawara, Kaito, Takefuji, Kazuhiro, and Terasawa, Toshio

Subjects

*SOLAR wind, *SOLAR cycle, *PLASMA density, *CRABS, *RADIO telescopes, *PULSARS, *SOLAR corona, *DENSITY

Abstract

Accurate measurements of the coronal plasma density profile, which varies with the solar cycle (SC), are necessary to elucidate the solar wind acceleration. In this study, the Crab pulsar is observed using the 327 MHz radio telescope at the Toyokawa Observatory of the Institute for Space-Earth Environmental Research of Nagoya University to investigate the coronal plasma density profile for radial distances between 5 and 60 solar radii at the SC24/25 minimum. We derive the dispersion measures (DMs) that represent the integration of plasma density along the line of sight (LOS) for giant radio pulses of the Crab pulsar. We find that the observed DMs increased above the interstellar background level when the LOS for the Crab pulsar approached the Sun in mid-June 2018 and 2019. This increase in DM is attributed to the effect of the coronal plasma. We determine the plasma density distribution by fitting a spherically symmetric model to the observed DM data. The flat radial slopes of the best-fit model are consistent with pulsar observations in the low-activity periods of past SCs, and they are attributed to the effect of the coronal hole over the south pole of the Sun. Our results show that the density level near the Sun is similar to those observed in the low activity periods of past SCs, implying recovery of the coronal plasma density from a significant reduction at the SC23/24 minimum. [ABSTRACT FROM AUTHOR]

Published

2022