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Krzysztof Maciesiak - One of the best experts on this subject based on the ideXlab platform.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
The Astrophysical Journal, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods (P) > 0.1 s, measured at the half-power point at 1 GHz, has a lower boundary line (LBL) that closely follows the P −0.5 scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies, the core, as well as the conal Component widths versus period, had a LBL that followed the P −0.5 relation with a similar lower boundary. The radio emission in normal pulsars has been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the P −0.5 relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the P −0.5 dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation that can explain the P −0.5 dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of a currently unexplained physical phenomenon.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
arXiv: High Energy Astrophysical Phenomena, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods ($P$) $>$ 0.1 seconds, measured at the half-power point at 1 GHz has a lower boundary line (LBL) which closely follows the $P^{-0.5}$ scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies the core as well as the conal Component widths versus period had a LBL which followed the $P^{-0.5}$ relation with a similar lower boundary. The radio emission in normal pulsars have been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the $P^{-0.5}$ relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the $P^{-0.5}$ dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation which can explain the $P^{-0.5}$ dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of an yet unexplained physical phenomenon.
Dipanjan Mitra - One of the best experts on this subject based on the ideXlab platform.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
The Astrophysical Journal, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods (P) > 0.1 s, measured at the half-power point at 1 GHz, has a lower boundary line (LBL) that closely follows the P −0.5 scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies, the core, as well as the conal Component widths versus period, had a LBL that followed the P −0.5 relation with a similar lower boundary. The radio emission in normal pulsars has been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the P −0.5 relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the P −0.5 dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation that can explain the P −0.5 dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of a currently unexplained physical phenomenon.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
arXiv: High Energy Astrophysical Phenomena, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods ($P$) $>$ 0.1 seconds, measured at the half-power point at 1 GHz has a lower boundary line (LBL) which closely follows the $P^{-0.5}$ scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies the core as well as the conal Component widths versus period had a LBL which followed the $P^{-0.5}$ relation with a similar lower boundary. The radio emission in normal pulsars have been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the $P^{-0.5}$ relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the $P^{-0.5}$ dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation which can explain the $P^{-0.5}$ dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of an yet unexplained physical phenomenon.
George I Melikidze - One of the best experts on this subject based on the ideXlab platform.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
The Astrophysical Journal, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods (P) > 0.1 s, measured at the half-power point at 1 GHz, has a lower boundary line (LBL) that closely follows the P −0.5 scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies, the core, as well as the conal Component widths versus period, had a LBL that followed the P −0.5 relation with a similar lower boundary. The radio emission in normal pulsars has been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the P −0.5 relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the P −0.5 dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation that can explain the P −0.5 dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of a currently unexplained physical phenomenon.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
arXiv: High Energy Astrophysical Phenomena, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods ($P$) $>$ 0.1 seconds, measured at the half-power point at 1 GHz has a lower boundary line (LBL) which closely follows the $P^{-0.5}$ scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies the core as well as the conal Component widths versus period had a LBL which followed the $P^{-0.5}$ relation with a similar lower boundary. The radio emission in normal pulsars have been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the $P^{-0.5}$ relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the $P^{-0.5}$ dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation which can explain the $P^{-0.5}$ dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of an yet unexplained physical phenomenon.
Rahul Basu - One of the best experts on this subject based on the ideXlab platform.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
The Astrophysical Journal, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods (P) > 0.1 s, measured at the half-power point at 1 GHz, has a lower boundary line (LBL) that closely follows the P −0.5 scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies, the core, as well as the conal Component widths versus period, had a LBL that followed the P −0.5 relation with a similar lower boundary. The radio emission in normal pulsars has been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the P −0.5 relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the P −0.5 dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation that can explain the P −0.5 dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of a currently unexplained physical phenomenon.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
arXiv: High Energy Astrophysical Phenomena, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods ($P$) $>$ 0.1 seconds, measured at the half-power point at 1 GHz has a lower boundary line (LBL) which closely follows the $P^{-0.5}$ scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies the core as well as the conal Component widths versus period had a LBL which followed the $P^{-0.5}$ relation with a similar lower boundary. The radio emission in normal pulsars have been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the $P^{-0.5}$ relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the $P^{-0.5}$ dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation which can explain the $P^{-0.5}$ dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of an yet unexplained physical phenomenon.
Anna Skrzypczak - One of the best experts on this subject based on the ideXlab platform.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
The Astrophysical Journal, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods (P) > 0.1 s, measured at the half-power point at 1 GHz, has a lower boundary line (LBL) that closely follows the P −0.5 scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies, the core, as well as the conal Component widths versus period, had a LBL that followed the P −0.5 relation with a similar lower boundary. The radio emission in normal pulsars has been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the P −0.5 relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the P −0.5 dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation that can explain the P −0.5 dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of a currently unexplained physical phenomenon.
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meterwavelength single pulse polarimetric emission survey iv the period dependence of Component widths of pulsars
arXiv: High Energy Astrophysical Phenomena, 2018Co-Authors: Anna Skrzypczak, Rahul Basu, Dipanjan Mitra, George I Melikidze, Krzysztof MaciesiakAbstract:The core Component width in normal pulsars, with periods ($P$) $>$ 0.1 seconds, measured at the half-power point at 1 GHz has a lower boundary line (LBL) which closely follows the $P^{-0.5}$ scaling relation. This result is of fundamental importance for understanding the emission process and requires extended studies over a wider frequency range. In this paper we have carried out a detailed study of the Profile Component widths of 123 normal pulsars observed in the Meterwavelength Single-pulse Polarimetric Emission Survey at 333 and 618 MHz. The Components in the pulse Profile were separated into core and conal classes. We found that at both frequencies the core as well as the conal Component widths versus period had a LBL which followed the $P^{-0.5}$ relation with a similar lower boundary. The radio emission in normal pulsars have been observationally shown to arise from a narrow range of heights around a few hundred kilometers above the stellar surface. In the past the $P^{-0.5}$ relation has been considered as evidence for emission arising from last open dipolar magnetic field lines. We show that the $P^{-0.5}$ dependence only holds if the trailing and leading half-power points of the Component are associated with the last open field line. In such a scenario we do not find any physical motivation which can explain the $P^{-0.5}$ dependence for both core and conal Components as evidence for dipolar geometry in normal pulsars. We believe the period dependence is a result of an yet unexplained physical phenomenon.