Precise nuclear physics for the sun

Bemmerer, Daniel

January 2012

For many centuries, the study of the Sun has been an important testbed for understanding stars that are further away. One of the first astronomical observations Galileo Galilei made in 1612 with the newly invented telescope concerned the sunspots, and in 1814, Joseph von Fraunhofer employed his new spectroscope to discover the absorption lines in the solar spectrum that are now named after him. Even though more refined and new modes of observation are now available than in the days of Galileo and Fraunhofer, the study of the Sun is still high on the agenda of contemporary science, due to three guiding interests. The first is connected to the ages-old human striving to understand the structure of the larger world surrounding us. Modern telescopes, some of them even based outside the Earth’s atmosphere in space, have succeeded in observing astronomical objects that are billions of lightyears away. However, for practical reasons precision data that are important for understanding stars can still only be gained from the Sun. In a sense, the observations of far-away astronomical objects thus call for a more precise study of the closeby, of the Sun, for their interpretation. The second interest stems from the human desire to understand the essence of the world, in particular the elementary particles of which it consists. Large accelerators have been constructed to produce and collide these particles. However, man-made machines can never be as luminous as the Sun when it comes to producing particles. Solar neutrinos have thus served not only as an astronomical tool to understand the Sun’s inner workings, but their behavior on the way from the Sun to the Earth is also being studied with the aim to understand their nature and interactions. The third interest is strictly connected to life on Earth. A multitude of research has shown that even relatively slight changes in the Earth’s climate may strongly affect the living conditions in a number of densely populated areas, mainly near the ocean shore and in arid regions. Thus, great effort is expended on the study of greenhouse gases in the Earth’s atmosphere. Also the Sun, via the solar irradiance and via the effects of the so-called solar wind of magnetic particles on the Earth’s atmosphere, may affect the climate. There is no proof linking solar effects to short-term changes in the Earth’s climate. However, such effects cannot be excluded, either, making it necessary to study the Sun. The experiments summarized in the present work contribute to the present-day study of our Sun by repeating, in the laboratory, some of the nuclear processes that take place in the core of the Sun. They aim to improve the precision of the nuclear cross section data that lay the foundation of the model of the nuclear reactions generating energy and producing neutrinos in the Sun. In order to reach this goal, low-energy nuclear physics experiments are performed. Wherever possible, the data are taken in a low-background, underground environment. There is only one underground accelerator facility in the world, the Laboratory Underground for Nuclear Astrophysics (LUNA) 0.4MV accelerator in the Gran Sasso laboratory in Italy. Much of the research described here is based on experiments at LUNA. Background and feasibility studies shown here lay the base for future, higher-energy underground accelerators. Finally, it is shown that such a device can even be placed in a shallow-underground facility such as the Dresden Felsenkeller without great loss of sensitivity.

info:eu-repo/classification/ddc/539

ddc:539

Quiet Sun Magnetic Fields / Magnetische Felder auf der ruhigen Sonne

Domínguez Cerdeña, Itahiza Francisco

14 July 2004

No description available.

520 Astronomie

Mathematics and Computer Science

Sonne

Photosphäre

Magnetfeld

Granulation

Spektropolarimetrie

Specklerekonstruktion

sun

photosphere

magnetic field

granulation

spectropolarimetry

speckle reconstruction

39.51

TGC100

TGC745

TGC800

Equatorial Coronal Holes and Their Relation to the High-Speed Solar Wind Streams / Äquatoriale Koronalöcher und ihr Zusammenhang mit schnellen Sonnenwindströmen

Xia, Lidong

22 May 2003

No description available.

530 Physik

Mathematics and Computer Science

Sonne

Sonnenwind

Koronaloch

UV-Strahlung

Magnetfeld

SUMER

SOHO

Sun

solar wind

coronal hole

UV radiation

magnetic field

SUMER

SOHO

39.51

TGC 740: Sonnenatmosphäre

Struktur und Ursprung starker Magnetfelder am Boden der solaren Konvektionszone / Structure and origin of strong magnetic field at the base of the solar convection zone

Rempel, Matthias Dieter

25 June 2001

No description available.

530 Physik

Mathematics and Computer Science

Sonnenfleckenzyklus

Magnetohydrodynamik

magnetische Flussröhren

Dynamotheorie

solar cycle

magnetohydrodynamics

magnetic flux tubes

dynamo theory

39.51

TGC 500: Sonnenaktivität {Astronomie}

Magnetic Activity at the Poles of the Sun / Magnetische Aktivitaet an den Polen der Sonne

Blanco Rodriguez, Julian

19 February 2008

No description available.

520 Astronomie

Mathematics and Computer Science

Sonne

Photosphäre

Magnetfeld

Spektroskopie

Polarimetrie

Specklerekonstruktion

polaren Fackeln

Sun

photosphere

magnetic field

spectroscopy

polarimetry

speckle reconstruction

polar faculae

39.51

TGC100

TGC540

TGC800

TGC740

Analysis of short-period waves in the solar chromosphere / Analyse von kurzperiodischen Wellen in der Chromosphaere der Sonne

Andic, Aleksandra

06 July 2005

No description available.

520 Astronomie

Mathematics and Computer Science

Kurzperiodische akustische Wellen

die Heizung der Sonnenchromosphaere

short-period acoustic waves

heating of the solar chromosphere

39.51

Precise nuclear physics for the Sun

Bemmerer, Daniel

03 December 2012

For many centuries, the study of the Sun has been an important testbed for understanding stars that are further away. One of the first astronomical observations Galileo Galilei made in 1612 with the newly invented telescope concerned the sunspots, and in 1814, Joseph von Fraunhofer employed his new spectroscope to discover the absorption lines in the solar spectrum that are now named after him. Even though more refined and new modes of observation are now available than in the days of Galileo and Fraunhofer, the study of the Sun is still high on the agenda of contemporary science, due to three guiding interests. The first is connected to the ages-old human striving to understand the structure of the larger world surrounding us. Modern telescopes, some of them even based outside the Earth’s atmosphere in space, have succeeded in observing astronomical objects that are billions of light- years away. However, for practical reasons precision data that are important for understanding stars can still only be gained from the Sun. In a sense, the observations of far-away astronomical objects thus call for a more precise study of the closeby, of the Sun, for their interpretation. The second interest stems from the human desire to understand the essence of the world, in particular the elementary particles of which it consists. Large accelerators have been constructed to produce and collide these particles. However, man-made machines can never be as luminous as the Sun when it comes to producing particles. Solar neutrinos have thus served not only as an astronomical tool to understand the Sun’s inner workings, but their behavior on the way from the Sun to the Earth is also being studied with the aim to understand their nature and interactions. The third interest is strictly connected to life on Earth. A multitude of research has shown that even relatively slight changes in the Earth’s climate may strongly affect the living conditions in a number of densely populated areas, mainly near the ocean shore and in arid regions. Thus, great effort is expended on the study of greenhouse gases in the Earth’s atmosphere. Also the Sun, via the solar irradiance and via the effects of the so-called solar wind of magnetic particles on the Earth’s atmosphere, may affect the climate. There is no proof linking solar effects to short-term changes in the Earth’s climate. However, such effects cannot be excluded, either, making it necessary to study the Sun. The experiments summarized in the present work contribute to the present-day study of our Sun by repeating, in the laboratory, some of the nuclear processes that take place in the core of the Sun. They aim to improve the precision of the nuclear cross section data that lay the foundation of the model of the nuclear reactions generating energy and producing neutrinos in the Sun. In order to reach this goal, low-energy nuclear physics experiments are performed. Wherever possible, the data are taken in a low-background, underground environment. There is only one underground accelerator facility in the world, the Laboratory Underground for Nuclear Astro- physics (LUNA) 0.4 MV accelerator in the Gran Sasso laboratory in Italy. Much of the research described here is based on experiments at LUNA. Background and feasibility studies shown here lay the base for future, higher-energy underground accelerators. Finally, it is shown that such a device can even be placed in a shallow-underground facility such as the Dresden Felsenkeller without great loss of sensitivity.

Nukleare Astrophysik

LUNA

Felsenkeller

Wasserstoffbrennen in der Sonne

Bethe-Weizsäcker-Zyklus

Proton-Proton-Kette

Nuclear Astrophysics

LUNA

Felsenkeller

hydrogen burning in the Sun

solar fusion

CNO cycle

pp chain

ddc:530

ddc:539

rvk:US 6200

Struktur und Dynamik kleinskaliger Magnetfelder der Sonnenatmosphäre / Ergebnisse hochaufgelöster Polarimetrie und Bildrekonstruktion / Structure and Dynamics of small scale magnetic fields in the solar atmosphere / Results of high resolution polarimetry and image reconstruction

Janßen, Katja

02 July 2003

No description available.

530 Physik

Mathematics and Computer Science

Sonne

Photosphäre

Magnetfeld

Spektroskopie

Polarimetrie

fraktale Dimension

Heizung

Specklerekonstruktion

sun

photosphere

magnetic field

spectroscopy

polarimetry

fractal dimension

heating

speckle reconstruction

39.51

TGC100

TGC540

TGC800

Observations and modeling of polar faculae on the Sun / Beobachtungen und numerische Simulationen polarer Fackeln der Sonne.

Okunev, Oleg

16 September 2004

No description available.

520 Astronomie

Mathematics and Computer Science

Sonne

Photosphäre

Magnetfeld

Spektroskopie

Polarimetrie

Specklerekonstruktion

Strahlungstransport

polaren Fackeln

sun

photosphere

magnetic field

spectroscopy

polarimetry

speckle reconstruction

radiative transfer

polar faculae

39.51

TGC100

TGC540

TGC800

TGC740

Precise nuclear physics for the Sun

Bemmerer, Daniel

25 June 2012

For many centuries, the study of the Sun has been an important testbed for understanding stars that are further away. One of the first astronomical observations Galileo Galilei made in 1612 with the newly invented telescope concerned the sunspots, and in 1814, Joseph von Fraunhofer employed his new spectroscope to discover the absorption lines in the solar spectrum that are now named after him. Even though more refined and new modes of observation are now available than in the days of Galileo and Fraunhofer, the study of the Sun is still high on the agenda of contemporary science, due to three guiding interests. The first is connected to the ages-old human striving to understand the structure of the larger world surrounding us. Modern telescopes, some of them even based outside the Earth’s atmosphere in space, have succeeded in observing astronomical objects that are billions of light- years away. However, for practical reasons precision data that are important for understanding stars can still only be gained from the Sun. In a sense, the observations of far-away astronomical objects thus call for a more precise study of the closeby, of the Sun, for their interpretation. The second interest stems from the human desire to understand the essence of the world, in particular the elementary particles of which it consists. Large accelerators have been constructed to produce and collide these particles. However, man-made machines can never be as luminous as the Sun when it comes to producing particles. Solar neutrinos have thus served not only as an astronomical tool to understand the Sun’s inner workings, but their behavior on the way from the Sun to the Earth is also being studied with the aim to understand their nature and interactions. The third interest is strictly connected to life on Earth. A multitude of research has shown that even relatively slight changes in the Earth’s climate may strongly affect the living conditions in a number of densely populated areas, mainly near the ocean shore and in arid regions. Thus, great effort is expended on the study of greenhouse gases in the Earth’s atmosphere. Also the Sun, via the solar irradiance and via the effects of the so-called solar wind of magnetic particles on the Earth’s atmosphere, may affect the climate. There is no proof linking solar effects to short-term changes in the Earth’s climate. However, such effects cannot be excluded, either, making it necessary to study the Sun. The experiments summarized in the present work contribute to the present-day study of our Sun by repeating, in the laboratory, some of the nuclear processes that take place in the core of the Sun. They aim to improve the precision of the nuclear cross section data that lay the foundation of the model of the nuclear reactions generating energy and producing neutrinos in the Sun. In order to reach this goal, low-energy nuclear physics experiments are performed. Wherever possible, the data are taken in a low-background, underground environment. There is only one underground accelerator facility in the world, the Laboratory Underground for Nuclear Astro- physics (LUNA) 0.4 MV accelerator in the Gran Sasso laboratory in Italy. Much of the research described here is based on experiments at LUNA. Background and feasibility studies shown here lay the base for future, higher-energy underground accelerators. Finally, it is shown that such a device can even be placed in a shallow-underground facility such as the Dresden Felsenkeller without great loss of sensitivity.

info:eu-repo/classification/ddc/530

ddc:530

info:eu-repo/classification/ddc/539

ddc:539