Alexander Pazur scite author profile

This article reviews phenomena of magnetoreception in plants and provides a survey of the relevant literature over the past 80 years. Plants react in a multitude of ways to geomagnetic fields-strong continuous fields as well as alternating magnetic fields. In the past, physiological investigations were pursued in a somewhat unsystematic manner and no biological advantage of any magnetoresponse is immediately obvious. As a result, most studies remain largely on a phenomenological level and are in general characterised by a lack of mechanistic insight, despite the fact that physics provides several theories that serve as paradigms for magnetoreception. Beside ferrimagnetism, which is well proved for bacterial magnetotaxis and for some cases of animal navigation, two further mechanisms for magnetoreception are currently receiving major attention: (1) the "radical-pair mechanism" consisting of the modulation of singlet-triplet interconversion rates of a radical pair by weak magnetic fields, and (2) the "ion cyclotron resonance" mechanism. The latter mechanism centres around the fact that ions should circulate in a plane perpendicular to an external magnetic field with their Lamor frequencies, which can interfere with an alternating electromagnetic field. Both mechanisms provide a theoretical framework for future model-guided investigations in the realm of plant magnetoreception.

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Magnetoreception in microorganisms and fungi

Pazur

Schimek

Galland

2007

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The ability to respond to magnetic fields is ubiquitous among the five kingdoms of organisms. Apart from the mechanisms that are at work in bacterial magnetotaxis, none of the innumerable magnetobiological effects are as yet completely understood in terms of their underlying physical principles. Physical theories on magnetoreception, which draw on classical electrodynamics as well as on quantum electrodynamics, have greatly advanced during the past twenty years, and provide a basis for biological experimentation. This review places major emphasis on theories, and magnetobiological effects that occur in response to weak and moderate magnetic fields, and that are not related to magnetotaxis and magnetosomes. While knowledge relating to bacterial magnetotaxis has advanced considerably during the past 27 years, the biology of other magnetic effects has remained largely on a phenomenological level, a fact that is partly due to a lack of model organisms and model responses; and in great part also to the circumstance that the biological community at large takes little notice of the field, and in particular of the available physical theories. We review the known magnetobiological effects for bacteria, protists and fungi, and try to show how the variegated empirical material could be approached in the framework of the available physical models.

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Transient effect of weak electromagnetic fields on calcium ion concentration in Arabidopsis thaliana

Pazur

Rassadina

2009

BMC Plant Biol

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Background: Weak magnetic and electromagnetic fields can influence physiological processes in animals, plants and microorganisms, but the underlying way of perception is poorly understood. The ion cyclotron resonance is one of the discussed mechanisms, predicting biological effects for definite frequencies and intensities of electromagnetic fields possibly by affecting the physiological availability of small ions. Above all an influence on Calcium, which is crucial for many life processes, is in the focus of interest. We show that in Arabidopsis thaliana, changes in Ca 2+ -concentrations can be induced by combinations of magnetic and electromagnetic fields that match Ca 2+ -ion cyclotron resonance conditions.

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Magnetic effect on CO₂ solubility in seawater: A possible link between geomagnetic field variations and climate

Pazur

Winklhofer

2008

Geophysical Research Letters

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[1] Correlations between geomagnetic-field and climate parameters have been suggested repeatedly, but possible links are controversially discussed. Here we test if weak (Earth-strength) magnetic fields can affect climatically relevant properties of seawater. We found the solubility of air in seawater to be by 15% lower under reduced magneticfield (20 mT) compared to normal field conditions (50 mT). The magnetic-field effect on CO 2 solubility is twice as large, from which we surmise that geomagnetic field variations modulate the carbon exchange between atmosphere and ocean. A 1% reduction in magnetic dipole moment may release up to ten times more CO 2 from the surface ocean than is emitted by subaerial volcanism. This figure is dwarfed in front of anthropogenic CO 2 emissions.

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Calcium ion cyclotron resonance in dissipative water structures

Pazur¹

2018

Electromagnetic Biology and Medicine

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Weak magnetic and electromagnetic fields affect physiological processes in animals, plants, and microorganisms. Ion cyclotron resonance (ICR) is discussed as one of the sensitive mechanisms, which enable perception of the geomagnetic field and its orientation. Numerous biological effects are observed involving several small ions, showing windows of predicted frequencies and intensities. The pioneering work of Guiliano Preparata and Emilio Del Giudice using quantum electrodynamics showed that spontaneously originating coherent regions in water facilitate ICR effects at incoherent water phase boundaries. Here we examine the ICR response of the calcium ion (Ca), crucial for many life processes. We use an aqueous solution containing the biologically ubiquitous membrane lipid L-α-phosphatidylcholine that serves as a biomimetic proxy for dynamic light scattering (DLS) and nonlinear dielectric spectroscopy (NLDS) measurements. One notable result is that this system approaches a new equilibrium upon addition of calcium by means of the oscillatory Belousov-Zhabotinsky chemical reaction, oscillations are significantly reduced under Ca ICR application. Secondly an "oscillator" of calcium ions appears to be able to itself couple coherently and predictably to large-scale coherent regions in water. This system appears able to regulate ion fluxes in response to very weak environmental electromagnetic fields.

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Alexander Pazur

Magnetoreception in plants

Magnetoreception in microorganisms and fungi

Transient effect of weak electromagnetic fields on calcium ion concentration in Arabidopsis thaliana

Magnetic effect on CO₂ solubility in seawater: A possible link between geomagnetic field variations and climate

Calcium ion cyclotron resonance in dissipative water structures

Contact Info

Product

Resources

About

Alexander Pazur

Magnetoreception in plants

Magnetoreception in microorganisms and fungi

Transient effect of weak electromagnetic fields on calcium ion concentration in Arabidopsis thaliana

Magnetic effect on CO2 solubility in seawater: A possible link between geomagnetic field variations and climate

Calcium ion cyclotron resonance in dissipative water structures

Contact Info

Product

Resources

About

Magnetic effect on CO₂ solubility in seawater: A possible link between geomagnetic field variations and climate