Month: September 2022

WEAK SIGNAL. “It is very challenging to sense magnetic fields as weak as that of the Earth using only biologically available materials. Only two basic mechanisms are considered theoretically viable in terrestrial animals: iron-mineral-based magnetoreception and radical-pair based magnetoreception.” https://lnkd.in/eUbuD-a View in LinkedIn

TWO MECHANISMS. “On the basis of current scientific evidence, iron-mineral-based magnetoreception and radical-pair-based magnetoreception mechanisms seem to exist in birds, but they seem to be used for different purposes.” https://lnkd.in/eUbuD-a View in LinkedIn

CHEMICAL SPIN. “These properties of the avian magnetic compass remained enigmatic until the Radical Pair Model provided a possible explanation. The model, described in detail by Ritz et al. proposes that the avian magnetic compass is based on spin-chemical processes in specialized photopigments.” http://rsif.royalsocietypublishing.org/content/12/103/20141103.full View in LinkedIn

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RADICAL PAIR. “When the Radical Pair Model was put forward, applying radio-frequency magnetic fields in the MHz range was suggested as a diagnostic tool. The respective experiments supported the model: adding such fields to the geomagnetic field disrupted magnetic compass orientation in several species of birds.” http://rsif.royalsocietypublishing.org/content/12/103/20141103.full View in LinkedIn

MULTIFACTORIAL. “One thing is for sure; the natural map sense of birds is multifactorial. It relies on input from olfaction and vision and possibly also from magnetic sensing and maybe even from hearing. Pigeons with opaque lenses that prevented them from detecting any local visual landmarks can return to within c. 5 km of their loft.” https://lnkd.in/eUbuD-a View in LinkedIn

SUBTLE SIGNAL. “The problem for a bird wanting to use a magnetic map is that the average change in magnetic field intensity is only c. 3 nT/km on the North-South axis: The geomagnetic field changes c. 30,000 nT from one of the magnetic poles to the magnetic equator, which are c. 10,000km apart. Likewise, magnetic inclination changes only c. 0.009°/km along the North-South axis (a 90° change over 10,000km).” https://lnkd.in/eUbuD-a View in LinkedIn

BACKGROUND NOISE. “Thus, any magnetic-field-based input to a reasonably precise map would require a very accurate magnetic sensory system and a very accurate sense of gravity. However, even if birds have such a system, daily, partly stochastic, natural variations in the geomagnetic field on the order of 30–100nT in more or less random directions mean that it is very difficult to imagine how a magnetic-field-based map sense could have a precision less than 10–30km (during magnetic storms generated primarily by the Sun, the geomagnetic field variability can reach 1000 nT.” https://lnkd.in/eUbuD-a View in LinkedIn

UNSOLVED. “Many studies have documented the presence of magnetite or some other kind of iron mineral crystals in almost any animal...However, the mere existence of iron mineral crystals or even magnetite does not represent significant evidence by itself that such structures have any relevance to magnetoreception.” https://lnkd.in/eUbuD-a View in LinkedIn

MAGNETIC CHAINS. “Single domain magnetite particles similar to those found in the magnetosome of magnetotactic bacteria have been observed from the olfactory tissues in a number of fish, including species of tuna, salmon and trout. Early studies used SQUID to describe the magnetic properties of frozen samples and revealed the presence of 40–100 nm-sized SD magnetite particles arranged in chains.” https://lnkd.in/eAwwGJ4 View in LinkedIn