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Observation of dielectric universalities in albumin, cytochrome C and Shewanella oneidensis MR-1 extracellular matrix
KA. Motovilov, M. Savinov, ES. Zhukova, AA. Pronin, ZV. Gagkaeva, V. Grinenko, KV. Sidoruk, TA. Voeikova, PY. Barzilovich, AK. Grebenko, SV. Lisovskii, VI. Torgashev, P. Bednyakov, J. Pokorný, M. Dressel, BP. Gorshunov,
Jazyk angličtina Země Anglie, Velká Británie
Typ dokumentu časopisecké články
NLK
Directory of Open Access Journals
od 2011
Free Medical Journals
od 2011
Nature Open Access
od 2011-12-01
PubMed Central
od 2011
Europe PubMed Central
od 2011
ProQuest Central
od 2011-01-01
Open Access Digital Library
od 2011-01-01
Open Access Digital Library
od 2011-01-01
Health & Medicine (ProQuest)
od 2011-01-01
ROAD: Directory of Open Access Scholarly Resources
od 2011
Springer Nature OA/Free Journals
od 2011-12-01
- MeSH
- albuminy metabolismus MeSH
- cytochromy c metabolismus MeSH
- elektrická vodivost MeSH
- elektřina * MeSH
- extracelulární matrix metabolismus MeSH
- Shewanella metabolismus MeSH
- skot MeSH
- spektrální analýza MeSH
- teplota MeSH
- voda chemie MeSH
- zvířata MeSH
- Check Tag
- skot MeSH
- zvířata MeSH
- Publikační typ
- časopisecké články MeSH
The electrodynamics of metals is well understood within the Drude conductivity model; properties of insulators and semiconductors are governed by a gap in the electronic states. But there is a great variety of disordered materials that do not fall in these categories and still respond to external field in an amazingly uniform manner. At radiofrequencies delocalized charges yield a frequency-independent conductivity σ 1(ν) whose magnitude exponentially decreases while cooling. With increasing frequency, dispersionless conductivity starts to reveal a power-law dependence σ 1(ν)∝ν s with s < 1 caused by hopping charge carriers. At low temperatures, such Universal Dielectric Response can cross over to another universal regime with nearly constant loss ε″∝σ1/ν = const. The powerful research potential based on such universalities is widely used in condensed matter physics. Here we study the broad-band (1-1012 Hz) dielectric response of Shewanella oneidensis MR-1 extracellular matrix, cytochrome C and serum albumin. Applying concepts of condensed matter physics, we identify transport mechanisms and a number of energy, time, frequency, spatial and temperature scales in these biological objects, which can provide us with deeper insight into the protein dynamics.
A M Prokhorov General Physics Institute RAS Moscow Russia
Institute for Metallic Materials IFW Dresden Dresden Germany
Institute of Physics AS CR Praha 8 Czech Republic
Moscow Institute of Physics and Technology Dolgoprudny Moscow Region Russia
Citace poskytuje Crossref.org
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- $a Motovilov, K A $u Moscow Institute of Physics and Technology, Dolgoprudny, Moscow Region, Russia. k.a.motovilov@gmail.com.
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- $a Observation of dielectric universalities in albumin, cytochrome C and Shewanella oneidensis MR-1 extracellular matrix / $c KA. Motovilov, M. Savinov, ES. Zhukova, AA. Pronin, ZV. Gagkaeva, V. Grinenko, KV. Sidoruk, TA. Voeikova, PY. Barzilovich, AK. Grebenko, SV. Lisovskii, VI. Torgashev, P. Bednyakov, J. Pokorný, M. Dressel, BP. Gorshunov,
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- $a The electrodynamics of metals is well understood within the Drude conductivity model; properties of insulators and semiconductors are governed by a gap in the electronic states. But there is a great variety of disordered materials that do not fall in these categories and still respond to external field in an amazingly uniform manner. At radiofrequencies delocalized charges yield a frequency-independent conductivity σ 1(ν) whose magnitude exponentially decreases while cooling. With increasing frequency, dispersionless conductivity starts to reveal a power-law dependence σ 1(ν)∝ν s with s < 1 caused by hopping charge carriers. At low temperatures, such Universal Dielectric Response can cross over to another universal regime with nearly constant loss ε″∝σ1/ν = const. The powerful research potential based on such universalities is widely used in condensed matter physics. Here we study the broad-band (1-1012 Hz) dielectric response of Shewanella oneidensis MR-1 extracellular matrix, cytochrome C and serum albumin. Applying concepts of condensed matter physics, we identify transport mechanisms and a number of energy, time, frequency, spatial and temperature scales in these biological objects, which can provide us with deeper insight into the protein dynamics.
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