Figure 2a Plasma stability Hsp33
Applied Microbiology
- The cold atmospheric pressure plasma-generated species superoxide, singlet oxygen and atomic oxygen activate the molecular chaperone Hsp33
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1026 results
Figure 1a Survival Rates
Applied Microbiology
- The cold atmospheric pressure plasma-generated species superoxide, singlet oxygen and atomic oxygen activate the molecular chaperone Hsp33
Figure 3b CD spectra Hsp33
Applied Microbiology
- The cold atmospheric pressure plasma-generated species superoxide, singlet oxygen and atomic oxygen activate the molecular chaperone Hsp33
Figure 4a Hsp33 Carbonylation
Applied Microbiology
- The cold atmospheric pressure plasma-generated species superoxide, singlet oxygen and atomic oxygen activate the molecular chaperone Hsp33
Figure 6b bubble radius evolution pos. pol.
EP2
- Ignition and propagation of nanosecond pulsed plasmas in distilled water - negative vs. positive polarity applied to a pin electrode
Figure 9b spectra analysis neg. pol.
EP2
- Ignition and propagation of nanosecond pulsed plasmas in distilled water - negative vs. positive polarity applied to a pin electrode
Figure 9a spectra analysis pos. pol.
EP2
- Ignition and propagation of nanosecond pulsed plasmas in distilled water - negative vs. positive polarity applied to a pin electrode
Figure 8b emission spectra neg. pol.
EP2
- Ignition and propagation of nanosecond pulsed plasmas in distilled water - negative vs. positive polarity applied to a pin electrode
Figure 8a emission spectra pos. pol.
EP2
- Ignition and propagation of nanosecond pulsed plasmas in distilled water - negative vs. positive polarity applied to a pin electrode
Figure 6b bubble radius evolution pos. pol.
EP2
- Ignition and propagation of nanosecond pulsed plasmas in distilled water - negative vs. positive polarity applied to a pin electrode