cluster photoemission
DESCRIPTION
Cluster photoemission. [email protected] Aug 24, 2011. Photoemission. Essential for EFW as the coupling of probes to plasma is mainly through photoemission The bias current applied to the probes is carried to the plasma mainly by photoemission - PowerPoint PPT PresentationTRANSCRIPT
Photoemission
• Essential for EFW as the coupling of probes to plasma is mainly through photoemission
• The bias current applied to the probes is carried to the plasma mainly by photoemission
• Photoemission determines the density-s/c potential relation useful for estimating n in tenuous plasmas
This presentation
• Study of photoemission 2003-2006• Recent low photoemission on SC2
Cluster EFW instruments
EFW: Electric Fields and Waves instrumentFour probes on 44 m wire booms on all four Cluster s/c
Double-probe instrument, measures E from
Bonus data products:- Spacecraft potential, Vsc (continuous, 5 Hz)- Photoemission current from bias voltage sweeps (semi-hourly)
EFW bias voltage sweeps
BV V RI Usually runs every four hours on every probe ~105 sweeps available, year 2000 - ...
Green line: fitted photoelectron saturation current
TIMED/SEE UV measurements
• TIMED: Sun-synchronous at 625 km
• SEE - Solar Extreme Ultraviolet Experiment
• UV spectra 0.5 nm – 194 nm
• 1 nm bins• ~2 hour intervals• 2003 - ...
• UV flux F(,t)• Photoemission
saturation current I(t)
• Photoelectron yield A()
• • formally possible
to derive material property A(): compare Cluster I(t) to TIMED F(,t)
dtFAtI ),()()(
• Method: non-negative least-squares fit.• Result: unphysical spikes -- method is sensitive to
data errors and noise.• Solar cycle & annual trends OK, solar rotation
variations higher in UV data than in Iph
Calculated yield
Can we find eph yield in space? ~No
Do lab-determined yields fit? ~Yes
• EFW: Al probes coated with DAG 213
• Lab yield curve for DAG gives too low current
• Lab yield curve for Al gives good fit post-2003 if increased by 10%
• Suggests DAG weared off in space
• Too high predicted currents in 2003 cannot be explained by wear (as DAG has lower yield than Al)
• DAG: Feuerbacher & Fitton, J. Appl. Phys., 1972• Al: Samson & Cairns, Rev. Sci. Instr., 1965
n(Vsc) relation I: Fundamentals
• Currents to spacecraft:– Ie ~ n: collected plasma e-,
scales with density n– Iph(Vsc): photoemission
• Saturation for Vsc < 0
• Decays for Vsc > 0
– Ii: negligible ion current
– Current balance Ie + Iph = 0 Vsc = f(n) relation
• Vsc a proxy for the densityEmpirical relation: EFW Vsc vs. plasma density from Cluster CIS ion spectrometer: 1.1 million data points (spins) from Feb-March 2003,
2004 & 2005
n(Vsc) relation II: Depends on UV
n-Vsc curve clearly varies with solar cycle
[Pedersen et al, JGR 2008]
n(Vsc) relation III: Correct for UV
• Photoemission current Iph(Vsc) depends on UV flux
• relation n = g(Vsc) depends on UV flux
• Should be improved if corrected for UV variations
• Possibilities:– Photoemission current from
sweeps– UV flux from TIMED– F10.7 UV proxy Same data as before, but density now normalized
to the photoemission current derived from adjacent sweeps, thus removing UV variations.
Spread appears less - true?
n(Vsc) relation IV: Improved? Yes!
Does UV variation compensation really improve the use of Vsc as a density proxy?
Compare empirical relations of Vsc(t) to (<> is time average):
Raw density n(t) from CIS
n(t) <F10.7>/F10.7(t)
n(t) <Iph>/Iph(t)
Quality quantified by the root mean square deviation (standard deviation) from a line least-squares fitted to the log-log plots
Resulting RMS deviations:
= 0.99 for raw density data
= 0.87 for F10.7 correction
= 0.81 for sweep photoemission correction
Recent photoemission drop on SC2SC2 has recently had much lower perigee than others
Reached 200 km in early June
Severe photoemission drop on SC2
Photocurrent determined from Vb sweepsSuggest zero (or even wrong sign!) of photoemission
This contrasts to the fact that we do see saturation of the E-field signal only part of the time with -20 nA bias current
Suggests real photosaturation current is something like 20-30 nA
Why do the Vb sweeps not agree with Ib operation?
Difference is ~50 nA
Corresponds to a 50 nA * 5 Mohm = 250 mV offset (to negative) somewhere in the Vb mode
Vb sweeps underestimating Iph0 (compared to Ib) consistent with previous observations
Anyway, we seem to have a drop by approx a factor 10
ISEE-1 saw a drop by a factor 3-4 when going down to 500 km
Very consistent with our data
No recovery signature yet
Data up to early August
Colour codes time:Blue = MarchRed = August
ISEE-1 saw recovery
If our probes were pure Al before, are they Al oxide now?
Langmuir mode data suggest 90 nA
Data up to early August
Colour codes time:Blue = MarchRed = August
ISEE-1 saw recovery
If our probes were pure Al before, are they Al oxide now?
The photoemission current determined from Cluster EFW probe bias sweeps correlate well but not perfectly with UV flux measurements from TIMED SEE
An attempt to derive the photoelectron yield curve of the EFW probes by non-negative least squares fitting failed
Laboratory yield for the original probe coating (DAG) only gives 50% of the photoemission, while pure Al fits within 10% -- has the coating all worn off?
The use of spacecraft potential as a proxy for plasma density is improved by correcting for UV flux variations, preferably from sweeps
SC2 photoemission dropped by a factor 10 when perigee reached 200 km
Consistent with ISEE-1 drop of factor 3-4 at 500 km
Photosaturation currents from Ib and Vb operations not consistent
Conclusions