Post on 20-Jan-2016
Balloelectric genesisof intermediate
ions(a synopsis)
Hannes Tammet,Urmas Hõrrak, Kaupo Komsaare, Markku Kulmala
CHRONOLOGY
1744: Richmann – air conductivity
1785: Coulomb – rediscovery of air conductivity
1834: Faraday – term ion
1840: Faraday – explanation of Seghill incident
1892: Lenard – studies of balloelectric effect1896: Thomson & Rutherford – mobility
1899: Elster & Geitel – atmospheric small ions
1905: Langevin – large ions
1913: Christiansen – term balloelectric effect
1915: Pollock – intermediate ions
1937: Chapman – mobility of balloelectric ions
1973: Siksna – water clathrates
1999: Chaplin – water superclusters
Annalen der Physik 1892
Lenard, P. (1915) Über Wasserfallelektrizität und über die Oberflächenbeschaffenheit der Flüssigkeiten. Annalen der Physik 47, 463–524.
Philipp Eduard Antonvon Lénárd,
a Magyar from Bratislava,Nobel Prize 1905
Previous work by the authors
of the presentation
Experimental study of the “rain effect” on the mobility distribution of air ions.
Experiments with water jet.
U. Hõrrak, H. Tammet, E.Tamm, A. Mirme.
Institute of Environmental Physics, University of Tartu,
18 Ülikooli St., 50090 Tartu, Estonia.
E-mail: Urmas.Horrak@ut.ee
Pikajärve, June 27–29. 2005
Hõrrak, U., Tammet, H., Aalto, P.P., Vana, M., Hirsikko, A., Laakso, L., Kulmala, M. (2006) Formation of Charged Nanometer Aerosol Particles Associated with Rainfall: Atmospheric Measurements and Lab Experiment. In Report Series in Aerosol Science, Helsinki, 81, 180-185.
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Size of the Size of the balloelectric ionsballoelectric ionsH. Tammet, U. Hõrrak, M. Kulmala
Pühajärve 2008
2009
Raintime bursts of intermediate
ions
Tartu, Tähe 4 attic storey and roof
0369
12
0 3 6 9 12 15 18 21 24
Tem
pera
ture
N
ois
e
85
90
95
100
RH
%
Precipitation
A rainy day in Tartu, April 2004
A rainy day in Hyytiälä, 6 December 2006.Air temperature +5.0…+8.5 ºC and RH 83…96% during the day.
0
250
500
750
1000
1250
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9Mobility, cm2V-1s-1
dn /
d(lo
g d)
, cm
-3>= 3 mm/h
2.0–2.9 mm/h
1.0–1.9 mm/h
0.1–0.9 mm/h
Average mobility distribution of negative atmospheric ions during the rain of different intensity in Hyytiälä.
Diameter = f (charge, mobility)
THE PROBLEM:
singly or multiply charged particles?
We can measure the mobility.How to estimate the size?
0
0.25
0.5
0.75
1
1 10 100 1000 10000
Droplet diameter, nm
Ele
ctric
mob
ility
, cm
2 V-1
s-1Rayleigh limit charge
Half of theRayleigh limit
Single charge
Mobility of a typical balloelectric ion
Singly charged particles: The concentration decreases, but the mobility does not change.
Multiply charged particles: The number concentration does not change, the mobility and the charge concentration decrease proportionally to each other.
Idea of the neutralization experiment:
0
50
100
150
200
250
300
350
400
450
500
550
600
0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5 0.55 0.6 0.65Mobility, cm2V-1s-1
Fra
ctio
n co
ncen
trat
ion
cm-3
REPEATED MEASUREMENTSAT FOUR LEVELSOF NEUTRALIZATION
0
500
1000
1500
2000
2500
3000
3500
4000
4500
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9Mobility, cm2V-1s-1
Dis
trib
utio
n of
cha
rge
conc
entr
atio
n
n+ = 810
n+ = 3320
n+ = 5770
n+ = 9700
Old particles are neutralized and do not affect this curve
Large mobility → small size
Old particles are waned due to the
evaporation
Small ions
dn /d (log Z)cm-3
Results of experiments: mobility decreases a little, far from the proportionality
Concentration of neutralizing small ions, cm-3
Conclusion:
The balloelectric ions are mostly the singly charged nanometer particles and
diameter = f (1 e, mobility)
Composition: water
or dry residueof a droplet?
The rainwater contains about 10 mg/l ofTDS (total dissolved solids).
The waterworks water used in the experiments contains 550 mg/l of TDS.
Conclusion: the dry residues of the waterworks water droplets should have 3-4 times bigger diameters when compared with the dry residues of the rainwater droplets.
Let’s compare…
Comparison of measurements at Hyytiälä SMEAR station (left)
and results of the experiment with water jet (right)
Size distributions of negative ions
0 .4 0 .6 0 .8 1 1 .2 1 .6 2 3 4 5 6 7 8
Mass d iam eter (n m )
Neg ative ion s. Au g u st 23, 2003.
0
100
200
300
400
500
600
Fraction concentration (cm
-3)
16 :17 16 :22 16 :27 16 :32 16 :38 16 :43 16 :48
0 .4 0 .6 0 .8 1 1 .2 1 .6 2 3 4 5 6 7 8
Mass d iam eter (n m )
Neg ative ion s. May 12, 2005.
0
100
200
300
400
500
600
Fraction concentration (cm
-3)
12 :45 12 :55 13 :05 13 :15 wa te r 13 :25 wa te r 13 :35 wa te r 13 :45 13 :55 14 :05
Rain event. Hyytiälä Laboratory water-jet. Tartu
0
500
1000
1500
2000
2500
3000
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9Mobility, cm2V-1s-1
dn /
d(lo
g d)
, cm
-3
Blue – natural rain at Hyytiälä, green – natural rain at Tartu, red – laboratory experiment splashing the waterworks water
Conclusion:
The size of balloelectric ions does not depend on the TDS and they cannot be considered as dry residues of droplets.
How the balloelectric
ions are created ?
Critical point: the surface tension requires a lot of energy to be saved in the surface of nanodroplets, where is the source?
The speed of large raindrops is 6-7 m/s. If 100% of the kinetic energy is to be transformed into the surface energy then the required speed is:
Dispersion of a raindrop fully into nanodrops seems to be impossible. However, the law of energy balance cannot exlude creating of a limited number of nanodrops. The nanometer scale processes during the splashing are hard to study and the mechanism of creating the nanodrops is almost unknown.
d : nm 10 100 1000 10000
v : m/s 290 90 29 9
Nobel prize winner 2002 John B. Fenn studied generating of ions of dissolved substances.
(ESI = electrospray ionization)
Wide field of ESI applications motivated research of Coulomb dispersion of droplets. Indeed, the fragments can be very small. However, they are
MULTIPLY CHARGED
Why they are not instantly evaporated ?
The characteristic evaporation time of 2.5 nm liquid water droplets at 10ºC and 100% relative humidity does not exceed 1 μs according to the kinetic theory. This time is about 7 magnitudes less than the estimated time of passage of the air to the instrument and 5 magnitudes less than the time of passage of the air through the analyzer.
If these estimates were true then the observation of 2.5 nm droplets in the described measurements would be recognized as impossible.
WATER JET OPEN WATER JET CLOSED
fine + coarse +
coarse –
fine –
Conclusion:
The balloelectric ions are not composed of the liquid water. ICE CRYSTALS ?
CLUSTERS ?
Lenard 1915
n = 21d = 1.06Z = 0.96
SIZE OF A BALLOELECTRIC ION CORRESPONDS TO
200…300MOLECULES OF WATER
Chaplin’s superclusters?
Number of water molecules
n = (πρd3 / 6) / (18 u)
n 17.5 (d / 1 nm)3 n = 280 follows d = 2.52 nm.
The water clusters known in mass spectrometry have maximum n = 21. Chaplin did not use mass spectrometry and does not refer experts like Beyer, Kebarle, Keesee and Castleman.He studied clusters not in the gas but in the water environment.
Chaplin’s magic icosahedron has n = 20×14 = 280
LINKS
• http://www.lsbu.ac.uk/water
• http://www.waterjournal.org
• http://www.mdpi.com/journal/water
• http://water.sigmaxi.org/?page_id=39
the last site contains a list of more than 60
journals related to water and hydrology
Picturesfrom Chaplin’s web:
Stable supercluster
A superlcuster can break down during long time
0
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1000
1500
2000
2500
3000
1 10 100 1000 10000Number of water molecules
Mob
ility
fra
ctio
n co
ncen
trat
ions
cm
-3
A+
B+
C+
D+
A-
B-
C-
D-
Distribution of balloelectric ions according to the number of water moleculesA, B, C ja D are levels of neutralizing ionization in the laboratory experiment
Final conclusions:Nature of rain-induced intermediate ions seems to be the same as nature of balloelectric ions in laboratory and near waterfalls. We proved that the balloelectric ions are probably
1) singly charged nanoparticles,2) not dry residues of droplets,3) not composed of classic liquid water,4) of size the Chaplin's 280-superclusters.
We still don't know1) their actual composition,2) how they are created,3) why they are not instantly evaporated.
Thank you for attention !
? ? ? ? ? ? ?CONCLUSION CONCLUSION