Online Encyclopedia

Kelvin in the middle of the 19th century, and the greater definiteness thus introduced into observational results, were notable events. Towards the end of the 19th century came the See also:

DISCOVERY

discovery made by W. Linss (6)1 and by J. See also:

ELSTER

Elster and H. Geitel (7) that even the most perfectly insulated conductors lose their See also:

charge, and that this loss depends on atmospheric conditions. Hard on this came the recognition of the fact that freely charged See also:

POSITIVE (or PORTABLE) ORGAN

positive and negative ions are always See also:

PRESENT

present in the atmosphere, and that a radioactive See also:

EMANATION (Lat. emanatio, from e-, out, manare, to flow)

emanation can be collected. Whilst no small amount of observational See also:

WORK

work has been done in these new branches of atmospheric electricity, the See also:

SCIENCE (Lat. scientia, from scire; to learn, know)

science has still not See also:

DEVELOPED

developed to a considerable extent beyond preliminary stages. Observations have usually been limited to a portion of the See also:

YEAR

year, or to a few See also:

HOURS, CANONICAL

hours of the See also:

day, whilst the results from different stations differ much in details.

It is thus difficult to See also:

FORM (Lat. forma)

form a See also:

JUDGMENT

judgment as to what has most claim to See also:

ACCEPTANCE (Lat. acceptare, frequentative form of accipere, to receive)

acceptance as the See also:

general See also:

law, and what may be regarded as See also:

LOCAL

local or exceptional. 2. Potential Gradient.—In dry See also:

WEATHER (O. Eng. weder; the word is common to Teutonic languages; cf. Du. weder, Dan. veir, Icel. ve8r, and Ger. Wetter and Gewitter, storm; the root is wa- to blow, from which is derived " wind ")

weather the electric potential in the atmosphere is normally positive relative to the See also:

earth, and increases with the height. The existence of earth currents (q. v.) shows that the earth, strictly speaking, is not all at one potential, but the natural See also:

DIFFERENCES, CALCULUS OF (Theory of Finite Differences)

differences of potential between points on the earth's See also:

SURFACE

surface a mile apart are insignificant compared to the normal potential difference between the earth and a point one See also:

FOOT

foot above it. What is aimed at in See also:

ORDINARY (med. Lat. ordinarius, Fr. ordinaire)

ordinary observations of atmospheric potential is the measurement of the difference of potential between the earth and a point a given distance above it, or of the difference of potential betweeen two points in the same See also:

VERTICAL (from Lat. vertex, highest point)

vertical See also:

LINE

line a given distance apart. Let a conductor, say a metallic See also:

SPHERE (Gr. vclsa?pa, a ball or globe)

sphere, be supported by a See also:

metal See also:

rod of negligible electric capacity whose other end is earthed. As the whole conductor must be at zero (i.e. the earth's) potential, there must be an induced charge on the sphere, producing at its centre a potential equal but of opposite sign to what would exist at the, same spot in See also:

FREE

free See also:

air. This neglects any charge in the air 1 See Authorities below. displaced by the sphere, and assumes a statical See also:

state of conditions and that the conductor itself exerts no disturbing See also:

INFLUENCE (Late Lat. influentia, from influere, to flow in)

influence. Suppose now that the sphere's earth connexion is broken and that it is carried without loss of charge inside a See also:

BUILDING

building at zero potential. If its potential as observed there is -V (volts), then the potential of the air at the spot occupied by the sphere was +V. This method in one shape or another has been often employed.

Suppose next that a fixed insulated conductor is somehow kept at the potential of the air at a given point, then the measurement of its potential is See also:

EQUIVALENT

equivalent to a measurement of that of the air. This is the basis of a variety of methods. In the earliest the conductor was represented by See also:

long metal wires, supported by See also:

SILK

silk or other insulating material, and See also:

LEFT

left to pick up the air's potential. The addition of See also:

sharp points was a step in advance; but the method hardly became a quantitative one until the sharp points were replaced by a See also:

FLAME (Lat. flamma; the root flag- appears in flagrare, to burn, blaze, and Gr. d, XEryew)

flame (fuse, See also:

gas, See also:

LAMP (from Gr. Xag ras, a torch, Xaµaav, to shine)

lamp), or by a liquid See also:

JET (Fr. jais, Ger. Gagat)

jet breaking into drops. The See also:

MATTER

matter leaving the conductor, whether the products of See also:

COMBUSTION (from the Lat. comburere, to burn up)

combustion or the drops of a liquid, supplies the means of securing equality of potential between the conductor and the air at the spot where the matter quits See also:

electrical connexion with the conductor. Of See also:

LATE

late years the See also:

FUNCTION

function of the See also:

COLLECTOR

collector is discharged in some forms of apparatus by a See also:

salt of See also:

RADIUM (from Lat. radius, ray)

radium. Of flame collectors the two best known are Lord Kelvin's portable electrometer with a fuse, or F. Exner's See also:

gold See also:

LEAF (O. Eng. leaf, cf. Dutch loof, Ger. Laub, Swed. lof, &c.; possibly to be referred to the root seen in Gr. Ma-eta, to peel, strip)

leaf See also:

ELECTROSCOPE

electroscope in See also:

CONJUNCTION (from Lat. conjungere, to join together)

conjunction with an oil lamp or gas flame. Of liquid collectors the representative is Lord Kelvin's water-dropping electrograph; while Benndorf's is the form of radium collector that has been most used. It cannot be said that any one form of collector is See also:

SUPERIOR

superior all See also:

ROUND (O. Fr. rond, Lat. rotundus, the Fr. is the source also of Du. rond; Ger., Swed., Dan. and Nor. rond)

round. Flame collectors See also:

BLOW, JOHN (1648-1708)

blow out in high winds, whilst water-droppers are See also:

apt to get frozen in See also:

winter. At first sight the See also:

BALANCE (derived through the Fr. from the Late Lat. bilantia, an apparatus for weighing, from bi, two, and lanx, a dish or scale)

balance of advantages seems to See also:

lie with radium.

But while gaseous products and even falling water are capable of modifying electrical conditions in their immediate neighbourhood, the " infection " produced by radium is more insidious, and other drawbacks present them-selves in practice. It requires a radium salt of high See also:

RADIOACTIVITY

radioactivity to be at all comparable in effectiveness with a See also:

GOOD, JOHN MASON (1764-1827)

good water-dropper. Experralents by F. Zz.z e rirdcated That a water-dropper /are often too raprafto 6e sathfactorlfydealt with 6y an ordr"nary See also:

PLACE (through Fr. from Lat. platea, street; Gr. IrAar6s, wide)

Place and See also:

Period. See also:

Jan. Feb. See also:

March. See also:

APRIL

April. May. See also:

JUNE

June. See also:

JULY

July. Aug.

See also:

EBERT, FRIEDRICH ADOLF (1791-1834)

Ebert. In the potential curves of the diagram the ordinates represent the hourly values expressed—as in Tables II. and III.—as percentages of the mean value for the day. If this be overlooked, a wrong impression may be derived as to the absolute amplitudes of the changes. The Kew curves, for instance, might suggest that the range maximum less minimum hourly value) was larger in June than in December. In reality the December range was 82, the June only 57 volts; but the mean value of the potential was 243 in December as against I I1 in June. So again, in the case of the Paris curves, the absolute value of the diurnal range in summer was much greater for the Eiffel Tower than for the, Bureau Central, but the mean voltage was 2150 at the former station and only 134 at the latter. 8. See also:

Fourier Coefficients.—Diurnal inequalities such as those of Tables II. and III. and intended to eliminate irregular changes, but they also to some extent eliminate See also:

REGULAR

regular changes if the hours of maxima and minima or the character of the diurnal variation alter throughout the year. The alteration that takes place in the regular diurnal inequality throughout the year is best seen by analysing it into a Fourier See also:

SERIES (a Latin word from serere, to join)

series of the type cl See also:

sin (t+a,)+es sin (21+as)-1-cs sin (3t+as)+c4 sin (41+x4)+. where t denotes time counted from (local) midnight, c1, c2, c3, c4,. are the amplitudes of the component See also:

HARMONIC

harmonic waves of periods 24, 12, 8 and 6 hours; al, as, as, at, are the corresponding phase angles. One hour of time t is counted as 150, and a dela% of one hour in the time of maximum answers to a diminution of 15 in al, of 300 in as, and so on. If a1, say, varies much throughout the year, or if the ratios of c2, es, c4,... to ci, vary much, then a diurnal inequality derived from a whole year, or from a season composed of several months, represents a mean curve arising from the superposition of a number of curves, which differ in shape and in the positions of their maxima and minima.

The result, if considered alone, inevitably leads to an underestimate of the average See also:

AMPLITUDE (from Lat. amplus, large)

amplitude of the regular diurnal variation. It is also desirable to have an See also:

IDEA (Gr. Ibia, connected with i&eiv, to see; cf. Lat. species from specere, to look at)

idea of the See also:

SIZE

size of the irregular changes which vary from one day to the next. On stormy days, as already mentioned, the irregular changes hardly admit of satisfactory treatment. Even on the quietest days irregular changes are always numerous and often large. Table IV. aims at giving a See also:

SUMMARY

summary of the several phenomena for a single station, Kew, on electrically quiet days. The first line gives the mean value of the potential gradient, the second the mean excess of the largest over the smallest hourly value on individual days. The hourly values are derived from smoothed curves, the See also:

OBJECT

object being to get the mean See also:

ORDINATE

ordinate for a 6o-See also:

minute period. If the actual crests of the excursions had been measured the figures in the second line would have been even larger. The third line gives the range of the regular diurnal inequality, the next four lines the amplitudes of the first four Fourier waves into which the regular diurnal inequality has been analysed. These mean values, ranges• and amplitudes are all measured in volts per metre (in the open) The last four lines of Table IV. give the phase angles of the first four Fourier waves. It will be noticed that the difference between the greatest and least hourly values is, in all but three winter months, actually larger than the mean value of the potential gradient for the day; it bears to the range of the regular diurnal inequality a ratio varying from 2.0 in May to 3.6 in November. At midwinter the 24-hour See also:

TERM

term is the largest, but near midsummer it is small compared to the 12-hour term.

The 24-hour term is very variable both as regards its amplitude and its phase See also:

ANGLE (from the Lat. angulus, a corner, a diminutive, of which the primitive form, angus, does not occur in Latin; cognate are the Lat. angere, to compress into a bend or to strangle, and the Gr. ayKOS, a bend; both connected with the Aryan root ank-, to

angle (and so Jan. Feb. March. April. May. June. July. Aug. Sept. Oct. Nov. Dec.

Mean Potential Gradient . 201 224 18o 138 123 III 98 114 121 153 200 243 . Mean of individual daily ranges 203 218 210 164 143 132 117 129 141 196 186 213 Range in Diurnal inequality 73 94 83 74 71 57 55 6o 54 63 52 82 c1 22 22 17 13 18 9 6 6 9 7 14 30 G2 21 33 34 31 22 23 24 26 23 30 17 21 Amplitudes of Fourier waves cs 7 to 5 5 3 I 3 2 3 6 5 7 C4 2 3 5 6 4 I 4 3 4 3 2 3 0 0 0 0 0 0 0 0 0 0 0 0 a, 206 204 123 72 86 79 48 142 154 192 202 208 II as 170 171 x86 193 188 183 185 182 199 206 212 175 Phase angles of Fourier waves as I t 9 36 96 100 125 124 107 t6 I8 38 36 See also:

A4(Z)

a4 235 225 307 314 314 277 293 313 330 288 238 249 its hour of maximum). The 12-hour term is much less variable, especially as regards its phase angle; its amplitude shows distinct maxima near the equinoxes. That the 8-hour and 6-hour waves, though small near midsummer, represent more than See also:

mere accidental irregularities, seems a safe inference from the regularity apparent in the annual variation of their phase angles. 9. Table V. gives some data for the 24-hour and 12-hour Fourier coefficients, which will serve to illustrate the diversity between different stations. In this table, unlike Table iV., amplitudes are all expressed as decimals of the mean value of the potential gradient for the corresponding season. " Winter " means generally the four midwinter, and " summer " the four midsummer, months; but at Karasjok three, and at Kremsmunster six, months are included in each season. The results for the Sonnblick are derived from a comparatively small number of days in August and September. At Potsdam the data represent the See also:

ARITHMETIC (Gr. apeOµ7run7, sc. TEXVn, the art of counting, from (ipLBµos, number)

arithmetic means derived from the Fourier See also:

ANALYSIS (Gr. avci and Meta, to break up into parts)

analysis for the individual months comprising the season. The 1862—1864 data from Kew—due to J.

D. Everett (19)—are based on "all" days; the others, except Karasjok to some extent, represent electrically quiet days. The cause of the large difference between the two sets of data for ci at Kew is uncertain. The potential gradient is in all cases See also:

LOWER

lower in summer than winter, and thus the reduction in ci in summer would appear even larger than in Table V. if the results were expressed in absolute measure. At Karasjok and Kremsmunster the seasonal variation in at seems comparatively small, but at Potsdam and the Bureau Central it is as large as at Kew. Also, whilst the winter values of al are fairly similar at the several stations the summer values are widely different. Except at Karasjok, where the diurnal changes seem somewhat irregular, the relative amplitude of the 12-hour term is considerably greater in summer than in winter. The values of See also:

A2(z)

a2 at the various stations differ comparatively little, and show but little seasonal See also:

CHANGE (derived through the Fr. from the Late Lat. cambium, cambiare, to barter; the ultimate derivation is probably from the root which appears in the Gr. «a urmu', to bend)

change. Thus the 12-hour term has a much greater uniformity than the 24-hour term. This possesses significance in connexion with the view, supported by A. B. Chauveau (21), F.

Exner (24) and others, that the 12-hour term is largely if not entirely a local phenomenon, due to the action of the lower atmospheric strata, and tending to disappear even in summer at high altitudes. Exner attributes the double daily maximum, which is largely a consequence of the 12-hour See also:

WAVE

wave, to a thin layer near the ground, which in the See also:

early afternoon absorbs the See also:

SOLAR, SOLLER (Lat. solarium, Fr.• galetas, Ital. solaio)

solar See also:

RADIATION, THEORY OF

radiation of shortest wave length. This layer he believes specially characteristic of arid dusty regions, while comparatively non-existent in moist climates or where foliage is luxuriant. In support of his theory Exner states that he has found but little trace of the double maximum and minimum in See also:

CEYLON

Ceylon and elsewhere. C. Nordmann (25) describes some similar results which he obtained in See also:

Algeria during August and September 1905. His station, See also:

PHILIPPEVILLE

Philippeville, is close to the shores of the Mediterranean, and See also:

sea breezes persisted during the day. The diurnal variation showed only a single maximum and minimum, between 5 and 6 P. M. and 4 and 5 A. M. respectively. So again, a few days' observations on the top of Mont See also:

Blanc (4810 metres) by le See also:

CADET (through the Fr. from the Late Lat. capitettum, a diminutive of caput, head, through the Provencal form capdet)

Cadet (26) in August and September 1902, showed only a single period, with maximum between 3 and 4 P. M., and minimum about 3 A.M.

Chauveau points to the reduction in the 12-hour term as compared to the 24-hour term on the Eiffel Tower, and infers the See also:

PRACTICAL

practical disappearance of the former at no See also:

GREAT

great height. The close approach in the values for el in Table V. from the Bureau Central and the Eiffel Tower, and the reduction of c2 at the latter station, are unquestionably significant facts; but the summer value for c2 at Karasjok—a See also:

low level station—is nearly as small as that at the Eiffel Tower, and notably smaller than that at the Sonnblick (3100 metres). Again, Kew is surrounded by a large See also:

park, not devoid of trees, and hardly the place where Exner's theory would suggest a large value for c2, and yet the summer value of c2 at Kew is the largest in Table V. 1o. Observations on See also:

mountain tops generally show high potentials near the ground. This only means that the equipotential surfaces are crowded together, just as they are near the See also:

ridge of a See also:

house. To ascertain how the increase in the voltage varies as the height in the free atmosphere increases, it is necessary to employ kites ors balloons. At small heights Exner (27) has employed See also:

CAPTIVE (from Lat. capere, to take)

captive balloons, provided with a burning fuse, and carrying a See also:

WIRE (A.S. wir, a wire; cf. Swed. vire, to twist, M.H.G. wiere, a gold ornament, Lat. viriae, armlets, ultimately from the root wi, to twist, bind)

wire connected with an electroscope on the ground. He found the gradientnearly See also:

UNIFORM

uniform for heights up to 30 to 40 metres above the ground. At great heights free balloons seem necessary. The balloon carries two collectors a given vertical distance apart. The potential difference between the two is recorded, and the potential gradient is thus found.

Some of the earliest balloon observations made the gradient increase with the height, but such a result is now regarded as abnormal. A balloon may leave the earth with a charge, or become charged through See also:

DISCHARGE (adapted from the O. Fr. discharge, modern decharge, from a med. Lat. discargare, to unload, dis- and earn care, to load, cf. " charge ")

discharge of See also:

BALLAST (O. Swed. barlast, perhaps from bar, bare or mere, and last, load)

ballast. These possibilities may not have been sufficiently realized at first. Among the most important balloon observations are those by le Cadet (1) F. Linke (28) and H. Gerdien (29). The following are samples from a number of days' results, given in le Cadet's See also:

BOOK

book. h is the height in metres, P the gradient in volts per metre. Aug. 9, 1893 h 824 830 1060 1255 1290 1745 1940 2080 2310 2520 P 37 43 43 41 42 34 25 21 18 16 Sep.11, 1897 h 1140 1378 1630 1914 2370 2786 3136 3364 3912 4085 P 43 38 33 25 22 21 19 19 14 13 The ground value on the last occasion was 150. From observations during twelve balloon ascents, Linke concludes that below the 1500-metre level there are numerous sources of disturbance, the gradient at any given height varying much greater heights there is much more uniformity. At heights from 1500 to 6000 metres his observations agreed well with the See also:

formula dV/dh=34—0•oo6 h, V denoting the potential, It the height in metres. The formula makes the gradient diminish from 25 volts per metre at 1500 metres height to 10 volts per metre at 4000 metres.

Linke's mean value for dV/dh at the ground was 125. Accepting Linke's formula, the potential at 4000 metres is 43,750 volts higher than at 1500 metres. If the mean of the gradients observed at the ground and at 1500 metres be taken as an approximation to the mean value of the gradient throughout the lowest 1500 metres of the atmosphere, we find for the potential at 1500 metres level 112,500 volts. Thus at 4000 metres the potential seems of the order of 150,000 volts, Bearing this in mind, one can readily imagine how close together the equipotential surfaces must lie near the See also:

SUMMIT

summit of a high sharp mountain peak. 11. At most stations a negative potential gradient is exceptional, unless during rain or thunder. During rain the potential is usually but not always negative, and frequent alternations of sign are not uncommon. In some localities, however, negative potential gradient is by no means uncommon, at least at some seasons, in the absence of rain. At See also:

MADRAS

Madras, Michie See also:

Smith (30) often observed negative potential during See also:

bright August and September days. The phenomenon was quite common between 9.30 A.M. and noon during See also:

WESTERLY

westerly winds, which at Madras are usually very dry and dusty. At Sodankyla, in 1882—1883, K. S.

Lemstrom and F. C. Biese (31) found that out of 255 observed occurrences of negative potential, ro6 took place in the absence of rain or snow. The proportion of occurrences of negative potential under a clear See also:

SKY (M. Eng. skie, cloud; O. Eng. skua, shade; connected with an Indo-European root sku, cover, whence " scum," Lat. obscurus, dark, &c.)

sky was much above its average in autumn. At Sodankyla rain or snowfall was often unaccompanied by change of sign in the potential. At the polar station Godthaab (32) in 1882—1883, negative potential seemed some-times associated with See also:

aurora (see AURORA POLARIS). Lenard, Elster and Geitel, and others have found the potential gradient negative near waterfalls, the influence sometimes extending to a considerable distance. Lenard (33) found that when pure water falls upon water the neighbouring air takes a, negative charge. Kelvin, Maclean and See also:

Galt (34) found the effect greatest in the air near the level of impact. A sensible effect remained, however, after the influence of splashing was eliminated. Kelvin, Maclean and Galt regard this See also:

PROPERTY

property of falling water as an objection to the use of a water-dropper indoors, though not of practical importance when it is used out of doors. 12.

Elster and Geitel (35) have measured the charge carried by raindrops falling into an insulated See also:

VESSEL (O. Fr. vaissel, from a rare Lat. vascellum, dim. of vas, vase, urn)

vessel. Owing to observational difficulties, the exact measure of success attained is a little difficult to See also:

GAUGE, or GAGE (Med. Lat. gauja, jaugia, Fr. jauge, perhaps connected with Fr. jale, a bowl, galon, gallon)

gauge, but it seems fairly certain that raindrops usually carry a; charge. Elster and Geitel found the sign of the charge often fluctuate repeatedly during a single rain See also:

storm, but it seemed more often than not opposite to that of the simultaneous potential gradient. Gerdien has more recently repeated the experiments, employing an apparatus devised by him for the purpose. It has been found by C. T. R. See also:

Wilson (36) that a vessel in which freshly fallen rain or snow has been evaporated to dryness shows radioactive properties lasting for a few hours. The results obtained from equal weights of rain and snow seem of the same order. 13. W. Linss (6) found that an insulated conductor charged either positively or negatively lost its charge in the free atmosphere; the potential V after time t being connected with its initial value Vo by a formula of the type V = Voe— at where a is constant.

This was, confirmed by Elster and Geitel (7), whose form of dissipation apparatus has been employed in most recent work. The percentage of the Place. Period. Winter. Summer. Cl. C2. ai. a2. cis C2. ai• a2. O O O O Kew 1862—64 0.283 0•16o 184 193 0.127 0.229 III 179 1898—19o4 •102 .103 206 18o .079 .213 87 186 Bureau Central 1894—98 •220 .104 223 206 •130 •200 95 197 Eiffel Tower 1896—98 .. .. .. . 133 •085 216 171 Sonnblick (22) 1902—3 .. ..

.208 •120 178 145 Karasjok . 1903—4 .356 .144 189 155 '165 •093 141 144 Kremsmunster (23). 1902 •28o .117 224 194 •166 .153 241 209 Potsdam 1904 .269 •101 194 185 .096 '152 343 185 from day to day and hour to hour; but at charge which is dissipated per minute is usually denoted by a+ or a_ according to its sign. The mean of a+ and a_ is usually de-noted by a± or simply by a, while q is employed for the ratio a_/a+. Some observers when giving mean values take E(a_/a+) as the mean value of q, while others take E(a_)/E(a+). The Elster and Geitel apparatus is furnished with a See also:

COVER (from the Fr. convert, from couvrir, to cover, Lat. cooperire)

cover, serving to protect the dissipator from the See also:

DIRECT

direct action of rain, See also:

wind or sunlight. It is usual to observe with this cover on, but some observers, e.g. A. Gockel, have made long series of observations without it. The loss of charge is due to more than one cause, and it is difficult to attribute an absolutely definite meaning even to results obtained with the cover on. Gockel (37) says that the results he obtained without the cover when divided by 3 are fairly comparable with those obtained under the usual conditions; but the appropriate divisor must vary to some extent with the See also:

CLIMATIC

climatic conditions. Thus results obtained for a+ or a_ with-out the cover are of doubtful value for purposes of comparison with those found elsewhere with it on.

In the case of q the uncertainty is much less. Table VI. gives the mean values of a± and q found at various places. The observations were usually confined to a few hours of the day, very commonly between II A.M. and I P.M., and in absence of in-formation as to the diurnal variation it is impossible to. say how much this influences the results. The first eight stations le inland; that at Seewalchen (38) was, however, adjacent to a large See also:

lake. The next five stations are on the See also:

COAST (from Lat. costa, a rib, side)

coast or on islands. The final four are at high levels. In the cases where the observations were See also:

con-fined to a few months the representative nature of the results is more doubtful. On mountain summits q tends to be large, i.e. a negative charge is lost much faster than a positive charge. Apparently q has also a tendency to be large near the sea, but this phenomenon is not seen at See also:

TRIESTE (Ger. Triest; Slay. Trst; the Roman Tergeste, q.v.)

Trieste. An exactly opposite phenomenon, it may be remarked, is seen near waterfalls, q becoming very small. Only See also:

INNSBRUCK

Innsbruck and Mattsee give a mean value of q less than unity. Also, as later observations at Innsbruck give more normal values for q, some doubt may be See also:

FELT (cognate with Ger. Filz, Du. vilt, Swed. and Dan. fill; the root is unknown; the word has given Med. Lat. filtrum, " filter ")

felt as to the earlier observations there.

The result for Mattsee seems less open to doubt, for the observer, von Schweidler, had obtained a normal value for q during the previous year at Seewalchen. Whilst the average q in at least the great See also:

MAJORITY (Fr. majorite; Med. Lat. majoritas; Lat. major, greater)

majority of stations exceeds unity, individual observations making q less than unity are not rare. Thus in 1902 (51) the percentage of cases in which q See also:

fell short of I was 30 at Trieste, 33 at See also:

Vienna, and 35 at Kremsmunster; at Innsbruck q was less than I on 58 days out of 98. In a long series of observations, individual values of q show usually a wide range. Thus during observations extending over more than a year, q varied from 0.18 to 8.25 at Kremsmunster and from o.11 to 3.00 at Trieste. The values of a+, a_ and a+ also show large variations. Thus at Trieste a+ varied from 0.12 to 4.07, and a_ from 0.11 to 3.87; at Vienna a+ varied from 0.32 to 7.10, and a_ from o•78 to 5'42; at Kremsmunster a± varied from 0.14 to 5.83. 14. Annual Variation.-When observations are made at irregular hours, or at only one or two fixed hours, it is doubtful how representative they are. Results obtained at noon, for example, probably differ more from the mean value for the 24 hours at one season than at another. Most dissipation results are exposed to considerable uncertainty on these grounds. Also it requires a long series of years to give thoroughly representative results for any element, and few stations possess more than a year or two's dissipation data.

II. 28Table VII. gives comparative results for winter (October to March) and summer at a few stations, the value for the season being the arithmetic mean from the individual months composing it. At Karasjok (10), Simpson observed thrice a day; the summer value there is nearly double the winter both for a+ and a_. The Kremsmunster (42) figures show a smaller but still distinct excess in the summer values. At Trieste (47), Mazelle's data from all days of the year show no decided seasonal change in a+ or a_; but when days on which the wind was high are excluded the summer value is decidedly the higher. At See also:

FREIBURG

Freiburg (43), q seems decidedly larger in winter than in summer; at Karasjok and Trieste the seasonal effect in q seems small and uncertain. 15. Diurnal Variation.-P. B. Zoiss (41, 42) has published dirunal variation data for Kremsmunster for more than one year, and independently for midsummer (May to August) and midwinter (December to February). His figures show a double daily period in both a+ and a_, the principal maximum occurring about i or 2 P.M. The two minima occur, the one from 5 to 7 A.M., the other from 7 to 8 P.M.; they are nearly equal.

Taking the figures answering to the whole year, May 1903 to 1904, a+ varied throughout the day from o•82 to 1.35, and a_ from o•85 to 1.47. At midsummer the extreme hourly values were 0.91 and 1.45 for a+, 0.94 and i•6o for a_. The corresponding figures at midwinter were 0.65 and 1.19 for a+, 0.61 and 1.43 for a_. Zoiss' data for q show also a double daily period, but the apparent range is small, and the hourly variation is somewhat irregular. At Karasjok, Simpson found a+ and a_ both larger between noon and I P.M. than between either 8 and 9 A.M. or 6 and 7 P.M. The 6 to 7 P.M. values were in general the smallest, especially in the case of a+; the evening value for q on the average exceeded the values from the two earlier hours by some 7 %. Summer observations on mountains have shown diurnal variations very large and fairly regular, but widely different from those observed at lower levels. On the Rothhorn, Gockel (43) found a+ particularly variable, the mean 7 A.M. value being 41 times that at I P.M. q (taken as E(a_/a+) varied from 2.25 at 5 A.M. and 2.52 at 9 P.M. to 7.82 at 3 P.M. and 8.35 at 7 P.M. On the Sonnblick, in early September, V. See also:

Conrad (22) found somewhat similar results for q, the principal maximum occur-See also:

RING (O.E. hring; a word common to Teutonic languages; and probably cognate with the Lat. circus, Gr. KtpKOS or KpLKOS, Skt'. chakra, wheel, circle, cf. also " harangue "); in art, a band of circular shape of varying sizes, made of any material and used f

ring at 1 P.M., with minima at 9 P.M. and 6 A.M.; the largest hourly value was, however, scarcely double the least. Conrad found a_ largest at 4 A.M. and least at 6 P.M., the largest value being double the least; a+ was largest at 5 A.M. and least at 2 P.M., the largest value being fully 22 times the least. On Mont Blanc, le Cadet (43) found glargest from I to 3 P.M., the value at either of these hours being more than double that at 11 A.M.

On the Patscherkofel, H. See also:

YON (1822-1847)

yon Ficker and A. Defant (52), observing in December, found q largest from I to 2 P.M. and least between 11 A.M. and noon, but the largest value was only I a times the least. On mountains much seems to depend on whether there are rising or falling air currents, and results from a single season may not be fairly representative. 16. Dissipation seems largely dependent on meteorological conditions, but the phenomena at different stations vary so much as to suggest that the connexion is largely indirect. At most stations a+ and a_ both increase markedly as wind velocity rises. From the observations at Trieste in 1902-1903 E. Mazelle (47) deduced an increase of about 3% in a+ for a rise of i km. per hour in wind velocity. The following are some of his figures, the velocity v being in kilometres per hour:- V 0to4. 20to24 40to49.6oto69. a - 0.64 1 03 1.38 0.33 q 1.13 1.19 1'00 0'96 For velocities from o to 24 km. per hour q exceeded unity in 74 cases out of ioo; but for velocities over 5o km. per hour q exceeded unity II Winter. Summer.

Place. a+ a_ a+ q a+ a_ a± g Karasjok 1903-1904 2'28 2'69 2.49 I•18 4'38 4'94 4'65 1.13 Kremsmunster 1903 I •14 I .30 P22 I. 14 I .38 I-56 1 .47 112 Freiburg . . .. .., .. 1.57 . . .. .. 1.26 Trieste 1902-1903 0.56 0.59 0.58 I•07 0.55 o•61 0.58 1.13 „ See also:

CALM

calm days . .. .. 0.35 ..

.. .. 0.48 Place. Period. Season. Observer or at q Authority. Authors y. Karasjok 1903-4 Year Simpson (10) 3'57 1'15 See also:

WOLFENBUTTEL

Wolfenbuttel Year Elster and Geitel(39) 1.33 1.05 Potsdam 1904 Year Ludeling (40) 1.13 1.33 Kremsmunster 1902 Year Z~Iss (41) I.32 1.18 1903 Year Zoiss (42) P35 1.14 Freiburg Year Gockel (43) .. I.41 Innsbruck 1902 Czermak (44) I.95 0.94 1905 Jan. to June Defant (45) 1.47 1.17 Mattsee (See also:

SALZBURG

Salzburg) 1905 July to Sept. von Schweidler (46) .. 0'99 Seewalchen 1904 July to Sept. von Schweidler (38) 1.18 Trieste . . 1902-3 Year Mazelle (47) 0.58 I.09 Misdroy. 1902 Ludeling (40) 1.09 1.58 See also:

SWINEMUNDE

Swinemunde 1904 Aug. and Sept.

Ludeling (40) I.23 I.37 See also:

HELIGOLAND (Ger. Helgoland)

Heligoland (sands) 1903 Summer Elster and Geitel (40) 1.14 1.71 See also:

plateau „ (40) 3.07 I.50 Juist (See also:

ISLAND (O.E. ieg =isle, +land')

Island) ,, (48) 1.56 1.56 See also:

ATLANTIC

Atlantic and See also:

German Ocean 1904 August Boltzmann (49) 1.83 2.69 Arosa (1800 m.) . 1903 Feb. to April Saake (50) i•79 I.22 Rothhorn (2300 m.) 1903 September Gockel (43) .. 5.31 Sonnblick (3100 m.) . 1903 September Conrad (22) .. 1'75 Mont Blanc (4810 m.) 1902 September le Cadet (43) .. I0•3 in only 40 cases out of Ioo. Simpson got similar results at Karasjok; the rise in a+ and a_ with increased wind velocity seemed, however, larger in winter than in summer. Simpson observed a fall in q for wind velocities exceeding 2 on See also:

Beaufort's See also:

scale. On the top of the Sonnblick, Conrad observed a slight increase of a± as the wind velocity increased up to 20 km. per hour, but for greater velocities up to 8o km. per hour no further decided rise was observed. At Karasjok, treating summer and winter independently, Simpson (10) found a+ and a_ both increase in a nearly linear relation with temperature, from below -20° to + 15° C. For ex-ample, when the temperature was below -2o° mean values were 0.76 for a+ and 0.91 for a_; for temperatures between -10° and -5° the corresponding means were 2.45 and 2.82; while for temperatures between +to° and +15° they were 4.68 and 5.23. Simpson found no certain temperature effect on the value of q.

At Trieste, from 470 days when the wind velocity did not exceed 20 km. per hour, Mazelle (47) found somewhat analogous results for temperatures from o° to 3o° C.; a_, however, increased faster than a+, i.e. q increased with temperature. When he considered all days irrespective of wind velocity, Mazelle found the influence of temperature obliterated. On the Sonnblick, Conrad (22) found a± increase appreciably as temperature See also:

rose up to 4° or 5° C.; but at higher temperatures a decrease set in. Observations on the Sonnblick agree with those at low-level stations in showing a diminution of dissipation with increase of relative humidity. The decrease is most marked as saturation approaches. At Trieste, for example, for relative humidities between 90 and loo the mean a± was less than See also:

HALF

half that for relative humidities under 40. With certain dry winds, notably See also:

FOHN (Ger., probably derived through Romansch favongn, favoign, from Lat. favonius)

Fohn winds in See also:

Austria and See also:

SWITZERLAND

Switzerland, dissipation becomes very high. Thus at Innsbruck Defant (45) found the mean dissipation on days of Fohn fully thrice that on days without Fohn. The increase was largest for a+, there being a fall of about 15% in q. In general, a+ and a_ both tend to be less on cloudy than on bright days. At See also:

KIEL

Kiel (53) and Trieste the average value of q is considerably less for wholly overcast days than for bright days. At several stations enjoying a wide prospect the dissipation has been observed to be specially high on days of great visibility when distant mountains can be recognized.

It tends on the contrary to be low on days of See also:

fog or rain. The results obtained as to the relation between dissipation and barometric pressure are conflicting. At Kremsmunster, Zolss (42) found dissipation vary with the absolute height of the See also:

BAROMETER (from Gr. (3apoc, pressure, and µETpov, measure)

barometer, a± having a mean value of 1.36 when pressure was below the normal, as against 1.20 on days when pressure was above the normal. He also found a± on the average about to % larger when pressure was falling than when it was rising. On the Sonnblick, Conrad (22) found dissipation increase decidedly as the absolute barometric pressure was larger, and he found no difference between days of rising and falling barometer. At Trieste, Mazelle (47) found no certain connexion with absolute barometric pressure. Dissipation was above the average when cyclonic conditions prevailed, but this seemed simply a consequence of the increased wind velocity. At Mattsee, E. R. von Schweidler (46) found no connexion between absolute barometric pressure and dissipation, also days of rising and falling pressure gave the same mean. At Kiel, K. Kaehler (53) found a+ and a_ both greater with rising than with falling barometer. V.

Conrad and M. Topolansky (54) have found a marked connexion at Vienna between dissipation and See also:

OZONE

ozone. Regular observations were made of both elements. Days were grouped according to the intensity of colouring of ozone papers, o representing no visible effect, and 14 the darkest See also:

COLOUR (Lat. color, connected with celare, to hide, the root meaning, therefore, being that of a covering)

colour reached. The mean values of a+ and a_ answering to 12 and 13 on the ozone scale were both about double the corresponding values answering to o and t on that scale. 17. A charged See also:

BODY

body in air loses its charge in more than one way. The air, as is now known, has always present in it ions, some carrying a positive and others a negative charge, and those having the opposite sign to the charged body are attracted and tend to discharge it. The rate of loss of charge is thus largely dependent on the extent to which ions are present in the surrounding air. It depends, however, in addition on the natural mobility of the ions, and also on the opportunities for convection. Of late years many observations have been made of the ionic charges in air. The best-known apparatus for the purpose is that devised by Ebert.

A See also:

CYLINDER (Gr. KvAwSpos, from KvXivaety, to roll)

cylinder See also:

CONDENSER

condenser has its inner surface insulated and charged to a high positive or negative potential. Air is See also:

DRAWN

drawn by an aspirator between the surfaces, and the ions having the opposite sign to the inner cylinder are deposited on it. The charge given up to the inner cylinder is known from its loss of potential. The See also:

VOLUME

volume of air from which the ions have been extracted being known, a measure is obtained of the See also:

TOTAL

total charge on the ions, whether positive or negative. The conditions must, of course, be such as to secure that no ions shall See also:

ESCAPE (in mid. Eng. eschape or escape, from the O. Fr. eschapper, modern echapper, and escaper, low Lat. escapium, from ex, out of, and cappa, cape, cloak; cf. for the sense development the Gr. iichueoOat, literally to put off one's clothes, hence to sli

escape, otherwise there is an underestimate. I+ is used to denote the charge on positive ions, I_ that on negative ions. The unit t4 which they are ordinarily referred is t electrostatic unit of electricity per cubic metre of air. For the ratio of the mean value of I+ to the mean value of I_, the See also:

LETTER (through Fr. lettre from Lat. littera or litera, letter of the alphabet; the origin of the Latin word is obscure; it has probably no connexion with the root of linere, to smear, i.e. with wax, for an inscription with a stilus)

letter Q is employed by Gockel (55), who has made an unusually See also:

COMPLETE

complete study of ionic charges at Freiburg. Numerous observations were also made by Simpson (10)—thrice a day—at Karasjok, and von Schweidler has made a good many observations about 3 P.M. at Mattsee (46) in 1905, and Seewalchen (38) in 1904 Station. Authority. I+ I_ Q Freiburg . . .

. Gockel 0.34 0.24 1.41 Karasjok . Simpson 0.38 0.33 1.17 These will suffice to give a general idea of the mean values met itGockel's mean values of I+ and Q would be reduced to 0.31 and Mattsee . . . . von Schweidler 0.35 0.29 1.19 Seewalchen . . . 0.45 0.38 1.17 1.38 respectively if his values for July—which appear abnormal—were omitted. I+ and L both show a considerable range of values, even at the same place during the same season of the year. Thus at Seewalchen in the course of a See also:

month's observations at 3 P.M., I+ varied from 0.31 to 0.67, and I_ from 0.17 to o•67. There seems a fairly well marked annual variation in ionic contents, as the following figures will show. Summer and winter represent each six months and the results are arithmetic means of the monthly values. Freiburg. Karasjok.

I+ I_ Q I+ I_ Q Winter . 0.29 O.2I 1.49 0.33 0.27 I.22 Summer . . 0.39 o•28 1.34 0.44 0.39 1.13 If the exceptional July values at Freiburg were omitted, the summer values of I+ and Q would become 0.33 and 1.25 respectively. 18. Diurnal Variation.—At Karasjok Simpson found the mean values of I+ and L throughout the whole year much the same between noon and I P.M. as between 8 and 9 A.M. Observations between 6 and 7 P.M. gave means slightly lower than those from the earlier hours, but the difference was only about 5 % in I+ and to % in L. The evening values of Q were on the whole the largest. At Freiburg, Gockel found I+ and I_ decidedly larger in the early afternoon than in either the morning or the late evening hours. His greatest and least mean hourly values and the hours of their occurrence are as follows: Winter. Summer. I+ I+ L Max. See also:

Min.

Max. Min. Max. Min. Max. ,Min. 0.333 0.193 0.242 0.130 0.430 0.244 0'333 0.192 2 P.M. 7 P.M. 2 P.M. 8 P.M. 4 P.M. 9 t0 4 P.M.

9 to to P.M. 10 P.M. Gockel did not observe between to P.M. and 7 A.M. 19. Ionization seems to increase notably as temperature rises. Thus at Karasjok Simpson found for mean values: Temp. less than—2o° — I0° to -5° to° to 15° I+=o•18, I_=o•16 I+=o•36, I_=0.30 I+=O.45, I-=0.43 Simpson found no clear influence of temperature on Q. Gockel; observed similar effects at Freiburg—though he seems doubtful whether the relationship is direct—but the influence of temperature on I+ seemed reduced when the ground was covered with snow. Gockel found a diminution of ionization with rise of relative humidity. Thus for relative humidities between 4o and 5o mean values were x.306 for I+ and 0.219 for I_; whilst for relative humidities between 90 and too the corresponding means were respectively 0.222 and 0.134. At Karasjok, Simpson found a slight decrease in I_ as relative humidity increased, but no certain change in I+. Specially large values of I+ and I_ have been observed at high levels in balloon ascents. Thus on the 1st of July 1901, at a height of 2400 metres, H.

Gerdien (29) obtained o•86 for I+ and 1.09 for L. 20. In 1901 Elster and Geitel found that a radioactive emanation is present in the atmosphere. Their method of measuring the radio-activity is as follows (48) : A wire not exceeding I mm. in See also:

DIAMETER (from the Cr. &a, through, µErpov, measure)

diameter, charged to a negative potential of at least 2000 volts, is supported between insulators in the open, usually at a height of about 2 metres. After two hours' exposure, it is wrapped round a See also:

FRAME

frame supported in a given position relative to Elster and Geitel's dissipation apparatus, and the loss of charge is noted. This loss is proportional to the length of the wire. The radioactivity is denoted by A, and A =1' signifies that the potential of the dissipation apparatus fell t volt in an hour per metre of wire introduced. The loss of the dissipation body due to the natural ionization of the air is first allowed for. Suppose, for instance, that in the absence of the wire the potential falls from 264 to 255 volts in 15 minutes, whilst when the wire (to metres long) is introduced it falls from 264 to 201 volts in io minutes, then 10A=(264—201) x6—(264—255)x4=342; or A=34.2. The values obtained for A seem largely dependent on the station. At Wolfenbuttel, a year's observations by Elster and Geitel (56) made A vary from 4 to 64, the mean being 20. In the island of Juist, off the See also:

FRIESLAND, or VRIESLAND

Friesland coast, from three See also:

WEEKS, EDWIN LORD (1849-1903)

weeks' observations they obtained only 5.2 as the mean.

On the other See also:

hand, at Altjoch, an Alpine station, from nine days' observations in July 1903 they obtained a mean of 137, the maximum being 224, and the minimum 92. At Freiburg, from 15o days' observations near noon in 1903-1904, Gockel (57) obtained a mean of 84, his extreme values being 10 and 420. At Karasjok, observing several times throughout the day for a good many months, Simpson (10) obtained a mean of 93 and a maximum of' 432. The same observer from four weeks' observations at See also:

HAMMERFEST

Hammerfest got the considerably lower mean value 58, with a maximum of 252. At this station much lower values were found for A with sea breezes than with See also:

LAND

land breezes. Observing on the See also:

PIER (older forms per or Pere, from Med. Lat. pera; the word for piers out of water. For river piers, where a firm, watertight is of obscure origin, and the connexion with Fr. Pierre, Lat. stratum is found at a moderate depth below the river-bed, the pctr

pier at Swinemunde in August and September 1904, Ludeling (40) obtained a mean value of 34. Elster and Geitel (58), having found air drawn from the See also:

SOIL

soil highly radioactive, regard ground air as the source of the emanation in the atmosphere, and in this way account for the low values they obtained for A when observing on or near the sea. At Freiburg in winter Gockel (55) found A notably reduced when snow was on the ground, I+ being also reduced. When the ground was covered by snow the mean value of A was only 42, as compared with 81 when there was no snow. J. C. McLennan (59) observing near the foot of See also:

Niagara found A only about one-See also:

SIXTH

sixth as large as at See also:

TORONTO

Toronto.

Similarly at Altjoch, Elster and Geitel (56) found A at the foot of a See also:

WATERFALL

waterfall only about one-third of its normal value at a distance from the fall. 21. Annual and Diurnal Variations.-At Wolfenbuttel, Elster and Geitel found A vary but little with the season. At Karasjok, on the contrary, Simpson found A much larger at midwinter-notwithstanding the presence of snow-than at midsummer. His mean value for November and December was 129, while his mean for May and June was only 47. He also found a marked diurnal variation, A being considerably greater between 3 and 5 A.M. or 8.3o to 10.30 P.M. than between Io A.M. and noon, or between 3 and 5 P.M. At all seasons of the year Simpson found A rise notably with increase of relative humidity. Also, whilst the mere absolute height of the barometer seemed of little, if any, importance, he obtained larger values of A with a falling than with a rising barometer. This last result of course is favourable to Elster and Geitel's views as to the source of the emanation. 22. For a wire exposed under the conditions observed by Elster and Geitel the emanation seems to be almost entirely derived from radium. Some part, however, seems to be derived from See also:

THORIUM (symbol Th, atomic weight ,232.42 [0=16])

thorium, and H.

A. Bumstead (60) finds that with longer exposure of the wire the relative importance of the thorium emanation increases. With three hours' exposure he found the thorium emanation only from 3 to 5% of the whole, but with 12 hours' exposure the percentage of thorium emanation rose to about 15. These figures refer to the state of the wire immediately after the exposure; the rate of decay is' much more rapid for the radium than for the thorium emanation. 23. The different elements-potential gradient, dissipation, ionization and radioactivity- are clearly not See also:

INDEPENDENT

independent of one another. The loss of a charge is naturally largely dependent on the richness of the surrounding air in ions. This is clearly shown by the following results obtained by Simpson (10) at Karasjok for the mean values of a+ corresponding to certain See also:

groups of values of If. To eliminate the disturbing influence of wind, different wind strengths are treated separately. Wind to o•1. 0•I to 0.2 to 0.3 0.3 t0 0.4. 0.4 t0 0.5.

. Strength. o to 1 0.45 0•6o 1.26 2.04 3.03 I ,, 2 0.65 I•o8 1.85 2.92 3'83 2 „ 3 .. .. 2.70 3.88 5'33 If we regard the potential gradient near the ground as representing a negative charge on the earth, then if the source of See also:

SUPPLY (through Fr. from Lat. supplere, to fill up)

supply of that charge is unaffected the gradient will rise and become high when the operations by which discharge is promoted slacken their activity. A diminution in the number of positive ions would thus naturally be accompanied by a rise in potential gradient. Table IX. associates with rise in potential gradient a reduced number of both positive and negative ions and a diminished rate of dissipation whether of a negative or a positive charge. The rise in q and Q indicates that the diminished rate of dissipation is most marked for positive charges, and that negative ions are even more reduced then positive. At KremsmunsterZolss (41) finds a considerable similarity between the diurnal variations in q and in the potential gradient, the hours of the forenoon and afternoon maxima being nearly the same in the two cases. No distinct relatic nship has yet been established between potential gradient and radioactivity. At Karasjok Simpson (10) found fairly similar mean values of A for two groups of observations, one confined to cases when the potential gradient exceeded +400 volts, the other confined to cases of negative gradient. At Freiburg Gockel (55, 57) found that when observations were grouped according to the value of A there appeared a distinct rise in both a_ and I+ with increasing A. For instance, when A See also:

lay between loo and 150 the mean value of a_ was 1.27 times greater than when A lay between o and 5o ; while when A lay between 120 and 150 the mean value of I+ was 1.53 times larger than when A lay between o and 30.

These apparent relationships refer to mean values. In individual cases widely different values of a_ or I+ are associated with the same value of A. 25. If V be the potential, p the See also:

DENSITY (Lat. densus, thick)

density of free electricity at a point in the atmosphere, at a distance r from the earth's centre, then assuming statical conditions and neglecting variation of V in horizontal directions, we have r-1(d/dr) (r dV/dr) +4rrp = 0. For practical purposes we may treat See also:

R2(rt-s2)

r2 as constant, and replace d/dr by d/dh, where h is height in centimetres above the ground. We thus find p= - (I/41r)d2V/dh2. If we take a tube of force 1 sq. cm. in See also:

section, and suppose it cut by equipotential surfaces at heights hl and h2 above the ground, we have for the total charge M included in the specified portion of the tube 4irM = (dV/dh)hl - (dV/dh)h2. Taking Linke's (28) figures as given in § It), and supposing h1=o, h2 =15 X lo', we find for the charge in the unit tube between the ground and 1500 metres level, remembering that the centimetre is now the unit of length, M=(I/4r) (125-25)/100. Taking I volt equal 1/300 of an electrostatic unit, we find M =0.000265. Between 1500 and 4000 metres the charge" inside the unit tube is much less, only 0.000040. The charge on the earth itself has its surface density given by u= - (I/42r) X See also:

I25 volts per metre, =0.000331 in electrostatic See also:

units. Thus, on the view now generally current, in the circumstances answering to Linke's experiemnts we have on the ground a charge of -331 X10-6 C.G.S. units per sq. cm.

Of the correspondingg positive charge, 265 X10-6 lies below the 1500 metres level, 40 X10--between between this and the 4000 metres level, and only 26)00-6 above 4000 metres. Thereis a difficulty in reconciling observed values of the ionization with the results obtained from balloon ascents as to the variation of the potential with See also:

ALTITUDE (Lat. altitudo, from altus, high)

altitude. According to H. Gerdien (61), near the ground a mean value for d2V/dh2 is -(1/10) volt/(metre)2. From this we deduce for the charge p per cubic centimetre (I f 42r) X IO-6 (volt/cm2), or 2.7 X10-9 electrostatic units. But taking, for example, Simpson's mean values at Karasjok, we have observed - p- l+- Ii =0.05 X (cm./metre)3 = 5 X 10-8, and thus (calculated p)/(observed p) = 0.05 approximately. Gerdien himself makes I+-I_ considerably larger than Simpson, and concludes that the observed value of p is from 30 to 50 times that calculated. The presumption is either that d2V/dh2 near the ground is much larger numerically than Gerdien supposes, or else that the ordinary See also:

INSTRUMENTS

instruments for measuring ionization fail to catch some See also:

SPECIES

species of See also:

ion whose charge is preponderatingly negative. 26. Gerdien (61) has made some calculations as to the probable average value of the vertical electric current in the atmosphere in fine weather. This will be composed of a See also:

CONDUCTION, ELECTRIC

conduction and a convection current, the latter due to rising or falling air currents carrying ions. He supposes the See also:

field near the earth to be loo volts per metre, or 1/300 electrostatic units.

For simplicity, he assumes I+ and I_ each equal 0.25 X 10-6 electrostatic units. The specific velocities of the ions-i.e. the velocities in unit field-he takes to be 1.3 X300 for the positive, and I•6X3oo for the negative. The positive and Simspon concluded that for a given wind velocity dissipation is practically a linear function of ionization. 24. Table IX. will give a general idea of the relations of potential gradient to dissipation and ionization. Potential q Karasjok (Simpson (10)). gradients volts per Kremsmunster(41). Freiburg (43). Rothhorn (43): a+ a_ I+ I_ Q metre. 0 to 5o 1.12 5o „ loo 1.14 1.31 .. 4.29 4.67 0.43 0.39 I.II 100 ,, 150 1.24 1.69 3.38 3.93 0.37 0.32 1.15 150 ,, 200 1.48 1.84 .. 1.85 2.58 0.36 0.28 1.28 200 ,, 300 ..

.. 3.21 1.37 I.58 o•26 0.19 I.42 300 ,, 400, .. 4'33 o•6o 0.85 .. .. .. 400 ,, 500 5.46 .. . . 500 „ 7001 .. 8.75 negative ions travel in opposite directions, so the total current is (1 /30o) (o.25 X 10-0) (1.3 X 300+ I.6 X 300), or 73 X Io-6 in electrostatic measure, otherwise 2.4 X10-" amperes per sq. cm. As to the convection current, Gerdien supposes-as in § 25-p=2.7 X 10-9 electrostatic units, and on fine days puts the average velocity of rising air currents at lo cm. per second. This gives a convection current of 2.7X10-6 electrostatic units, or about 1/27 of the conduction current. For the total current we have approximately 2.5 X10-" amperes per sq. cm.

This is insignificant compared to the size of the currents which several authorities have calculated from considerations as to terrestrial See also:

magnetism (q.v.). Gerdien's estimate of the convection current is for fine weather conditions. During rainfall, or near clouds or dust layers, the magnitude of this current might well be enormously increased; its direction would naturally vary with climatic conditions. 27. H. Mache (62) thinks that the ionization observed in the atmosphere may be wholly accounted for by the radioactive emanation. If this is true we should have q=See also:

ant, where q is the number of ions of one sign made in I cc. of air per second by the emanation, a the constant of recombination, and n the number of ions found simultaneously by, say, Ebert's apparatus. Mache and R. Holfmann, from observations on the amplitude of saturation currents, deduce r4 as a mean value. Taking for a Townsend's value 1.2 +10-6, Mache finds n =1800. The charge on an ion being 3.4 X io 10 Mache deduces for the ionic charge, I+ or I_, per cubic metre 1800X3.4 X io '° X 106, or o.6. This is at least of the order observed, which is all that can be expected from a calculation which assumes I+ and I_ equal.

If, however, Mache's views were correct, we should expect a much closer connexion between I and A than has actually been observed. 28. C. T. R. Wilson (63) seems disposed to regard the action of rainfall as the most probable source of the negative charge on the earth's surface. That great separation of positive and negative electricity sometimes takes place during rainfall is undoubted, and the charge brought to the ground seems preponderatingly negative. The difficulty is in accounting for the continuance in extensive fine weather districts of large positive charges in the atmosphere in See also:

FACE (from Lat. fades, derived either from facere, to make, or from a root fa-, meaning " appear "; cf. Gr. cbatvstv)

face of the processes of recombination always in progress. Wilson considers that convection currents in the upper atmosphere would be quite inadequate, but conduction may, he thinks, be sufficient alone. At barometric pressures such as exist between 18 and 36 kilometres above the ground the mobility of the ions varies inversely as the pressure, whilst the coefficient of recombination a varies approximately as the pressure. If the atmosphere at different heights is exposed to ionizing radiation of uniform intensity the rate of See also:

PRODUCTION (Lat. productionem, from producere, to pro-duce)

production of ions per cc., q, will vary as the pressure. In the steady state the number, n, of ions of either sign per cc. is given by n=~q and so is independent of the pressure or the height.

The conductivity, which varies as the product of n into the mobility, will thus vary inversely as the pressure, and so at 36 kilometres will be one See also:

HUNDRED

hundred times as large as close to the ground. Dust particles interfere with conduction near the ground, so the relative conductivity in the upper layers may be much greater than that calculated. Wilson supposes that by the fall to the ground of a preponderance of negatively charged rain the air above the shower has a higher positive potential than elsewhere at the same level, thus leading to large conduction currents laterally in the highly conducting upper layers. 29. Thunder.-Trustworthy frequency See also:

STATISTICS

statistics for an individual station are obtainable only from a long series of observations; while if means are taken from a large See also:

AREA

area places may be included which differ largely amongst themselves. There is the further complication that in some countries thunder seems to be on the increase. In temperate latitudes, speaking generally, the higher the latitude the fewer the thunderstorms. For instance, for See also:

EDINBURGH

Edinburgh (64) (1771 to 1900) and See also:

LONDON

London (65) (1763 to 1896) R. C. Mossman found theappears fairly uniform, we may take See also:

Hungary (67). According to the statistics for 1903, based on several hundred stations, the average number of days of thunder throughout six subdivisions of the See also:

COUNTRY (from the Mid. Eng. contre or contrie, and O. Fr. cuntree; Late Lat. contrata, showing the derivation from contra, opposite, over against, thus the tract of land which fronts the sight, cf. Ger. Gegend, neighbourhood)

country, some wholly plain, others mainly mountainous, varied only from 21.1 to 26.5, the mean for the whole of Hungary being 23.5. The See also:

ANTITHESIS (the Greek for " setting opposite ")

antithesis of this exists in the See also:

UNITED

United States of See also:

AMERICA

America.

According to A. J. See also:

Henry (68) there are three regions of maximum frequency: one in the south-See also:

east, with its centre in See also:

FLORIDA

Florida, has an average of 45 days of thunder in the year; a second including the middle See also:

MISSISSIPPI

Mississippi valley has an average of 35 days; and a third in the middle See also:

MISSOURI

Missouri valley has 30. With the exception of a narrow See also:

STRIP

strip along the See also:

CANADIAN

Canadian frontier, thunderstorm frequency is fairly high over the whole of the United States to the east of the Tooth See also:

meridian. But to the See also:

west of this, except in the Rocky Mountain region where storms are numerous, the frequency steadily diminishes, and along the Pacific coast there are large areas where thunder occurs only once or twice a year. 30. The number of thunderstorm days is probably a less exact measure of the relative intensity of thunderstorms than statistics as to the number of persons killed annually by lightning per million of the See also:

POPULATION (Lat. populus, people; populare, to populate)

population. Table X. gives a number of statistics of this See also:

KIND (O. E. ge-cynde, from the same root as is seen in " kin," supra)

kind. The letter M stands for " Midland." Inhabitants. Hungary 7.7 Upper Missouri and Plains . 15 See also:

NETHERLANDS

Netherlands 2.8 Rocky Mountains and Plateau Io England, N.1\4. 1.8 South Atlantic .

. 8 1.3 Central Mississippi . 7 „ E. S.M.. . 1.2 Upper " 7 See also:

York and W.M. 1.1 See also:

OHIO

Ohio Valley . 7 N 1.o Middle Atlantic 6 See also:

WALES (Cymru, Gwalia, Cambria)

Wales. . 0.9 Gulf States 5 England, S.E. . o•8 New England 0.7 Pacific Coast . . <I` „ N.W. S.W.. . . 0.6 North and South Dakota .

20 London . . . . . . o 1 See also:

California o The figure for Hungary is based on the seven years 1897-1903; that for the Netherlands, from data by A. J. Montle (69) on the nine years 1882-1890. The See also:

ENGLISH

English data, due to R. See also:

Lawson (70), are from twenty-four years, 1857-188o; those for the United States, due to Henry (68), are for five years, 1896-1900. In comparing these data allowance must be made for the fact that danger from lightning is much greater out of doors than in. Thus in Hungary, in 1902 and 1903, out of 229 persons killed, at least 171 were killed out of doors. Of the 229 only 67 were See also:

WOMEN

women, the only assignable explanation being their rarer employment in the See also:

FIELDS, JAMES THOMAS (1817-1881)

fields. Thus, ceteris paribus, deaths from lightning are much more numerous in a country than in an See also:

INDUSTRIAL

industrial population.

This is well brought out by the low figure for London. It is also shown conspicuously in figures given by Henry. In New York State, where the population is largely industrial, the annual deaths per million are only three, but of the agricultural population eleven, In states such as See also:

WYOMING

Wyoming and the Dakotas the population is largely rural, and the deaths by lightning rise in consequence. The frequency and intensity of thunder-storms are unquestionably greater in the Rocky Mountain than in the New England states, but the difference is not so great as the statistics at first sight suggest. 31. Even at the same place thunderstorms vary greatly in intensity and duration. Also the times of beginning and ending are difficult to define exactly, so that several elements of uncertainty exist in data as to the seasonal or diurnal variation. The monthly data in Table XI. are percentages of the total for the year. In most cases the figures are based on the number of days of thunder at a particular station, or at the average station of a country; but the second set Jan. Feb. March. April.

May. June. July. Aug. Sept. Oct. Nov. Dec. Edinburgh I.8 1.4 I.4 3.8 12.3 20.8 28.2 19.1 7.0 2.3 1.1 0.8 London o•6 0.5 1.6 6.6 12.7 18.3 25'5 19.2 9.3 3.1 I.7 0.9 Paris 0.2 0.4 2.3 7.5 14.9 21.6 22.0 17.0 9.9 3.5 0.4 0.4 Netherlands 2.2 1.8 3.7 6.5 14.0 14.7 I5.6 14.7 10.3 10.1 3.8 2.5 See also:

France . 2.2 2.8 4.1 8.4 13.8 18.7 14.6 13.5 10.0 6.3 3.1 2.4 Switzerland 0.2 0.3 0.5 4.9 11.9 22.9 29.9 18•o 9.8 1-1 , 0.3 0.2 Hungary (a) o•o o•i 1.6 5.7 20.9 25.0 23.2 15.9 5.7 1.3 0.4 0.2 (b) o•o o•o I•o 3.2 II.8 20.6 30.7 25.3 6.9 0.5 0.0 0.0 United States 0.1 0.1 1.2 4.0 14.3 25.0 27.2 20.4 5.8 1.4 0.3 0•I Hong-See also:

KONG

Kong o•0 2.1 4.3 8.5 12.8 23.4 14.9 21.3 ro•6 2•I o•0 0.0 Trevandrum 3.2 3.8 13.1 20.9 18.6 4.9 P2 3.5 2.5 12.9 12.0 3.3 Batavia . 10.4 9.2 II•I 10.5 7.9 5.5 4.3 3.8 5.4 8.8 12.2 I0.9 average annual number of "thunderstorm days to be respectively 6.4 and 10.7; while at Paris (1873-1893) E. Renou (66) found 27.3 such days.

In some tropical stations, at certain seasons of the year, thunder is almost a daily occurrence. At Batavia (18) during the See also:

EPOCH (Gr. E7roxij, holding in suspense, a pause, from E1rxav, to hold up, to stop)

epoch 1867-1895, there were on the average 120 days of thunder in the year. As an example of a large area throughout which thunder frequencyfor Hungary relates to the number of lightning strokes causing See also:

FIRE (in O. Eng. f j'r; the word is common to West German languages, cf. Dutch vuur, Ger. Feuer; the pre-Teutonic form is seen in Sanskrit pu, pavaka, and Gr. irup; the ultimate origin is usually taken to be a root meaning to purify, cf. Lat. purus)

fire,: and the figures for the United States relate to deaths by lightning. The data for Edinburgh, due to R. C. Mossman (64), refer to 130 years, 1771 to 1900. The data for London (1763-1896) are also due to I See also:

Note in case of Pacific Coast, Table X., " <1 " means less than 1." Mossman (65) ; for Paris (1873-1893) to Renou (66) ; for the Nether-lands (1882-1900) to A. J. Monne (69); for France(71) (1886-1899) to Frou and Hann; for Switzerland to K. See also:

Hess (72) ; for Hungary (67) (1896-1903) to L. von See also:

SZALAY, LADISLAS (1813-1864)

Szalay and others; for the United States (1890-1900) to A. J. Henry (68); for Hong-Kong (73)(1894-1903) to W.

Doberck. The Trevandrum (74) data (1853-1864) were due originally to A. Broun; the Batavia data (1867-1895) are from the Batavia Observations, vol. xviii. Most stations in the See also:

NORTHERN

northern hemisphere have a conspicuous maximum at midsummer with little thunder in winter. Trevandrum (8° 31' N.) and Batavia (6° 11' S.), especially the former, show a double maximum and minimum. 32. Daily Variation.-The figures in Table XII. are again perfor See also:

Germany, due to O. See also:

STEFFENS, HENRIK (1773-1845)

Steffens (80), represent the average number of houses struck by lightning in a year per million houses; in the first See also:

DECADE (from Gr. Oka, ten)

decade only seven years (1854-186o) are really included. Mossman thinks that the apparent increase at Edinburgh and London in the later decades is to some extent at least real. The two sets of figures show some corroborative features, notably the low frequency from 186o to 1870. The figures for Germany-representing four out of six divisions of that country-are remarkable. In Germany as a whole, out of a million houses the number struck per annum was three and a half times as great in the decade 1890 to 1900 as between 1854 and 186o.

Von Bezold (81) in an earlier memoir presented data analogous to Steffens', seemingly accepting them as representing a true increase in thunderstorm destructiveness. Hour. 0-2. 2-4. 4-6. 6-8. 8-Io. 10-12. 0'-2' 2'-4'. 4'-6'. 6'-8'. 8'-ro'.

Io'-12'. See also:

FINLAND (Finnish, Suomi or Suomenmaa)

Finland (76) 2.3 2.0 2.2 3.0 4.6 12.1 18.9 19.2 16.1 10.1 6•I 3.4 Edinburgh (64) 1.7 2.0 1.4 I.7 4.7 14.2 22.4 23'7 11'9 9.2 5.I 2.0 See also:

Belgium (77) 3.0 2.9 1.7 1.8 2.0 6.4 12.9 21.6 19.4 15.8 8.4 4.1 See also:

Brocken (78) 1.6 2.5 I.3 I.3 4.2 3.1 12.1 28.6 22.4 10.1 7.2 5.6 Switzerland (72) 3•I 2.3 2•I 1.6 2.0 7.3 13.8 20.9 20.8 14.6 8•o 3.5 Italy (77) 1.3 1.6 1.4 2.0 3.0 8.5 19.5 26.5 16'6 9.8 8.3 1.5 Hungary (i.) (67) 2.1 I.9 1.9 2•I 2.9 I1.5 18.1 22.0 17.9 10.7 6.2 2.8 „ (ii.) (67) 6.9 4.2 2.3 2.0 2.0 5.0 9.9 16.9 18.2 Io•7 11.7 10.0 „ (iii.) (75) 2.3 1.9 2.0 2.4 2.7 7.9 16.1 22•I 19.1 12.7 7.6 3.2 (iv.) (75) 2.6 2.2 1.9 1.9 3.6 13.3 19.9 20.7 15.2 9.2 6.2 3.3 Trevandrum (74) 5.6 4.9 4.3 1'3 I.4 2'0 13'3 24.5 15.9 13'3 7.6 5.9 Agustia (74) 2.9 2.9 0.3 0.0 1.7 2.9 15•I 36.1 22.2 9.3 4.6 2.0 centages. They are mostly based on data as to the hour of commencement of thunderstorms. Data as to the hour when storms are most severe would throw the maximum later in the day. This is illustrated by the first two sets of figures for Hungary (67). The first set relate as usual to the hour of commencement, the second to the hours of occurrence of lightning causing fires. Of the two other sets of figures for Hungary (75), (iii.) relates to the central plain, (iv.) to the mountainous regions to north and south of this. The hour of maximum is earlier for the mountains, thunder being more frequent there than in the plains between 8 A.M. and 4 P.M., but less frequent between 2 and to P.M. Trevandrum (8° 31 N., 76° 59' E., 195 ft. above sea-level) and Agustia (8° 37' N., 77° 20' E., 6200 ft. above sea-level) afford a contrast between low ground and high ground in See also:

India. In this instance there seems little difference in the hour of maximum, the distinguishing feature being the great concentration of thunderstorm occurrence at Agustia between noon and 6 P.M. 33.

Table XIII. gives some data as to the variability of thunder from year to year. The figures for the Netherlands (69) and France (71) are the number of days when thunder occurred somewhere in the country. Its larger area and more varied climate give a much larger number of days of thunder to France. Notwithstanding the proximity of the two countries, there is not much See also:

PARALLELISM, PSYCHOPHYSICAL

parallelism between the data. The figures for Hungary (67) give the number of lightning strokes causing fire; those for the United States (68) give the number of per-sons killed by lightning. The conspicuous maximum in 1901 and great drop in 1902 in Hungary are also shown by the statistics as to the number of days of thunder. This number at the average station of the country fell from 38.4 in 1901 to 23.1 in 1902. On the whole, however, the number of destructive lightning strokes and of days of thunder do not show a close parallelism. 34. Table XIV. deals with the variation of thunder over longer periods. The data for Edinburgh (64) and London (65) due to Mossman, and those for See also:

TILSIT

Tilsit, due to C. Kassner (79), represent the average number of days of thunder per annum.

The data Doubts have, however, been expressed by others-e.g. A. Gockel, Das Gewitter, p. Io6-as to the real significance of the figures. Changes in the height or construction of buildings, and a greater readiness to make claims on See also:

INSURANCE

insurance offices, may be contributory causes. 35. The fact that a considerable number of See also:

PEOPLE

people sheltering under trees are killed by lightning is generally accepted as a convincing See also:

PROOF (in M. Eng. preove, proeve, preve, &°c., from O. Fr . prueve, proeve, &c., mod. preuve, Late. Lat. proba, probate, to prove, to test the goodness of anything, probus, good)

proof of the unwisdom of the proceeding. When there is an See also:

OPTION (Lat. optio, choice, choosing, optare, to choose)

option between a tree and an adjacent house, the latter is doubt-less the safer choice. But when the option is between sheltering under a tree and remaining in the open it is not so clear. In Hungary (67), during the three years 1901 to 1903, 15 % of the total deaths by lightning occurred under trees, as against 57 % wholly in the open. In the United States (68) in 1900, only to % of the deaths where the precise conditions were ascertained occurred under trees, as against 52 % in the open. If then the See also:

RISK

risk under trees exceeds that in the open in Hungary and the United States, at least five or six times as many people must remain in the open as seek shelter under trees.

An isolated tree occupying an exposed position is, it should be remembered, much more likely to be struck than the average tree in the midst of a See also:

wood. A good See also:

DEAL

deal also depends on the species of tree. A good many years' data for See also:

LIPPE

Lippe (82) in Germany make the liability to lightning stroke as follows-the number of each species being supposed the same:-See also:

OAK (O. Eng., (lc)

Oak 57, See also:

Fir 39, See also:

PINE (Lat. Pinus, Gr. srlrur)

Pine 5, See also:

BEECH

Beech 1. In See also:

STYRIA (German, Steiermark or Steyermark)

Styria, according to K. Prohaska (83), the species most liable to be struck are oaks, poplars and See also:

PEAR (Pyrus communis)

pear trees; beech trees again are exceptionally safe. It should, however, be See also:

BORNE, KARL LUDWIG (1786–1837)

borne in mind that the apparent differences between different species may be partly a question of height, exposure or proximity to water. A good deal may also depend on the soil. According to Hellmann, as quoted by Henry (82), the liability to lightning stroke in Germany may be put at See also:

CHALK

chalk 1, See also:

clay 7, See also:

sand 9, See also:

LOAM (O.E. lam; the word appears in Dut. leem and Ger. Lehm; the ultimate origin is the root lai-, meaning " to be sticky," which is seen in the cognate " lime," Lat. limus, mud, clay)

loam 22. Year Nends. France. Hungary. U.S .A.

Year. lands. . France. ar U.S.A. lands. lands. g y 1882 98 .. 141 .. 1893 102 288 233 209 1883 117 .. 195 .. 1894 111 300 333 336 1884 95 .. 229 .. 1895 119 309 280 426 1885 93 •• 192 .. 1896 109 266 299 341 1886 102 251 319 ..

1897 119 297 350 362 1887 78 292 236 .. 1898 95 299 386 367 1888 94 286 232 .. 1899 112 299 368 563 1889 126 294 258 .. 1900 108 .. 401 713 1890 93 299 265 .. 1901 .. .. 502 1891 98 317 302 204 1902 .. .. 322 1892 86 324 350 251 1903 .. .. 256 Decade ending 1810.

1820. 1830. 1840. 1850. 186o. 1870. 1880. 1890. 1900. Edinburgh 4.9 5.7 7.7 6'7 5.7 6'5' 5.4 10.6 9.4 9'2 London 9.5 8.3 11.5 11.8 Io•5 11'9 9.6 15.7 13.0 .. Tilsit . ..

. . I2.1 I2•I 16•I 15.3 I I.9 17.6 2I.8 . . Germany, . .. .. .. .. .. 49 66 91 143 175 West . .. .. . ..

92 to6 187 244 331 ,, . North . . . .. 124 135 245 288 352 ,, . See also:

AST, GEORG ANTON FRIEDRICH (1778-1841)

ast . .. . . . . .. . . 102 143 186 210 273 East .

. . . . . Whole .. .. . . . _- .. 90 116 189 254 318 36. Numerous attempts have been made to find periodic variations in thunderstorm frequency. Among the periods suggested are the 11-year sunspot period, or half this (cf. v. Szalay (67)). Ekholm and See also:

ARRHENIUS, SVANTE AUGUST (1859– )

Arrhenius (84) claim to have established the existence of a tropical lunar period, and a 25.929-day period; while P. Polis (85) considers a synodic lunar period probable.

A. B. MacDowall (86) and others have advanced See also:

EVIDENCE (Lat. evidentia, evideri, to appear clearly)

evidence in favour of the view that thunderstorms are most frequent near new See also:

moon and fewest near full moon. Much more evidence would be required to produce a general acceptance of any of the above periods. 37. St Elmo's Fire.—Luminous discharges from masts, lightning conductors, and other pointed See also:

OBJECTS

objects are not very infrequent, especially during thunderstorms. On the Sonnblick, where the phenomenon is common, Elster and Geitel (87) have found St Elmo's fire to See also:

ANSWER (derived from and, against, and the same root as swear)

answer to a discharge sometimes of positive sometimes of negative electricity. The colour and See also:

APPEARANCE (from Lat. apparere, to appear)

appearance differ in the two cases, red predominating in a positive; See also:

BLUE (common in different forms to most European languages)

blue in a. negative discharge. The differences characteristic of the two forms of discharge are de-scribed and illustrated in Gockel's Das Gewitter. Gockel states (l.c. p. 74) that during snowfall the sign is positive or negative according as the flakes are large or an small and powdery. The discharge is not infrequently accompanied by a sizzling See also:

sound.

38. Of late years many experiments have oeen made on the influence of electric fields or currents on plant growth. S. Lemstrom (88), who was a See also:

PIONEER

pioneer in this See also:

DEPARTMENT (Fr. departement, from departir, to separate into parts)

department, found an electric field highly beneficial in some but not in all cases. Attempts have been made to apply electricity to See also:

agriculture on a commercial scale, but the exact measure of success attained remains somewhat doubtful. Lemstrom believed atmospheric electricity, to See also:

PLAY

play an important part in the natural growth of vegetation, and he assigned a See also:

SPECIAL

special role to the needles of fir and pine trees. See also:

TEXT (Lat. textum, woven fabric, from texere, to weave)

Text-books:—(1) G. le Cadet, Etude du champ electrique de l'atmosphere (Paris, 1898) ; (2) Svante A. Arrhenius, Lehrbuch der kosmischen Physik (See also:

LEIPZIG

Leipzig, 1903) ; (3) A. Gockel, Das Gewitter (See also:

COLOGNE (Ger. Koln, or officially, since 1900, Coln)

Cologne, 1905). Lists of See also:

ORIGINAL

original authorities:—(4) F. Exner, M.Z., vol. 17, 1900, p.

529 (especially pp. 542-3); (5) G. C. Simpson, Q.J.R. Met. See also:

Soc., vol. 31, 1905, p. 295 (especially pp. 305-6). References in the text: (6) M.Z., vol. 4, 1887, p• 352 ; (7) T.M., vol. 4, 1899, p.

213; (8) P.Z., vol. 4, p. 661; (9) M.Z., vol. 23, 1906, p. 114; (10) P.T., vol. 205 A, 1906, p. 61; (11) P.Z., vol. 5, p. 26o; (12) C. Chree, P.T., vol. 206 A, p. 299; (13) Annual volumes, Greenwich Magnetical and Meteorological Observations; (14) M.Z., vol.

8, 1891, p. 357; (15) M.Z., vol. 7, 1890, p. 319 and vol. 8, 1891, p. 113; (16) Annual volumes, Annaes do Obs. do See also:

INFANTE (Spanish and Portuguese form of Lat. infans, young child)

Infante D. Luiz; (17) Annual Reports, Central Meteorological Observatory of See also:

JAPAN

Japan; (18) Observations made at the Mag. and Met. Obs. at Batavia, vol. 18, 1895; (19) J. D. Everett, P.T., vol. 158, 1868, p.

347; (20) M.Z., vol. 6, 1889, p. 95; (21) A. B. Chauveau, See also:

Ann. bureau central metiorologique, Paris, annee 1900, "Memoires," p. CI; (22) V. Conrad, S., 113, p. 1143; (23) P. B. ZOlss, P.Z., vol. 5, p. 260; (24) T.M., vol.

7, 1902, p. 89; (25) Revue generale See also:

des sciences, 1906, p. 442 ; (26) T.M., vol. 8, 1903, p. 86. and vol. 9, 1904, p. 147 ; (27) S., 93, p. 222 ; (28) M.Z., vol. 22, 1905, p. 237; (29) P.Z., vol. 4, p. 632; (30) Phil.

Mag., vol. 20, 1885, p. 456; (31) Expedition polaire finlandaise, vol. 3 (See also:

HELSINGFORS (Finnish Helsinki)

Helsingfors, 1898); (32) A. See also:

PAULSEN, FRIEDRICH (1846-1908)

Paulsen, See also:

Bull. de l'Acad. ... de Danemarke, 1894, p. 148; (33) Wied. Ann., vol. 46, 1892, p. 584; (34) P.T., vol. 191 A, p. 187; (35) M.Z., vol.

5, 1888, p. 95; S•, 99, p. 421; T.M., vol. 4, 1899, p. 15; (36) Camb. Phil. Soc. Proc., vol. II, p. 428, and vol. 12, U. 17 and 85; (37) P.Z., vol.

4, pp. 267 and 873; (38) E. R. v. hweidler, S., 113, p. 1433; (39) S., III, July 1902; (40) Veroffentl. des Kg. Preuss. Met. Inst., 1904 ; (41) P.Z., vol. 5, p. 1o6; (42) S., 114, p. 198; (43) P.Z., vol. 4, p. 871; (44) P.Z., vol.

4, p. 93; (45) M.Z., vol. 23, 1906, p. 229; (46) S., 114, p. 1705; (47) S., 114, p. 399; (48) P.Z., vol. 4, p. 522; (49) S., 113, p. 1455; (50) P.Z., vol. 4, p. 627; (51) P.Z., vol. 4, p.

90; (52) S., 114, p. 151; (53) M.Z., vol. 23, 1906, p. 253; (54) P.Z., vol. 5, p. 749; (55) M.Z., vol. 23, 1906, pp. 53 and 339; (56) P.Z., vol. $ p. 11; (57) P.Z., vol. 5, p. 591; (58) T.M., vol.

9, 1904, p. 49; (59) P.Z., vol. p. 295 ; (60) P.Z., vol. 5, p. 504; (61) T.M., vol. 10, 1905, p. 65; (62) S., 114, p. 1377; (63) Camb. Phil. Soc. Proc., vol. 13, p.

363; (64) Trans. R.S. Edin., vol. 39, p. 63, and vol. 40, p. 484; (65) Q.J.R. Met. Soc., vol. 24, 1898, p. 31 ; (66) M.Z., vol. 11, 1894, p.

277; (67) Jahrbiicher der Konigl. Ung. Reichsanstalt See also:

FUR (connected with O. Fr. forre, a sheath or case; so " an outer covering ")

fur Met. and Erdmag., vol. 33, 1903, III. Theil with appendix by L. von Szalay; (68) U.S. Dept. of Agriculture, Weather Bureau Bulletin, No. 30, 1901; (69) M.Z., vol. 19, 1902, p. 297; (70) Q.J.R. Met. Soc., vol. 15, 1889, p.

140; (71) M.Z., vol. 20, 1903, p. 227; (72) M.Z., vol. 20, 1903, p. 522; (73) M.Z., vol. 23, 1906, p. 367; (74) M.Z., vol. 22, 1905, p. 175; (75) J. Hegyfoky, M.Z., vol. 20, 1903, p. 218; (76) M.Z., vol.

22, 1905, p. 575; (77) S. Arrhenius, M.Z., vol. 1888, p. 348; (78) G. Hellmann, M.Z.; vol. 22, 1905, p. 223; (79) M.Z., vol. i 1, 1894, P. 239; (80) M.Z., vol. 23, 1906, p. 468; (81) See also:

Berlin Sitz., 1889, No. 16; (82) A.

J. Henry, U.S. Dept. of Agriculture Bull., No. 26, 1899; (83) M.Z., vol. 16, 1899, p. 128; (84) K. Sven. See also:

Vet. Akad. Hand., Bd. 19, No. 8, Bd.

20, No. 6, Bd. 31, Nos. 2 and 3; (85) M.Z., vol. 11, 1894, p. 230; (86) Nature, vol. 65, 1902, p. 367; (87) M.Z., vol. 8, 1891, p. 321; (88) Brit. Assoc. See also:

REPORT (O.Fr. report or raport, modern rapport, from O.Fr. reporter, mod. rap porter, Lat. reportare, to bring back, in poetical use only, of bringing back an account, news, &c.)

Report for 1898, p.

8o8, also Electricity in Agri-culture and See also:

Horticulture (London, 1904). (C.

End of Article: ATMOSPHERIC ELECTRICITY

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