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Fluctuations in the Atmospheric Inertia: 1873–1950 PDF

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METEOROLOGICAL MONOGRAPHS BOARD OF EDITORS Assistant Editor Editor-in-Chief Assistant to the Editor THOMAS A. GLEESON WERNER A. BAUM WHEATON M. CoWARD, JR. Florida State University Florida State University American Meteorological Society Associate Editors DAVID ATLAS F. N. FRENKIEL jEROME NAMIAS A. F. Cambridge Research Center J. Hopkins Applied Physics Lab. U. S. Weather Bureau w. GERALD L. BARGER LAWRENCE GATES HANS NEUBERGER U. S. Weather Bureau University of California at L.A. Pennsylvania State University LOUIS J. BATIAN JOSEPH J. GEORGE CHESTER W. NEWTON University of Arizona Eastern Air Lines University of Chicago FREDERIC A. BERRY MAURICE H. HALSTEAD HANS A. PANOFSKY Aerometric Research Inc. Navy Electronics Laboratory Pennsylvania State University RoscoE R. BRAHAM, JR. BERNHARD HAURWITZ NORMAN G. PHILLIPS University of Chicago University of Colorado Mass. Institute of Technology RICHARD A. CRAIG SEYMOUR L. HESS RICHARD J. REED Florida State University Florida State University University of Washington GEORGE P. CRESSMAN HENRY G. HouGHTON HERBERT RIEHL U. S. Weather Bureau Mass. Institute of Technology University of Chicago A. NELSON DINGLE WOODROW C. JACOBS HENRY STOMMEL University of Michigan Library .of Congress Woods Hole Ocean. Instn. GORDON E. DUNN HELMUT E. LANDSBERG VERNER E. SUOMI U.S. Weather Bureau U. S. Weather Bureau University of Wisconsin ROBERT G. FLEAGLE JAMES E. MILLER HARRY WEXLER University of Washington New York University U. S. Weather Bureau • METEOROLOGICAL MONOGRAPHS, a serial publication of the American Meteorological Society, serves as a me dium for original papers, survey articles, and other material in meteorology and closely related fields; it is intended for material which is better suited in length or nature for publication in monograph form than for publication in the journal of Meteorology, in the Bulletin of the American Meteorological Society or in Weatherwise. A METEOROLOGICAL MONOGRAPH may consist of a single paper or of a group of papers concerned with a single general topic. • INFORMATION FOR CONTRIBUTORS Manuscripts for the METEOROLOGICAL MONO 3. Table of contents. Chapter, section, and subsec GRAPHS should be sent directly to the Editor: Werner tion headings should all be listed in the table of con A. Baum, Florida State University, Tallahassee, Florida. tents. Manuscripts may be submitted by persons of any na 4. Title, author's name and affiliation. The affiliation tionality who are members or nonmembers of the So should be stated as concisely as possible and should not ciety, but only manuscripts in the English language can constitute a complete address. The date of receipt of be accepted. Every manuscript submitted is reviewed the manuscript is supplied by the editor. and in no case does the editor advise the author as to acceptability until at least one review has been obtained. 5. Abstract. This should summarize the principal hy Authors will receive galley proof but not page proof. potheses, methods, and conclusioiiS of the mvestigation. It should not include mathematical symbols or refer Manuscripts. The manuscript must be comJ?lete and ences to equation numbers, since the abstract is some in final form when submitted. It must be origmal type times quoted verbatim in abstracting or reviewing jour written copy on one side only of white paper sheets nals. 8Y2 X II inches, coiiSecutively numbered; double spac 6. Text. For one of a group of papers which together ing and wide margins are essential. Carbon copy and constitute a MONOGRAPH, 1t is sufficient to divide the single spacing are not acceptable. text into sections, each with a separate heading, num bered consecutively. The section heading should be Each manuscript may include the following compo placed on a separate line, flush with the margin, and nents, which should be presented in the order listed. Of these, the table of contents; title, author's name and should not be underlined. Subsection headings, if needed, should be located at the beginning of certain affiliation; abstract; text; references; and legends are paragraphs and underlined. obligatory. 7. References. References should be arranged alpha I. Title page. This will be prepared by the editor betically and designated by numbers. The numbers are if the manuscript is accepted for publication. enclosed by brackets in the text but not in the alpha betical listing. When two or more references are in 2. Preface or foreword. A preface may be contrib uted by the spoiiSors of the investigation, or by some vc;>lve~, sepa:at~ the numbers by semicolons: thus, "pre VIous mvestigatwns [3; 12; 27] have shown ..." other interested group or individual. The preface should indicate the ongin of the study and should pre Each reference listed should be complete and in the sent other facts of general interest which emphasize following form. For an article: author(s), year, title of its importance and significance. article, title of serial publication (underlined), volume Continued on Cover !J METEOROLOGICAL MONOGRAPHS Volume 4 May 1961 Number 24 FLUCTUATIONS IN THE ATMOSPHERIC INERTIA: 1873-1950 by El Sayed Mohammed Hassan PUBLISHED BY THE AMERICAN METEOROLOGICAL SOCIETY 4 5 8 E A C 0 N ST., 80S T 0 N 8, MASS. METEOROLOGICAL MONOGRAPHS BOARD OF EDITORS Assistant Editor Editor-in-Chief Assistant to the Editor THOMAS A. GLEESON WERNER A. BAUM WHEATON M. COWARD, JR. Florida State University Florida State University American Meteorological Society Associate Editors DAVID ATLAS F. N. FRENKIEL JEROME NAMIAS A. F. Cambridge Research Center J. Hopkins Applied Physics Lab. U. S. Weather Bureau GERALD L. BARGER W. LAWRENCE GATES HANS NEUBERGER U. S. Weather Bureau University of California at L.A. Pennsylvania State University LOUIS J. BATTAN JOSEPH J. GEORGE CHESTER W. NEWTON University of Arizona Eastern Air Lines University of Chicago FREDERIC A. BERRY MAURICE H. HALSTEAD HANS A. PANOFSKY Aerometric Research Inc. Navy Electronics Laboratory Pennsylvania State University RoscoE R. BRAHAM, JR. BERNHARD HAURWITZ NORMAN G. PHILLIPS University of Chicago University of Colorado Mass. Institute of Technology RICHARD A. CRAIG SEYMOUR L. HESS RICHARD J. REED Florida State University Florida State University University of Washington GEORGE P. CRESSMAN HENRY G. HOUGHTON HERBERT RIEHL U. S. Weather Bureau Mass. Institute of Technology University of Chicago A. NELSON DINGLE WooDRow C. JAcoBs HENRY STOMMEL University of Michigan Library of Congress Woods Hole Ocean. Instn. GORDON E. DUNN HELMUT E. LANDSBERG VERNER E. SUOMI U. S. Weather Bureau U. S. Weather Bureau University of Wisconsin ROBERT G. FLEAGLE JAMES E. MILLER HARRY WEXLER University of Washington New York University U. S. Weather Bureau METEOROLOGICAL MONOGRAPHS, a serial publication of the American Meteorological Society, serves as a medium for original papers, survey articles, and other material in meteorology and closely related fields; it is intended for material which is better suited in length or nature for publication in monograph form than for publication in the journal of Meteorology} in the Bulletin of the American Meteorological Society or in Weatherwise. A METEOROLOGICAL MONOGRAPH may consist of a single paper or of a group of pa pers concerned with a single general topic. ISBN 978-1-940033-50-1 (eBook) DOI 10.1007/978-1-940033-50-1 FLUCTUATIONS IN THE ATMOSPHERIC INERTIA: 1873-1950 El Sayed Mohamed Hassan Cairo University' TABLE OF CO~TE!\'TS will vary because of the variable storage of atmospheric water vapor. Other effects are comparatively small. 1. INTRODUCTION ................. . 2. THE VARIABLE LOAD ............. . According to Bannon and Steele (1957), the seasonal 3. OCEAN YIELDING ................ . 1 variation is given by 4. THE ATMOSPHERIC INERTIA ...... . 1 5. THE DISTRIBUTION OF STATIONS .. 2 V(t) = - 0.17 cos 0 - 0.08 sin 0 (1) 6. DATA ............................ . 4 7. TABULATED VALUES ................ . 5 where 0 is the sun's longitude, varying from 0 deg on 8. HARMONIC EXPRESSIONS ........... . 27 1 January to 360 deg on 31 December. APPENDIX .......................... . 27 A. List of all stations used in the computation. 27 B. Sea level correction. . . . . . . . . . . . . . . . . . . . . . . . . . . 36 3. Ocean yielding C. The mean of the pressure record ...... . 39 D. Rejected data ................................ . 40 In the frequency range under consideration here, it would appear that the ocean responds to atmospheric pressure as an inverted barometer (M unk and Mac 1. Introduction Donald, 1960; §9.3). Consequently, departures of the In a study of the meteorological contribution to total load on the sea floor are everywhere the same at ward irregularities in the rotation of the earth, Munk a fixed time, but the departures vary in time because and Hassan (1961) have evaluated the seasonal terms of the variation in the fraction of the atmosphere in the moments and products of atmospheric inertia that lies above oceans. Let q (t) designate the value 0 and the power spectrum of the non-seasonal products of q(O, A; t) for oceanic areas. Then of inertia. For that purpose, mean monthly values r f. were computed from all available station-level pres + SV(t) q(O, A; t)ds q(O, A; t)ds sures since 1873. Calculations were extensive and per ~ Land Oceans formed on the IBM 709 computer at the University (2) of California at Los Angeles. The resulting time series constitute a description of some integral properties of Here Anm, Bnm designate the amplitudes of the the global atmosphere-in particular, of the coeffi spherical harmonics of an expansion of a function cients of the second spherical harmonic of the variable F = q(O, X; t) over land and F = 0 over oceans. surface pressure. In publishing the computed values, Similarly, anm, bnm refer to the expansion of a function we hope that this description of the atmosphere might equal to 1 over oceans and zero over land. The latter be useful to other investigators. coefficients have been evaluated by Munk and Mac Donald (1960, §A.1). 2. The variable load Let q(O, A; t) designate the departure, from the 4. The atmospheric inertia mean, of atmospheric load per unit surface area, as a It is convenient to represent the inertial tensor in function of colatitude 0, east longitude A, and time t. terms of the dimensionless quantities 1/;1, 1/;2, 1/;a. Here Let S = 411"a2 designate the surface area of the earth, f/;1, 1/;2 are components of the atmospheric products of and let ds = a2 sin OdOdA designate a differential sur inertia divided by ( C - A), where A, A, C are the face element. Then three principal moments of inertia of the planet earth. J 1/;1 is the component relative to an axis from the center q(O, X; t)ds = SV(t) of mass through the meridian of Greenwich; 1/;2 is the component relative to an axis 90 deg east of Green Is the departure in total atmospheric mass, and this wich. if;a is the atmospheric moment of inertia divided by C. For further details, we refer to Munk and Mac 1 This work was done while the author was visiting the Scripps Institution of Oceanography. Donald (1960). We then have 1 2 METEOROLOGICAL MONOGRAPHS VoL. 4, No. 24 ::c (p~)z ::c P0I P0o ::c pIl cos Ai p0o :z:: PII sinAi p~ I: P02 P0o ::c P0o P0I ::c (p~)2 ::c p~ coo A; p~ I: PII sin >-.-i p~ I: P20 P0I ::c P0o PII cos\ z: po1 piI cos A; z: (piI coo\) 2 :z:: PII sin Ai p: cos Ai E P20 p: cos A; z: P0o p1I sin ~i z: p10 p: sinAi ::c p11 coo ~i p1I s1. n A· I: (p: ~in A; )2 I: P20 PII sin ).i ::c P0o P0z z: p10 P0z z: p~ coo A; p~ I: PII sinAi p~ E (p~)2 4= ::c p00 Pz1 cos ~i z: p10 Pz1 coo~; z: p11 cos ~i p2I cos ~i z: p11 a1. n x.i p21 cos Ai E P20 PzI cos "-i ::c Poo PzI s1. n ~i z: P0I pi sin A; z: PII cos A; p2I sm. A; :z:: p1I sin Ai p~ Bin Ai l:: P20 p~ sin >..i ::c p00 p22 cos z ~i z: P0I p~ cos 2 A; z: p11 cos A; p2z cos 2 A; z: PI1 sin ).i pi cos 2 X.i E P0z p~ cos 2 ).i :t P0o p2z s1. n 2 ~i z: P0I p~ sin Z ~i z: p1I cos >..i Pz2 s1. n 2 Ai z: p1I s1. n Ai Pz2 s1. n Z ).i l:: P20 Pz2 s1. n 2 Ai FIG. 1. Determinant A arising from the :& IP~lz :& p10 P0o :& PII cos ~i P0o :z: p1I sin ).i P0o z: P0z P0o :& P0o P0I I: IP~lz I: p: cos A; P0I I: pIl 81. 0 ).i P0I :& P20 P0I :& P0o PII cos ~i I: P0I p: cos ~i :& (pIi COB Ai) Z :& PII sin ).i p~ cos ~i :& P20 p: cos Ai :& Poo PII sin ~i I: P0I p: sin ~i I: p1I cos ~i PII ain ).i :& (p: sin~.1 )2 I: P02 PII sin)..1 :& P0o P02 :& P0I P02 :& pIi cos ~i P02 :& PII sin ).i P02 :z:: (p~l2 (.t.AlzI = :& P0o P21 cos ~i :& P0I pi cos ~i :& p11 cos ~i Pz1 coo A; :& PI1 sin ).i PzI cos ).i E P0z p~ cos A; p: :& p~ sin ).i :& p10 Pi sinAi :& pIi cos ).i p~ sin ).i :& PI1 sin ).i p~ sin Ai l:: P20 P2I sin A1. :& p00 pi coo Z ~.,'1 :z:: P0I p~ cos 2 Ai :& P1I CO& ).i p~ cos 2 A; :& PII sin >..i p~ cos 2 ).i l:: Pz0 p~ cos 2 '; :& P0o p~ sin 2 ).i :& P0I p~ sin 2 A; :& pIl cos >..i p~ sin 2 ).i l:: PII sin X.1. p~ sin 2 A.i :z:: P0z p~ sin 2. \i FrG. 2. Determinant (AA)21 arising from the f - _!!_____ { 5. The distribution of stations q(fJ, A; t) sin fJ cos fJ cos Ads "'' (t) C- A Land The stations are not uniformly distributed (fig. 3). + iceans Ads } To evaluate surface integrals, the usual procedure is qo (t) sin fJ cos fJ cos to contour the required quantities as well as possible, to read off representative values for each 5-deg square for example, multiply by sin fJ, and sum. The proce dure is subjective and not suitable for machine calcu lations. Assume a network of observation stations not We now substitute for q0(t) from (2), and this allows uniformly distributed on the earth's surface. Denote us to evaluate 1/1 (t) from measurements over land only: 1 the coordinates of station i by fJ;, A;, the total number of stations being I. Let F;(t) be the atmospheric (3) pressure departure for the continental station i (F = 0 over oceans). It is required to approximate F;(t) by a function Similarly, N f;(t) = L L I[Anm(t)cos (mA;) +Bnm(t)sin (mA;)] (4) n=O m=O and such that (5) (6) DECEMBER 1960 METEOROLOGICAL MONOGRAPHS 3 l: p~ coo ki p~ :!: p~ sin >.i p~ l: P22 cos 2 >.i P0o :!: p22 S.l n 2 ki P0o I: p~ cos ~i p~ :!: p~ sin ).i P0I :!: pi coo 2 ki P0I l: Pz2. n.n 2 >.i P0I l: p~ cos ki ~ cos ki l: p~ sin >.i p~ coo ki :!: p22 cos 2 >.i PII cos >.i :!: p22 u.n 2 >.i p1I cos >.1 l: p~ cos >.i p~ sin >.i :!: p~ sink; PII sin ).i l: p22 cos 2 >.i pI1 sin >.i :!: P22 n.n 2 >.i PII Bin)..1 l: p~ cos '; p~ l: p~ sin >.i P20 l: p22 cos 2 >.i Pz0. l: P22 n.n 2 ki P20 .E (p~ cos >.i)2 :!: p~ sin >.i p~ cos ki I: p22 cos 2 >.i p2I cos >.; :!: Pz2. S.l n 2 ki p2I coo k; l: p~ coo >.i p~ sin k; I: (p~ sin >.i )2 .E Pz2. cos 2 >.i p2I S.l n '; :!: P2z. o.m z. >.i p2I sm. ki l: p~ cos ki p~ cos 2 ki :!: p2I s1. n >.i p~ cos 2 .i I: 1p 22 cos 2 >.i) 2 :!: p22 n.n z. >.i p22 cos 2 >.i l: p~ cos >.i p~ sin 2 >.1 :!: p~ sin >.i p~ sin 2 >.i :!: p~ cos 2 '; Pz2 st. n 2 X.i :!: ( p22 sm. 2 >.1) 2 right-hand side of the system of eq (7). l: Pzl sin >l. .P0o :!: p22 cos 2 >.i p00 z; P22 sin 2 ).l. Po0 l: Fi p~ z; P21 sm. ';PI0 E p22 •cos 2 >.i p01 z; P22 sin 2 ).l. P0I .E F1 p1I cos >-; .E Pz1 st. n x.i p 1I cos x.i l: p22 cos 2 >.; p1i cos >-; :!: Pz2 st. n 2 ).i PII cos ),i l: F.l p11 sin ).l. :!: PzI S.l n li p1I s1. n x.i l: p22 cos 2 >.; p-11 sin '; :!: Pz2 s1. n 2 Xi PI1 sin ).i ,!; F.l P20 Z: p~ sin >.i p~ Z: p22 cos 2 li.; p20 :!: Pz2 st. n 2 x.i p20 i: F.l P2I cos,\.l z; Pz1 st. n \i p2I cos ki z; p22 cos 2 >.1 PzI cos ,1 .E P22 sin 2 ).i p2I cos xi z; F.l P2I sin x.1. Z: p(!p ~ sin},1)2 .<: p~ cos 2 >-; p~ sin >.1 :!: Pz2 s1. n 2 \i PzI sin ).i i: F.l Pz2 cos 2 x.l I; sin hi p~ cos 2 X.i z: (p-; cos 2 >l. .)2 :!: P22 sin 2 )..i p22 cos ).i :!: F.l Pz2 sin 2 >.l. 2: p~ sin Ai p~ sin 2 \ i: Pz2 cos 2 A.i p22 st. n 2 \ :!: (p~ sin 2 >.1)2 system of eq (7) when solving for A21• is a minimum. The calculation is carried out for one month at a time. To simplify the notation, we write F;, j;, A,m, Bnm for F;(t), j;(t), A,m(t), Bnm(t). Fur thermore, Pnm (cos fJ;) is designated by (pnm),. By (7) to{~::}. minimizing (6) with respect we obtain and the coefficients Ak;, Bk; are independent. Hence, the value of any one coefficient (A 2\ say) does not depend on the number of terms to which the expansion is carried. or For the case of nonuniformly distributed stations, the entire system of eq (7) has to be solved. The value of any one coefficient (A 21, for example) now depends on the number of terms to which the expansion is carried. :E LN L" {[Anmcos (mX;)+Bnmsin (mX;)](pnm)} We have chosen to evaluate all terms up to and in i n=O m=O cluding degree two. This involves the nine coefficients: X [ { c.o sjX~ ; f (Pk0i ] . Ao0; At0, At1; A2°, A2\ A22. Slll)Ai Bt1; B2\ B22. For the case of uniformly distributed stations, the The coefficients A0°, A2°, A2\ B21 are required in the summation of terms containing Pnmpki will vanish expressions for t/1, and it seems reasonable to choose a except when n = k and m = j. In that case, system (7) that includes all terms up to degree two. 4 METEOROLOGICAL MONOGRAPHS VoL. 4, No. 24 ANTARCTIC 9()'Yf 0 FIG. 3. Positions of stations used in the computation of excitation functions. We find that (a) Atlantic Ocean: Spitzbergen, Iceland, Green land, Resolution Island, Baffin Island, Perrin (8) Islands, The British Isles, Ireland, Cuba, Haiti and Trinidad. where A is a ninth order determinant given by fig. 1. (b) Indian Ocean: Ceylon and Madagascar. The summation is all terms of the determinant over i. (c) Pacific Ocean: The Japanese Islands, The East The terms of (AA)nm can be found from A by replacing Indies, Indonesia, New Zealand, and Tasmania. the column L: (pnm cos mXi)2 by the left-hand side of eq (7). As an example, (AA)l is given by fig. 2. (2) Station-level pressure was used whenever reported. (3) When only sea-level pressure was reported, the 6. Data correction to bring it up to station level was calcu All the data have been taken from the Smithsonian lated. The known station height and the mean monthly Miscellaneous Collections, Vols. 79, 90, and lOS and temperature were used, and the correction was calcu from the World Weather Records published by the lated with the help of the Smithsonian Meteorological Weather Bureau. The latter publication is a continua Tables (Fifth Revised Edition). The record was used tion of the Smithsonian volumes. In the majority of only when the maximum seasonal variation of the the cases, the pressure in all these volumes has been correction term was less than 10 per cent of the maxi published for the station level. All the data were mum variation of the sea-level pressure. This cri accorded equal weight, even though there are large terion limits the use of sea-level pressure to stations differences in precision. In spite of the obviously rather near sea level. When the station level changed enormous effort to produce a homogeneous record for during the length of the record, the lowest value was any one station, there are, in some cases, variations taken for this calculation. in the level of the instrument. In some cases, correc (4) Calculations were started for the year 1873, the tions are entered explicitly. In other cases, it is not first year when the number of stations exceeded SO clear whether corrections have been made. A list of (fig. 4). A graph showing the growth of number of the large number of minor decisions in the reduction stations is shown in fig. 4, and a map showing the of the observations are included in the appendix. positions of all stations used in the computation is The following rules are followed in processing the shown in fig. 3. data: (S) The mean pressure was calculated on an IBM (1) Island stations were not used when the area of 6SO for each station using all published monthly the island was less than ten degrees square, except means whenever possible. In some instances, the for islands close to continents. The islands used are: homogeneity of the whole record could not be ascer- DECEMBER 1960 METEOROLOGICAL MONOGRAPHS 5 500r----,,---,l---yl---yi---,-I---,-I-"-TI---..-., the computation according to the following scheme: .. · 0 90E 180E 270E 0 .· . Northern hemisphere Col. 3 4 6 5 Southern hemisphere 7 8 10 9 - 400 f- ....... Thus, . . I- ... ······· - column 3 4 5 6 7 8 9 10 1 2 3 4 5 6 7 8 ... .. .. !' •••••• - 300 t- .. .. means that in the northern hemisphere there is 1 sta .. - tion between 0 and 90E, there are 2 stations between t- .. .. . 90E and 180E, 3 stations between 0 and 90W, and 4 .. stations between 90W and 180W; in the southern 200 - - hemisphere there are 5 stations between 0 and 90E, 6 .. · - stations between 90E and 180E, 7 stations between 0 I- and 90W, and 8 stations between 90W and 180W. ._ .. .·· The remaining columns give 100 - I- - These have been evaluated according to eq (3) and I I _l _j_ I I I (5) for the following four models: 1880 1900 1920 1940 FIG. 4. Number of stations used in the computation of I. Col. 11-13 Anm, Bnm, from (7), V=O excitation functions. II. 14-16 Anm, Bnm, from (7), v~o III. 17-19 Anm, Bnm, from (8), V=O tained, and the mean was calculated for different IV. 20-22 Anm, Bnm, from (8), v~ o. portions separately. In most cases, the mean was based on more than ten years of record. Only in 60 out Thus, for Models I and II, no allowance is made for of 567 stations was the record shorter than a decade. the uneven distribution of stations. In Models III (6) The reported data were used without correc and IV, this has been taken into account. For I and tions. Data were rejected only in cases of obvious III, the variation in water vapor is neglected. The errors. No attempts were made to smooth the records time series plotted in fig. 5 (pp. 26-27) correspond to or to correct the data beyond the corrections that Model IV. have already been published. The year 1999 at the end of the table gives if/ calcu lated from the means of all station records. For com 7. Tabulated values parison, we include lit calculated by taking the means The first two columns refer to year and month. of allif/(t). This mean has been taken over two periods, Columns 3 to 10 give the number of stations used in 1873 to 1950 and 1900 to 1950.

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