k JUL 13irq:3 



fesures 



Vol 



,44. 



JULY 7, 1893. 



Single Copies, Ten Cents. 

 13.50 Per Year, in Advance. 



CONTENTS. 



"Htdrazoic Acid : A New Form of Apparatus 

 FOR Its Preparatio2^ ; "Its Physiological 

 Action. Cyril 6. Hopkins 1 



On Pkotopterus Annectens. B. W. Shufeldt. 2 



Observations on a Cyclone Near 'Williams- 

 town, Kansas. E. H. S. Bailey 3 



Notes on the Copepoda of Wisconsin, C. 



Dwight Marsh 3 



The Hillock and MorND Formations of South- 

 ern California. Daniel Cleveland 4 



Current Notes on Anthropology.— XXXI. 



D. G. Brinton, Editor 4 



Notes and News — 5 



Notes on the Flora of Long Island. Smith 

 Ely JelUffe 6 



Consumption Among the Colored People of 



the Southern States. G. W. Hubbard.. 6 



Xetters to the Editor 7, 8, 9, 10, 11, 12 



Book Reviews 12, 13 



Among the Publishers 13 



Entered at the Post-Offlee of New York, N.Y., as 

 Second-Olasa Mail Matter. 



Walker Prizes in Natural History. 



The Boston Society of Natural History 



offers a first prize of from S60 to $100 and a secood 

 prize of a sum not exceeding S50 for the best me- 

 moirs, in English, on one of the following sub- 

 jects: 



1. The relations of inflorescence to cross-fertiliza 

 tion illustrated by the plants of Eastern Massa. 

 chusetts. 



2. "What depths of formerly overlying rocks, now 

 removed by denudation, may be inferred from the 

 structure of various rocks in Eastern Massachu. 

 setts ? 



3. Experiments affording evidence for or against 

 the theory of evolution. 



Each memoir must be accompanied by a sealed 

 envelope enclosing the author''s name and super- 

 scribed by a motto corresponding to one borne by 

 the manuscript, and must be handed to the Secre- 

 tary on or before April 1, 1894. 



Prizes will not be awarded unless the memoirs are 

 of adequate merit. 



SAMUEL HENSHAW, Secretary. 



Boston, July 3, 189S. 



ROSE POLYTECHNIC INSTITUTE, 



Terre Hante, Ind. A College of Engineering. 

 Well endowed, well equipped. Courses in Me- 

 chanical, Electrical, Civil Engineering, and Chem- 

 istry. Extensive Machine Shops. Laboratories, 

 Drawing Rooms, Library. Expenses low. Address 

 H. T. EDDY, President. 



Tie Batrachians and Reptiles of Indiana. 



A Work of 204 pages, with 8 plates of 12 figures. 

 Contains full descriptions of nearly one hundred 

 species of Batrachians and Reptiles, together with 

 abundant notes on their habits. The identification 

 of the species made easy by means of analytical 

 tables. By O. P. Hay, Ph.D. Price, in paper cover, 

 postpaid, SI. 00. 



Bowen-Merrill Book Co , Indianapolis, Ind. 



VSEFlTIi HAND-BOOKS. 



The Ornamental Penman's Pocketbook of Alpha- 

 bets, for sign-writers, engravers, stone-cutters and 

 draftsmen, 20 cts. A System of Easy Lettering, by 

 Howard Cromwell, 50 ots. Practical Electrics : A 

 Universal Handybook on Every-day Electrical Mat- 

 ters, 135 pp., fully illustrated. 12mo, cloth. "5 cts. 

 Notes on Design of Small Dynamo, by G. Halliday, 

 79 pp., with a number of plates to scale. 18mo, cloth, 

 $1. The Phonograph and How to Construct It, by 

 W. Gillett, 8r pp., 12 folding plates, 12mo, cloth, S3. 

 SPON & CHAMBERLAIN, PubUshers, 12 Cortlandt 

 St., New York. Illustrated and descriptive cata- 

 logues, 10 cts. 



NEW METHOD OF PROTECTING BUILDINGS FROM LIGHTNING. 

 SPARE THE ROD AND SPOIL THE HOUSE! 



lilcfJitniiirf Destroys. Shall it be Your Souse or a Pound of Copper? 



PROTECTION FROM LIGHTNING. 

 What is the Problem ? 



In seeking a means of protection from llghtniog-dlscharges, we have In view 

 two objects,— the one the prevention of damage to buildings, and the other 

 the prevention of Injury to life. In order to destroy a building in whole or In 

 part, It is necessary that work should he done ; that is, as physicists express 

 Ir, energy is required. Just before the lightning-discharge takes place, the 

 energy capable of doing the damage which we seek to prevent exists in the 

 column of air extending from the cloud to the earth in some form that makes 

 It capable of appearing as what we call electricity. We will therefore call it 

 electrical energy. What this electrical energy is, it is not necessary for us to 

 consider In this place ; but that it exists there can be no doubt, as it manifests 

 Itself in the destruction of buildings. The problem that we have to deal with, 

 therefore, is the conversion of thld energy into some other form, and the ac- 

 ■complishment of this In such a way as shall result in the least injury to prop- 

 erty aud life. 



Why Have the Old Rods Failed? 



When lightning-rods were first proposed, the science of energetics was en- 

 . tirely undeveloped ; that is to say, in the midJle of the last century scientific 

 iflen had not come to recognize the fact that the different forms of energy — 

 heat, electricity, mechanical power, etc.— were convertible one Into the other, 

 and that each could produce just so much of each of the other forms, and no 

 more. The doctrine of the conservation and correlation of energy was first 

 clearly worked out in the early part of this century. There were, however, 

 some facts known in regard to eleclrlclty a hundred and forty years ago ; and 

 among these were tbe attracting power of points for an electric spark, and the 

 conducting power of metals. Lightning-rods were therefore introduced with 

 the idea that the electricity existing In the lightning-discharge could be con- 

 veyed around the building which it was proposed to protect, and that the 

 building would thus be saved. 



The question as to dissipation of the energy Involved was entirely Ignored, 

 naturally ; and from that time to thls,*in spite of the best endeavors of those 

 Interested, lightning-rods constructed in accordance with Franklin's principle 

 have not furnished satisfactory protection. The reason for this is apparent 

 when it is considered that the electrical energy existing In the atmosphere 

 before the discharge, or, more exactly, in the column of dielectric from the 

 cloud to the earth, above referred to, reaches its maximum value on the sur- 

 ■face of the conductors that chance to be within the column of dielectric ; so 

 ■ that the greatest display of energy will be on the surface of the very lightning- 

 rods that were meant to protect, and damage results, as so often proves to be 

 the case. 



It will be understood, of course, that this display of energy on the surface 

 ■of the old lightning-rods Is aided by their being more or less Insulated from 

 the earth, but in any event the very existence of such a mass of metal as an 

 old lightning-rod can only tend to produce a disastrous dissipation of electrical 

 energy upon its surface,— *' to draw the lightning," as It Is so commonly put. 



Is there a Better Means of Protection? 

 Having cleared our minds, therefore, of any idea of conducting electricity, 

 and keeping clearly in view the fact that in providing protection against light- 

 ning we must furnish some means by which the electrical energy may be 

 harmlessly dissipated, the question arises, " Can an Improved form be given 

 to the rod, so that It shall a'd In this dissipation ? "' 



As the electrical energy involved manifests itself on the surface of conduc- 

 tors, the Improved rod should be metallic ; but, instead of making a large rod, 

 suppose that we make It comparatively small in size, so that tbe total amount 

 of metal running from the top of the house to some poiut a little below the 

 foundations shall not exceed one pound. Suppose, again, that we iutroduce 

 numerous insulating joints in this rod. We shall then have a rod that experi- 

 ence shows will be readily destroyed — will be readily dissipated —when a 

 discharge takes place; and it will be evident, that, so far as the electrical en- 

 ergy is consumed In doing this, there will be the less to do other damage. 



The only point that remains to be proved as to the utility of such a rod Is to 

 show that the dissipation of such a conductor does not tend to injure other 

 bodies in its immediate vicinity. On this point, I cau only sav that I have 

 found no case where such a conductor (for Instance, a bell wlre/has been dis- 

 sipated, even if resting against a plastered wall, where there has been any 

 material damage done to surrounding objects. 



Of course, it is readily understood that such an explosion cannot take place 

 In a confined space without the rupture of the walls (the wire cannot be 

 boarded over); but In every case that I have found recorded this dissipation 

 takes place just as gunpowder burns when spread on a board. The objects 

 against which the conductor rests may be stained, but they are not shattered, 



I would therefore make clear this distinction between the action of electri- 

 cal energy when dissipated on the surface of a large conductor and when dis- 

 sipated on the surface of a comparatively small or easily dissipated conductor. 

 When dissipated on the surface of a large conductor, — a conductor so strong 

 as to resist the explosive effect, — damage results to objects around. When 

 dissipated on the surface of a small conductor, the conductor goes, but the 

 other objects around are saved 



A Typical Case of the Action of a Small Conductor. 



Franklin, in a letter to ColUnson read before the London Royal Society, 

 Dec. 18, 1755, describing the partial destruction by lightning of a church-tower 

 at Newbury, Mass , wrote, " Near the bell was fixed an Iron hammer to strike 

 the hours ; and from the tall of the hammer a wire went down through a small 

 gimlet-hole in the floor that the bell stood upon, and through a second floor In 

 like manner; then horizontally under and near tbe plastered celling of that 

 second floor, till it came near a p'astered wall ; then down by the side of that 

 wall to a clock, which stood about twenty feet below the bell. The wire was 

 not bigger than a common knitting needle. The spire was split all to piece*' 

 by the lightning, and the parts flung In all directions over the square in which 

 the church stood, so that nothing remained above the bell. The Ilghtfing 

 passed between the hammer and the clock In the above-mentioned w!re 

 without hurting either of the floors, or having any effect upon them ^except 

 making the gimlet-holes, through which tbe wire passed, a Util ^ bigger), and 

 without hurting the plastered wall, or any part of the building, so far as the 

 aforesaid wire and the pendulum-wire of tbe clock extended; which latter 

 wire was about the thickness of a goose-quUl. From the end of the pendu- 

 lum, down quite to the ground, the buil ling was exceedingly rent and dam- 

 aged. . . . No part of the aforementioned long, small wire, between the clock 

 and the hammer, could be found, except about two iuches that huug to the 

 tall of tbe hammer, and about as much that was fastened to the clock; the 

 rest being exploded, and Its particles dissipated in smoke and air, as gun- 

 powder is by common flre, and had only left a black smutty track on the plas- 

 tering, three or four inches broad, darkest in the middle, and fainter towards 

 the edges, all along the celling, under which it passed, and down the wall.'' 



One hundred feet of the Hodges Patent Lightniug Dlspeller (made under 

 patents of N. D. C. Hodges. Editor of Science) will be maUed, postpaid, to any 

 address, on receipt of five dollars (S5i. 



Correspondence •ioUcifed. Agents u-anted. 



AMERICAN LIGHTNING PROTECTION CO., 



874r Broad^vav, Ne-w York Citv. 



