BAROMETER AND WEATHER GUIDE. BOARD OF TRADE. 1859. COMPILED BY REAR-ADMIRAL FITZROY, F. R. S. _THIRD EDITION. _ (WITH ADDITIONS. ) LONDON: PRINTED BY GEORGE E. EYRE AND WILLIAM SPOTTISWOODE, PRINTERS TO THE QUEEN'S MOST EXCELLENT MAJESTY. FOR HER MAJESTY'S STATIONERY OFFICE. AND SOLD BY J. D. POTTER, _Agent for the Admiralty Charts_, 31, POULTRY, AND 11, KING STREET, TOWER HILL. 1859. _Price One Shilling. _ Transcriber's Note: Minor typographical errors have been corrected without note. However, due to an omission in the original text, the anchor for footnote #4 has been placed in an assumed position. A brief table of contents, though not present in the original publication, has been provided below: PREFACE HOW TO FORETELL WEATHER MARINE BAROMETER . . . A contraction of rules for foretelling weather--in accordance with thefollowing pages--is submitted, for scales of common barometers. RISE | FALL | FOR | FOR | N. ELY. | S. WLY. NW. -N. -E. | SE. -S. -W. | DRY | WET | OR | OR | LESS | MORE WIND. | WIND. | ------ | ------ | EXCEPT | EXCEPT | WET FROM | WET FROM N. ED. | N. ED. | ======================== Add one tenth for each hundred feet above the Sea. * * * LONG FORETOLD--LONG LAST, SHORT NOTICE--SOON PAST. * * * FIRST RISE AFTER LOW, FORETELLS STRONGER BLOW. PREFACE. Many persons have advocated placing barometers at exposed fishingvillages; and the Board of Trade has sanctioned the principle of someassistance by Government to a limited extent, depending on the necessityof each case, and other contingencies, such as the care, publicity, andsetting of the barometers. It was thought advisable to substitute a few words on the scales ofthese instruments in place of those usually engraved (which are not themost suitable), and to compile brief and plain information respectingthe use of weather-glasses. The following pages were prepared; but only the first few were intendedparticularly for this purpose. After writing these, it was suggested that some remarks might be addedfor the benefit of many persons, especially young officers at sea, andthe suggestion was complied with; yet not so as to diminish theportability of this compilation, or increase its price. These remarks, derived from the combined observation, study, andpersonal experience of various individuals, are in accordance, generally, with the results obtained by eminent philosophers. The works of Humboldt, Herschel, Dové, Sabine, Reid, Redfield, Espy, andothers, are appealed to in confirmation of this statement. To obviate any charge of undue haste, or an insufficiently consideredplan--which may be fairly brought against many novelties--the followingtestimony to the first published suggestion of such a measure issubmitted. In the First Report of the Committee on Shipwrecks (1843), at pages 1, 2, 3, the following evidence was printed by order of the House ofCommons. "I think that the neglect of the use of the barometer has led to the loss of many ships. From a want of attention to the barometer, they have either closed the land (if at sea), or have put to sea (being in harbour in safety) at improper times; and in consequence of such want of precaution the ships have been lost, owing to bad weather coming on suddenly, which might have been avoided had proper attention been paid to that very simple instrument. While alluding to the use of barometers, I may remark, that if such weather-glasses were put in charge of the Coast-guard, at the principal stations round the coast, so placed as to allow any one passing by to look at them, they might be the means, not only of preventing ships from going to sea just before bad weather was coming on, but of preventing the great losses of life which take place every year on our coasts (particularly in the Orkney Islands and on the coasts of Scotland and Ireland), owing to fishing vessels and boats going to sea when bad weather is impending. No bad weather ever comes on our coasts without timely warning being given by the barometer. The oldest seaman are often deceived by the look of the weather, but there is no instance on record of very bad weather, such as would have involved loss of life to the extent we have heard of in several years, having come on without the barometer having given timely warning. By the very small expense of an establishment of barometers, so placed as to be accessible to any fishermen, boatmen, or others on the coasts, much loss of life, as well as loss of boats, and even shipping, might be prevented. "What state of the barometer indicates danger?--It varies in different climates according to the range. The range is small between the tropics, but very large in the higher latitudes. In our climate the range is usually about two inches. The barometer falling considerably below its average height is at once an indication that some considerable change is going to take place, and when it falls low, as for instance (in our climate) to near 29 inches, or below 29 inches, a gale is certain to follow. "Are the Committee to understand that you are of opinion that every ship ought to have a barometer on board?--I think that every ship ought to have either a barometer or sympiesometer, which is an efficient substitute for a barometer. "Does the barometer show a sudden change of wind as well as the coming on of bad weather? Supposing a gale of wind is blowing, and you are sailing with a fair wind, does the barometer show any change of wind?--Decidedly. "Supposing the wind was at West-north-west and it shifted suddenly to West-south-west, would the barometer indicate that?--It requires some practice to be able to say _exactly what is likely to take place_ after a change in the barometer; but the principal point for a seaman is, that no violent wind will blow without the barometer giving warning. He may not know exactly from what quarter the wind will come, but no strong wind will come on without warning being given. "You recommend that at the Coast-guard stations there should be a barometer, by means of which people would know when a violent wind was coming on; but as it would not indicate the quarter from which it was coming, would you have the merchant ship always remain in port till the barometer showed fine weather?--Being accustomed to the barometer on our coast, one could tell from what quarter the wind would probably come by the height of the barometer, taken in connexion with its previous height, and the state of the weather, and the strength of winds that had prevailed before. Taking the state of the barometer in connexion with the appearance of the weather one could make a satisfactory conclusion as to the quarter from which any violent wind would come. And the barometer, after very little practice, can be used by any man. There is no difficulty in using it sufficiently to know that danger is coming on; and if danger is coming on, a man refrains, of course, from exposing himself to it; the quarter from which the wind comes being of minor consequence. "With a North-easterly wind, in this part of the world, the barometer stands, on an average, about half an inch higher than with the same strength of wind from the South-westward. All over the world there is a similar difference proportionate to the range of the mercury for which allowance should always be made in considering the height of the barometer. "[1] In the first Number of Meteorological Papers, published by the Board ofTrade, 1857, is the following passage respecting the use ofweather-glasses:-- "The variety of interesting and useful, if not always important, subjects included within the range of meteorology, is not perhaps sufficiently realized in the minds of active participators in the world's stirring work. Irrespective of any scientific object, how much utility is there to all classes in what is commonly called 'weather wisdom'? In our variable climate, with a maritime population, numbers of small vessels, and especially fishing boats, how much life and property is risked unnecessarily by every unforeseen storm? Even animals, birds, and insects have a presaging instinct, perhaps a bodily feeling, that warns them; but man often neglects his perceptive and reasoning powers; neither himself observes, nor attends to the observations of others, unless special inclination or circumstances stimulate attention to the subject. Agriculturists, it is true, use weather-glasses: the sportsman knows their value for indicating a good or bad scenting day; but the coasting vessel puts to sea, the Shetland fisherman casts his nets, without the benefit of such a monitor, and perhaps without the weather wisdom which only a few possess, and cannot transfer to others. "Difficult as it is to foretell weather accurately, much useful foresight may be acquired by combining the indications of instruments (such as the barometer, thermometer, and hygrometer) with atmospheric appearances. What is more varying than the aspect of the sky? Colour, tint of clouds, their soft or hard look, their outline, size, height, direction, all vary rapidly, yet each is significant. There is a peculiar aspect of the clouds before and during westerly winds which differs from that which they have previous to and during easterly winds, which is one only of the many curious facts connected with the differing natures of easterly and westerly currents of air throughout the world, which remain unchanged, whether they blow from sea to land, or the reverse. [2] "Perhaps some of those who make much use of instruments rather undervalue popular knowledge, and are reluctant to admit that a 'wise saw' may be valuable as well as a 'modern instance;' while less informed persons who use weather-glasses unskilfully too often draw from them erroneous conclusions, and then blame the barometer. "Not only are reliable weather-glasses required at the smaller outlying ports and fishing places, but plain, easily intelligible directions for using them should be accessible to the seafaring population, so that the masters of small vessels, and fishermen, might be forewarned of coming changes in time to prepare for them, and thus become instrumental in saving much property and many lives. " _June 1858. _ HOW TO FORETELL WEATHER. Familiar as the practical use of weather-glasses is, at sea as well ason land, only those who have long watched their indications, andcompared them carefully, are really able to conclude more than that therising glass[3] USUALLY foretells less wind or rain, a falling barometermore rain or wind, or both; a high one fine weather, and a low, thecontrary. But useful as these general conclusions are _in most cases_, they are _sometimes_ erroneous, and then remarks may be rather hastilymade, tending to discourage the inexperienced. By attention to the following observations (the results of many years'practice and many persons' experience) any one not accustomed to use abarometer may do so without difficulty. The barometer shows whether the air[4] is getting lighter or heavier, oris remaining in the same state. The quicksilver falls as the air becomeslighter, rises as it becomes heavier, and remains at rest in the glasstube while the air is unchanged in weight. Air presses on everythingwithin about forty miles of the world's surface, like a _much_ lighterocean, at the bottom of which we live--not feeling its weight, becauseour bodies are full of air, but feeling its currents, the winds. Towardsany place from which the air has been drawn by suction, [5] air presseswith a force or weight of nearly fifteen pounds on a square inch ofsurface. Such a pressure holds the limpet to the rock when, bycontracting itself, the fish has made a place without air[6] under itsshell. Another familiar instance is that of the fly which walks on theceiling with feet that stick. The barometer tube, emptied of air, andfilled with pure mercury, is turned down into a cup or cisterncontaining the same fluid, which, feeling the weight of air, is sopressed by it as to balance a column of about thirty inches (more orless) in the tube, where no air presses on the top of the column. If a long pipe, closed at one end only, were emptied of air, filled withwater, the open end kept in water and the pipe held upright, the waterwould rise in it more than thirty feet. In this way water barometershave been made. A proof of this effect is shown by any well with asucking pump--up which, as is commonly known, the water will rise nearlythirty feet, by what is called suction, which is, in fact, the pressureof air towards an empty place. The words on scales of barometers should not be so much regarded forweather indications, as the rising or falling of the mercury; for, if itstand at _Changeable_, and then rise towards _Fair_, it presages achange of wind or weather, though not so great, as if the mercury hadrisen higher; and, on the contrary, if the mercury stand above _fair_and then fall, it presages a change, though not to so great a degree asif it had stood lower: besides which, the direction, and force of wind, are not in any way noticed. It is not from the point at which themercury may stand that we are alone to form a judgment of the state ofthe weather, but from its _rising_ or _falling_; and from the movementsof immediately preceding days as well as hours, keeping in mind effectsof change of _direction_, and dryness, or moisture, as well asalteration of force or strength of wind. * * * In this part of the world, towards the higher latitudes, the quicksilverranges, or rises and falls, nearly three inches--namely, between aboutthirty inches and nine-tenths (30·9), and less than twenty-eight inches(28·0) on extraordinary occasions; but the usual range is from aboutthirty inches and a half (30·5), to about twenty-nine inches. Near theLine, or in equatorial places, the range is but a few tenths, except instorms, when it sometimes falls to twenty-seven inches. The sliding-scale (vernier) divides the tenths into ten parts each, orhundredths of an inch. The number of divisions on the vernier exceedsthat in an equal space of the fixed scale by one. [7] * * * By a thermometer the _weight_ of air is _not_ shown. No air is withinthe tube. None can get in. But the bulb of the tube is full of mercury, which contracts by cold, and swells by heat--according to which effectthe thread of metal in the small tube is drawn down or pushed up so manydegrees: and thus shows the temperature. [8] If a thermometer have a piece of linen tied round the bulb, wettedenough to keep it damp by a thread or wick dipping into a cup of water, it will show less heat than a dry one, in proportion to the dryness ofthe air, and quickness of drying. [9] In very damp weather, with or_before_ rain, fog, or dew, two such thermometers will be nearly alike. For ascertaining the dryness or moisture of air, the readiest, andsurest method is the comparison of two thermometers; one dry, the other_just_ moistened, and _kept so_. Cooled by evaporation as much as thestate of the air admits--the moist (or wet) bulb thermometer shows atemperature nearly equal to that of the other one, when the atmosphereis extremely damp, or moist; but lower at other times, --in proportion tothe dryness of air, and consequent evaporation, --as far as twelve orfifteen degrees in this climate; twenty or even more elsewhere. Fromfour to eight degrees of difference is usual in England; and about sevenis considered healthy for living rooms. The thermometer fixed to a barometer intended to be used only as aweather-glass shows the temperature of air about it nearly--but does notshow the temperature of mercury within exactly. It does so however nearenough for ordinary practical purposes--provided that no sun, nor fire, nor lamp heat is allowed to act on the instrument partially. The mercury in the cistern and tube being affected by cold or heat, makes it advisable to consider this when endeavouring to foretell comingweather by the length of the column. * * * Briefly, the barometer shows weight or pressure of the air; thethermometer--heat and cold, or temperature; and the wet thermometer, compared with a dry one, the degree of moisture or dampness. [10] It should be remembered that the state of the air _foretells_, ratherthan shows present weather (an invaluable fact too often overlooked);that the longer the time between the signs and the change foretold bythem, the longer such altered weather will last; and, on the contrary, the less the time between a warning and a change, the shorter will bethe continuance of such foretold weather. * * * If the barometer has been about its ordinary height, say near thirtyinches, at the sea level, [11] and is steady, or rising--while thethermometer falls, and dampness becomes less--North-westerly, Northerly, or North-easterly wind--or less wind--may be expected. On the contrary--if a fall takes place, with a rising thermometer andincreased dampness, wind and rain may be expected from theSouth-eastward, Southward, or South-westward. A fall, with a low thermometer, foretells snow. Exceptions to these rules occur when a North-easterly wind, with wet(rain or snow) is impending, before which the barometer often rises (onaccount of the _direction_ of the coming wind alone), and deceivespersons who, from that sign only, expect fair weather. When the barometer is rather below its ordinary height, say, belowtwenty-nine inches and nine-tenths (at the sea level _only_), a riseforetells less wind, or a change in its direction towards theNorthward, --or less wet; but when the mercury[12] has been low, say near29 inches--the first rising usually precedes, and foretells, strongwind--(at times heavy squalls)--from the North-westward--Northward--orNorth-eastward--_after_ which violence a rising glass foretellsimproving weather--if the thermometer falls. But, if the warmthcontinue, probably the wind will back (shift against the sun's course), and more Southerly, or South-westerly wind will follow. "Backing" is abad sign, with any wind. The most dangerous shifts of wind, and the heaviest Northerly[13] galeshappen after the mercury first rises from a very low point. Indications of approaching changes of weather, and the direction andforce of winds are shown less by the height of mercury in the tube, thanby its falling or rising. Nevertheless, a height of about 30 inches (atthe level of the sea) with a continuance of it, is indicative of fineweather and moderate winds. The barometer is said to be _falling_ when the mercury in the tube issinking, at which time its upper surface is _sometimes_ concave orhollow. The barometer is _rising_ when the mercurial column islengthening; its upper surface being then, as in _general_, convex orrounded. [14] A rapid rise of the barometer indicates unsettled weather. A slow rise, or steadiness, with dryness, shows fair weather. A considerable and rapid fall is a sign of stormy weather and rain. Alternate rising and sinking show very unsettled weather. The greatest depressions of the barometer are with gales from the S. E. , Southward, or S. W. ; the greatest elevations, with winds from the N. W. , Northward, or N. E. , or when calm. Although the barometer generally falls with a Southerly, and rises witha Northerly wind, the contrary _sometimes_ occurs; in which cases theSoutherly wind is dry and the weather fine; or the Northerly wind is wetand violent. [15] When the barometer sinks considerably, high wind, rain, or snow willfollow: the wind will be from the Northward if the thermometer is low(for the season)--from the Southward if the thermometer is high. Sudden falls of the barometer, with a Westerly wind, are sometimesfollowed by violent storms from N. W. Or North. If a gale sets in from the Eastward or S. E. , and the wind veers by theSouth, the barometer will continue falling until the wind becomes S. W. , when a comparative lull may occur; after which the gale will be renewed;and the shifting of the wind towards the N. W. Will be indicated by afall of the thermometer as well as a rise of the barometer. Three things appear to affect the mercury in a barometer:-- 1. The direction of the wind--the North-east wind tending to raise itmost--the South-west to lower it the most, and wind from points of thecompass between them proportionally as they are nearer one or the otherextreme point. N. E. And S. W. May therefore be called the wind's extreme bearings(rather than _poles_?) The range, or difference of height, of the mercury, due to change ofdirection _only_, from one of these bearings to the other (supposingstrength or force, and moisture, to remain the same) amounts in theselatitudes to about half an inch (shown by the barometer as read off). 2. The amount, taken by itself, of vapour, moisture, wet, rain, hail, orsnow, in the wind or current of air (direction and strength remainingthe same) seems to cause a change amounting, in an extreme case, toabout half an inch. 3. The strength or force alone of wind from any quarter (moisture anddirection being unchanged) is preceded, or foretold, by a fall or rise, according as the strength will be greater or less, ranging, in anextreme case, to more than two inches. Hence, supposing the three causes to act together--in extreme cases--themercury might range from about 31 (30·9) inches to near 27 inches, whichhas happened _occasionally_. Generally, however, as the three act much less strongly, and are less inaccord--ordinary varieties of weather (the wind varying as usual--withmore or less cloudiness, or rain) occur much more frequently thanextreme changes. Another general rule requires attention; which is, that the wind usuallyveers, shifts, or goes round, _with the sun_, (right-handed in northernplaces, left-handed in the southern parts of the world, ) and that, whenit does not do so, or backs, more wind or bad weather may be expectedinstead of improvement. In a barometer the mercury begins to rise occasionally before theconclusion of gale, sometimes even at its commencement, as theequilibrium of the atmosphere begins to be restored. Although themercury falls lowest before high winds, it frequently sinks considerablybefore heavy rain only. The barometer falls, but _not always_, on theapproach of thunder and lightning, or when the atmosphere is highlycharged with electricity. [16] Before and during the earlier part ofserene and settled weather, the mercury commonly stands high, and isstationary. [17] Instances of fine weather, with a low glass, occur exceptionally, butthey are always preludes to a duration of wind or rain, _if not both_. After very warm and calm weather, rain or a storm is likely to occur;or at any time when the atmosphere has been _heated_ much above theusual temperature of the season. Allowance should invariably be made for the previous state of theinstrument during some days as well as hours, because its indicationsmay be affected by remote causes, or by changes close at hand. Some ofthese changes may occur at a greater or less distance, influencingneighbouring regions, but not visible to each observer whose barometer, nevertheless, feels their effect. There may be heavy rains or violent winds beyond the horizon, out ofview of an observer, by which his instruments may be affectedconsiderably, though no particular change of weather occurs in hisimmediate locality. It may be repeated, that the longer a change of wind or weather isforetold by the barometer before it takes place, the longer the presagedweather will last; and, conversely, the shorter the warning, the lesstime whatever causes the warning; whether wind or a fall of rain, hail, or snow, will continue. Sometimes severe weather from an equatorial[18] direction, not lastinglong, may cause no great fall of the barometer, because followed by a_duration_ of wind from polar regions:--and at times it may fallconsiderably with polar winds and fine weather, apparently against theserules, because a _continuance_ of equatorial wind is about to follow. Bysuch changes as these one may be misled, and calamity may be theconsequence if not thus forewarned. The veering of the winds is a direct consequence of the earth'srotation, while currents of air from the polar regions are alternatingor contending with others from the equator. The polar currents are cold, dry, and heavy. Those from the equatorialparts of the world are warm, moist, and comparatively light. Theiralternate or combined action, with the agencies of solar heat andelectricity, cause the varieties of weather that we experience. It is not intended to discourage attention to what is usually called"weather wisdom. " On the contrary, every prudent person will combineobservation of the elements with such indications as he may obtain frominstruments. The more carefully and accurately these two sources of foreknowledge arecompared and combined, the more satisfactory will the results prove. A few of the more marked signs of weather--useful alike to seaman, farmer, and gardener, are the following: Whether clear or cloudy, a rosy sky at sunset presages fine weather; ared sky in the morning, bad weather, or much wind (if not rain):--a greysky in the morning fine weather; a high dawn, wind; a low dawn; fairweather. [19] Soft-looking or delicate clouds foretell fine weather, with moderate orlight breezes;--hard edged oily-looking clouds, wind. A dark, gloomy, blue sky is windy;--but a light, bright blue sky indicates fine weather. Generally, the _softer_ clouds look, the less wind (but perhaps morerain) may be expected;--and the harder, more "greasy, " rolled, tufted, or ragged, the stronger the coming wind will prove. Also, a brightyellow sky at sunset presages wind; a pale yellow, wet:--and thus by theprevalence of red, yellow, or grey tints, the coming weather may beforetold very nearly: indeed, if aided by instruments, almostexactly. [20] Small inky-looking clouds foretell rain; a light scud, driving acrossheavy clouds, wind and rain; but if alone, wind only. High upper clouds crossing the sun, moon, or stars, in a directiondifferent from that of the lower clouds, or wind then blowing, foretella change of wind (beyond tropical latitudes). [21] After fine clear weather the first signs (in the sky) of change areusually small, curled, streaked, or spotty clouds, followed by anovercasting of vapour, that grows into cloudiness. This murkyappearance, more or less oily or watery, as wind or rain will prevail, is a sure sign. The higher and more distant the clouds seem to be, themore gradual, but extensive, the coming change of weather will prove. Generally speaking, natural, quiet, delicate tints or colours, with softundefined forms of clouds, foretell fine weather: but gaudy or unusualhues, with hard, definite outlines, presage rain and wind. Misty clouds forming, or hanging on heights, show wind and raincoming--if they remain, or descend. If they rise, or disperse, theweather will improve, or become fine. When sea birds fly out early, and far to seaward, moderate wind and fairweather may be expected. When they hang about the land, or over it, sometimes flying inland, expect a strong wind, with stormy weather. Asmany creatures, besides birds, are affected by the approach of rain orwind, such indications should not be slighted by the observer ofweather. There are other signs of a coming change in the weather known lessgenerally than may be desirable; and, therefore worth notice here. When birds of long flight, such as swallows and others, hang about homeand fly low--rain or wind may be expected. Also when animals seeksheltered places, instead of spreading over their usual range: when pigscarry straw to their sties; and when smoke from chimneys does not ascendreadily, (straight upwards during a calm, ) an unfavourable change may belooked for. Dew is an indication of fine weather. So is fog. Neither of these twoformations occurs under an overcast sky, or when there is much wind. Onesees the fog occasionally rolled away, as it were, by wind--but notformed while it is blowing. Remarkable clearness of atmosphere, near the horizon; distant objects, such as hills, unusually visible; or raised (by refraction); and what iscalled "a good _hearing_ day" may be mentioned among signs of wet, ifnot wind, to be expected. [22] More than usual twinkling of the stars; indistinctness or apparentmultiplication of the moon's horns; haloes; "wind-dogs;" and therainbow; are more or less significant of increasing wind, if notapproaching rain. [23] Near land, in sheltered harbours, in valleys, or over low ground, thereis usually a marked diminution of wind during part of the night--and adispersion of clouds. At such times an eye on an overlooking height maysee an extended body of vapour below; which the cooling of night hasrendered visible. * * * Although the preceding remarks are probably sufficient for theirprincipal purpose--these pages may fall into the hands of personsfamiliar with the subject, to whom the following observations may beaddressed, as some of the _reasons_ for what has been so briefly, if nottoo positively outlined. As the mercurial column rises with increase of pressure by theatmosphere, and descends when the pressure diminishes, it indicates agreater or less accumulation of air, which, like other fluid, such aswater (when heaped above its average level or reduced below it, fromwhatever cause), --will have a tendency to fall or rise till the generalequilibrium is restored. An observer may be under the centre of suchaccumulation or depression, he may be more or less distant from it, though within the influence of whatever horizontal movement of air maybe caused by such temporary increase or diminution of pressure. Hencethe barometer shows, and generally foretells, changes of wind; but ascomplications always occur, and as changes are of greater or lessextent, affecting or extending through a wider or more limited area, accompanied by hygrometric and electrical alterations, it is extremelydifficult at times to say beforehand what particular change of weatheris to be expected, and at what interval of time; although after theevent the correspondence of barometric changes with those of the weathercan be readily traced. However, notwithstanding occasional perplexity, the general character of weather during the next few days may bepredicted by an observer who understands the nature and use of thisinstrument and the thermometer, and has watched them in the fewimmediately preceding days. In endeavouring to foretell weather, the general peculiarity shouldalways be remembered, that the barometric column usually stands higherwith easterly than it does with westerly winds; and with winds from thepolar regions higher than with those from the direction of the equator. Hence the highest columns are observed with north-east winds in northernlatitudes, and with south-east in the southern hemisphere. In middle latitudes there is an average difference (unreduced orobserved height as read off) of about half an inch, other things beingsimilar, between the heights of the mercury with North-easterly, andwith South-westerly winds. The steadier the column, or the more gradually it moves, the moresettled in character will the weather be, and conversely: because itshows a quiet settled state of the atmosphere; or, if otherwise, thereverse. In the tropics, when the barometric column moves contrary toits usual daily motion, inferior weather may be expected (temporarily), because the usual air currents are disturbed. This regular movement, whether tidal, or otherwise connected with thesun's influence--sensible in tropical latitudes, but more or less maskedelsewhere--amounts to nearly two-tenths of an inch near the equator, thehighest being at about nine, and the lowest near three o'clock. * * * Some movements of the atmosphere may be illustrated by reference to themotion of water drawn off from a reservoir by a small opening below; orby similar _upward_ draught through a syphon; or by a gradual pouring inat the upper surface. From a slight motion at the commencement, affecting only that portion ofthe fluid adjoining either of those places of diminution or repletion, gradually all the water becomes influenced and acquires more or lessrapid movement. But suppose a long reservoir or canal of fluid which hastwo such points of exhaustion or two of such repletion (as imaginedabove), and that one of either is near each end of the vessel. If eachaperture be opened at the same moment, equal effects will be caused ineach half of the fluid towards either end of the vessel, but in themiddle there must be a neutral point at which the water falls, yet hasno horizontal motion. The converse takes place in raising the level. Andin the case of fluid drawn off or diminished in weight at one end whileincreased by repletion at the other, the _whole_ body of water will movesimilarly to that in the former vessel, but unequally. Hence it isevident, that before horizontal motion occurs, an augmentation or adiminution of pressure must take place somewhere more or less remote;and so it is with the lighter fluid atmosphere, --which has centres, lines, or areas of depression towards which currents flow. Such considerations show in some degree why the barometric changesusually precede, but sometimes only accompany, changes of weather: and, though very rarely, occur without any sensible alteration in the windcurrent of the atmosphere. An observer may be near a central pointtowards which the surrounding fluid tends, --or from which it diverges. He may be at the very farthest limit of the portion of fluid that is soinfluenced. He may be at an intermediate point--or he may be betweenbodies of atmosphere tending towards opposite directions. It has been said, that "a whirlwind which sets an extended portion ofthe atmosphere into a state of rapid revolution diminishes the pressureof the atmosphere over that portion of the earth's surface, and most ofall at the centre of the whirl. The depth of the compressing column ofair will, at the centre, be least, and its weight will be diminished inproportion to the violence of the wind. " Yet this has been controvertedwith respect to the _general_ effect of air in horizontal motion, andthe depth of the column in question. Certainly there are two kinds of whirlwinds--one caused by rarefaction, tending to lighten vertical pressure under the vortex, though not, perhaps, under all the current drawn towards it; and the other, aconsequence of opposing winds, which occasion huge eddies or whirlwindsof compression. Some whirlwinds are accompanied by rushes from the upper atmosphere, from the colder regions, which, mingling with warmer and moister airnear the sea, cause dense clouds. About their centre it sometimeshappens that the barometer falls as much as two or three inches, showinga diminution of atmospheric pressure by nearly a tenth part; when itshould be expected, from physical considerations alone, that very denseclouds would be formed. [24] * * * The column of mercury falls about one tenth of an inch for each of thefirst few hundred feet above the sea level, but varying when it becomesmuch more elevated. [25] Due allowance, therefore, should be made inobserving, when on high land. The tides are affected by atmospheric pressure, so much that a rise ofone inch in the barometer will have a corresponding fall in the tides ofnine to sixteen inches, or about one foot for each inch. [26] * * * Vessels sometimes enter docks, or even harbours, where they havescarcely a foot of water more than their draught; and as docking, aswell as launching large ships, requires a close calculation of height ofwater, the state of the barometer becomes of additional importance onsuch occasions. * * * * * To render these pages rather more useful at sea, in _any_ part of theworld, a few words about squalls and hurricanes are here offered to theyoung seaman. Generally, squalls are preceded, or accompanied, or followed by clouds;but the very dangerous "white squall" (of the West Indies and otherregions), is indicated only by a rushing sound, and by white wavecrests. "Descending squalls" come slanting downwards, off high land, [27] or fromupper regions of atmosphere. They are dangerous, being sometimesviolently strong. A squall cloud that can be seen through or under is not likely to bring, or be accompanied by, so much wind as a dark continued cloud extendingbeyond the horizon. How the comparative hardness or softness of cloudsforetells more or less wind or rain, was stated in pages 13 and 14. The expressions "hardening up, " "softening, " or looking "greasy, " arefamiliar to seamen: and such very sure indications are the appearancesso designated, that they can hardly be mistaken. The rapid or slow rise of a squall cloud--its more or less disturbedlook--that is, whether its body is much agitated, and changing formcontinually, with broken clouds, or scud, flying about--or whether themass of cloud is shapeless and nearly quiet, though floating onwardsacross the sky--foretells more or less wind accordingly. An officer of a watch, with a good eye for clouds and signs of changingweather, may save his men a great deal of unnecessary exposure, as wellas work, besides economising sails, spars, and rigging. In some of the "saws" about wind and weather, there is so much truththat, though trite and simple, their insertion here can do no harm. Adverting to the barometer:-- When rise begins, after low, Squalls expect and clear blow. Or:--_First_ rise, after very low, Indicates a stronger blow. Also:--Long foretold, long last: Short notice, soon past. To which may be added:--In squalls-- When rain comes before wind, Halyards, sheets, and braces mind. And:--When wind comes before rain, Soon you may make sail again. * * * Also, generally speaking:-- When the glass falls low, Prepare for a blow; When it rises high, Let all your kites fly. [28] * * * To these short expressions--well known, in practice, to the experienced;a very concise but sure rule may be added, for avoiding the central orstrongest part of a hurricane, cyclone, typhoon, tornado, or circlingstorm. With your face towards the wind, in North latitude, the centre of thecircling, or rotatory storm, will be square to your right. In Southlatitude, square to your left. The apparent veering of the wind, and the approach or retreat of thedangerous central circle, depend on your position in the curvilinearwhirl or sweep. Draw a circle;--mark the direction of the rotation or circulation, by anarrow with the head towards the left hand (against the movement of awatch's hands) in North latitude; but towards the right (or with thehands of a watch) if in South latitude. The direction of the wind, andthe bearing of the centre, show your position in the meteor, for such itis, though perhaps hundreds of miles in diameter; and the veering of thewind, or the contrary, and its change in strength, will show how themeteor is moving bodily--over an extensive region, revolvinghorizontally--or inclined at a certain angle to the horizontal plane. If the observer be stationary, in North latitude, and the centre pass onhis polar side, he will experience a change of wind from Southward bythe West towards North; but if it pass between him and the Equator, thechange will be from Southward by the East towards North; but otherwisein South latitude, as his place in circles sketched will show moreclearly than words. The roughest sketch or diagram, indicating thevarious directions of wind, and the course of the meteor's centre, willshow more plainly than descriptions--which must necessarily vary witheach case, and are tedious. Cyclonology, or really meteorology, is simple enough in these greatcharacteristic effects; but their causes must be the philosopher'sstudy, rather than that of the young practical seaman. Were it not for this reflection, one might endeavour to show how all thegreat Easterly trade winds--the no less important anti-trades, [29] ornearly constant Westerly winds, --and their complicated eddying offsets, are all (on greater or smaller scales) breadths, or zones of atmosphere, alternating, or circulating, or crossing (superposed orlaterally)--between which, at distant intervals, occur those strongeddies, or storms, called hurricanes--typhoons--tornadoes--or cyclones. The great easterly and westerly movements--so clearly shown byphilosophers to be the consequences of cold polar currents of air--warmequatorial currents--and diurnal rotation of the earth;[30] are grandruling phenomena of meteorology--to which storms, and all local changes, occurring but occasionally, are subordinate and exceptional. Furtherinvestigations into electrical and chemical peculiarities will probablythrow additional light, perhaps the strongest, on meteorologicalscience. * * * * * In the previous observations, general reference has been made tomercurial barometers of the ordinary kind; but, excepting theconstruction of the instruments themselves, those observations apply toall barometers, wheel--aneroid--or metallic--and likewise, of course, tothe sympiesometer, which is a modified barometer. But as these fourlast-mentioned instruments are scarcely so familiar as the simplest formof barometer, it may be useful to add a few words about each of them. * * * The WHEEL barometer has a syphon tube, partly filled with mercury, onwhich, at the short or open end of the tube, a float moves, to which aline is attached that moves a wheel, carrying an index. [31] * * * ANEROID barometers, if often compared with good mercurial columns, aresimilar in their indications, and valuable; but it must be rememberedthat they are not independent instruments; that they are set originallyby a barometer, [32] require adjustment occasionally, and may deterioratein time, though slowly. The aneroid is quick in showing the variation of atmospheric pressure, and to the navigator who knows the difficulty, at times, of usingbarometers, this instrument is a great boon, for it can be placedanywhere, quite out of harm's way, and is not affected by the ship'smotion, although faithfully giving indication of increased or diminishedpressure of air. [33] In ascending or descending elevations, the hand ofthe aneroid may be seen to move (like the hand of a watch), showing theheight above the level of the sea, or the difference of level betweenplaces of comparison. [34] The principle on which it is constructed may be explained in a fewwords, without going into a scientific or too minute detail of itsvarious parts. The weight of a column of air, which in a commonbarometer acts on the mercury, in the aneroid presses on a smallcircular metal box, from which nearly all air is extracted; and to thisbox is connected, by nice mechanical arrangement, the hand visible overthe face of the instrument. When the atmospheric pressure is lessened onthe vacuum box, a spring acting on levers, turns the hand to the left, and when the pressure increases, the spring is affected differently, thehand being turned to the right. It acts in any position, but as it_often varies several hundredths with such a change_, it should be helduniformly, while read off. The known expansion and contraction of metals under varyingtemperatures, caused doubts as to the accuracy of the aneroid under suchchanges; but they were partly removed by introducing into the vacuum boxa small portion of gas, as a compensation for the effects of heat orcold. The gas in the box, changing it bulk on a change of temperature, was intended to compensate for the effect on the metals of which theaneroid is made. Besides which, a further and more, reliablecompensation has lately been effected by a combination of brass andsteel bars. [35] METALLIC barometers (in _outer_ shape and size like aneroids) have notyet been tested adequately in very moist, hot, or cold air for asufficient time. They, as well as sympiesometers, are likewise dependentor secondary instruments, and liable to deterioration. For limitedemployment, when sufficiently compared, they may be very useful, especially in a few cases of electrical changes not foretold or shown bymercury. The SYMPIESOMETER is considered to be more sensitive than the marinebarometer, falling sooner, and rising earlier: but this is partly inconsequence of the marine barometer tube being contracted, to preventoscillation or "pumping. " In the sympiesometer a gas is used, whichpresses on the confined surface of the liquid with an uniform pressureat an equal state of temperature. The liquid is raised or depressed byan increase or diminution in the density of the atmosphere, and changeof temperature is allowed for, by the sliding scale of the instrumentbeing always set to agree with the height of the mercury in the attachedthermometer, bringing the _pointer_ on the sliding scale of thesympiesometer to the same degree on the inverted scale (over which itslides) as is indicated by the thermometer. The height of the fluid, asthen shown by the sliding scale, indicates the pressure of theatmosphere. As the instrument is delicate, great care should be taken, in carryingor handling, to keep the top always upwards, and to exclude casual raysof the sun, or a fire, or lamp. Oil sympiesometers seem to be affected more than mercurial, or others, and much more than the barometer, by lightning or electricity. Thatthey, and the hermetically sealed "STORM GLASSES, " are influenced bycauses besides pressure and temperature, appears now to be certain. * * * The daily movement of the barometer may be noted (in a form or table ofdouble entry) at the time of each observation, by a dot at the placecorresponding to its altitude, and the time of observing; which dotshould be connected with the previous one by a line. The resulting freecurve (or zig-zag) will show at a glance what have been the movementsduring the days immediately previous, by which, and not merely by thelast observation, a judgment may be formed of the weather to beexpected. Such a diagram may be filled up by _uncorrected_ observations, itsobject being to serve as a weather guide for immediate use, rather thanfor future investigation. If closely kept up, it will prove to be ofutility, and will in some degree reward the trouble of keeping a regularrecord. For purely scientific objects much more nicety and detail arerequired. * * * * * HESITATION is sometimes felt by young seamen, at first using the vernierof a barometer, for want of some such familiar explanation as thefollowing:-- The general principle of this moveable dividing scale is, that the totalnumber of the smallest spaces or subdivisions of the vernier are madeequal, taken altogether, to one less than that number of the smallestspaces in an equal length of the fixed scale. For example: ten spaces on the vernier being made equal to nine on thescale, each vernier space is one tenth less than a scale space; and ifthe first line or division of the vernier agree exactly with any line ofthe scale, the next line of the vernier must be one tenth of a tenth (orone hundredth) of an inch from agreement with the next _scale_ division;the following vernier line must be two hundredths out, and so on:therefore, the number of such differences (from the next tenth on thescale) at which a vernier line agrees with a scale line, when set, isthe number of hundredths to be added to the said tenth; (in a commonbarometer, reading only to hundredths of an inch). The vernier of a barometer reading to thousandths of an inch, is on asimilar principle, though differently divided. In this application ofit, generally, twenty-five vernier spaces equal twenty-four of the scalespaces, which are each half a tenth, or five hundredths of an inch;therefore, the difference between one of the vernier and one of thescale is two-tenths of a hundredth, or two thousandths of an inch[25)·050(·002]. This is the usual graduation of scientific barometers; but for ordinarypurposes, as weather-glasses, a division, or reading, to the hundredthof an inch is sufficient. When set properly, the vernier straight edge, the top of the mercury, and the observer's eye, should be on the same level; the edge (orpointer) just _touching_[36] the middle and uppermost point of thecolumn. Great care should be taken to look thus square, or at right angles tothe scale. Light, or something white, at the _back_ of the tube, assists inaccurately setting the vernier, and may be shifted about to aid inreading off. * * * THE ANEROID has been recommended, in these pages, as a weather-glass;but it may increase its usefulness to append a table for measuringheights (approximately) by this, or any barometer, which can be comparedwith another, or itself, at a higher or lower station. If the measure of a height rather greater than the aneroid will commonlyshow, be required, it may be _re-set_ thus--When at the upper station(_within its range_), and having noted the reading carefully, touch thescrew behind so as to bring back the hand a few inches (if theinstrument will admit), then read off and start again. _Reverse theoperation when descending. _ This may add some inches of measure_approximately_. * * * * * In the following Table, the difference between the number of feetopposite the height of a barometer, at one station, and that at anotherstation, is their approximate difference of height. TABLE. -----------+-----------++-----------+-----------++-----------+----------- Barometer | Height in || Barometer | Height in || Barometer | Height in Inches. | feet. || Inches. | feet. || Inches. | feet. -----------+-----------++-----------+-----------++-----------+----------- 31·0 | 0 || 26·8 | 3829 || 22·7 | 8201 30·9 | 85 || 26·7 | 3927 || 22·6 | 8317 30·8 | 170 || 26·6 | 4025 || 22·5 | 8434 30·7 | 255 || 26·5 | 4124 || 22·4 | 8551 30·6 | 341 || 26·4 | 4223 || 22·3 | 8669 30·5 | 427 || 26·3 | 4323 || 22·2 | 8787 30·4 | 513 || 26·2 | 4423 || 22·1 | 8906 30·3 | 600 || 26·1 | 4524 || 22·0 | 9025 30·2 | 687 || 26·0 | 4625 || 21·9 | 9145 30·1 | 774 || 25·9 | 4726 || 21·8 | 9266 30·0 | 862 || 25·8 | 4828 || 21·7 | 9388 29·9 | 950 || 25·7 | 4930 || 21·6 | 9510 29·8 | 1038 || 25·6 | 5033 || 21·5 | 9632 29·7 | 1126 || 25·5 | 5136 || 21·4 | 9755 29·6 | 1215 || 25·4 | 5240 || 21·3 | 9878 29·5 | 1304 || 25·3 | 5344 || 21·2 | 10002 29·4 | 1393 || 25·2 | 5448 || 21·1 | 10127 29·3 | 1482 || 25·1 | 5553 || 21·0 | 10253 29·2 | 1572 || 25·0 | 5658 || 20·9 | 10379 29·1 | 1662 || 24·9 | 5763 || 20·8 | 10506 29·0 | 1753 || 24·8 | 5869 || 20·7 | 10633 28·9 | 1844 || 24·7 | 5976 || 20·6 | 10760 28·8 | 1935 || 24·6 | 6083 || 20·5 | 10889 28·7 | 2027 || 24·5 | 6190 || 20·4 | 11018 28·6 | 2119 || 24·4 | 6297 || 20·3 | 11148 28·5 | 2211 || 24·3 | 6405 || 20·2 | 11278 28·4 | 2303 || 24·2 | 6514 || 20·1 | 11409 28·3 | 2396 || 24·1 | 6623 || 20·0 | 11541 28·2 | 2489 || 24·0 | 6733 || 19·9 | 11673 28·1 | 2582 || 23·9 | 6843 || 19·8 | 11805 28·0 | 2675 || 23·8 | 6953 || 19·7 | 11939 27·9 | 2769 || 23·7 | 7064 || 19·6 | 12074 27·8 | 2864 || 23·6 | 7175 || 19·5 | 12210 27·7 | 2959 || 23·5 | 7287 || 19·4 | 12346 27·6 | 3054 || 23·4 | 7399 || 19·3 | 12483 27·5 | 3149 || 23·3 | 7512 || 19·2 | 12620 27·4 | 3245 || 23·2 | 7625 || 19·1 | 12757 27·3 | 3341 || 23·1 | 7729 || 19·0 | 12894 27·2 | 3438 || 23·0 | 7854 || 18·9 | 12942 27·1 | 3535 || 22·9 | 7969 || 18·8 | 13080 27·0 | 3633 || 22·8 | 8085 || 18·7 | 13219 26·9 | 3731 || | || | -----------+-----------++-----------+-----------++-----------+----------- MARINE BAROMETER, ADOPTED BY HER MAJESTY'S GOVERNMENT, _On the recommendation of the Kew Observatory Committee of the BritishAssociation for the Advancement of Science. _ This instrument should be suspended in a good light for reading, but outof the reach of sunshine or the heat of a fire or lamp. It should be asnearly amidships, and exposed as little to sudden changes oftemperature, gusts of wind, or injuries, as possible. In a ship of warit should be below the lowest battery or gun-deck. Light should haveaccess to the back of the tube, to admit of setting the index so as tohave its lower edge a tangent to the surface of the mercury--the eyebeing on the same level, which is known by the back and front edges ofthe index being in one line with the mercury surface. White paper orcard will reflect light for setting the vernier correctly. The height ofthe cistern above or below the ship's water-line should be ascertained, and entered on the register. It is desirable to place the barometer in such a position as not to bein danger of a side blow, and also sufficiently far from the deck aboveto allow for the spring of the metal arm in cases of sudden movements ofthe ship. If there is risk of the instrument striking anywhere when the vessel ismuch inclined, it will be desirable either to put some soft padding onthat place, or to check movement in that direction by a light elasticcord; in fixing which, attention must be paid to have it acting onlywhere risk of a blow begins, not interfering otherwise with the freeswing of the instrument: a very light cord attached above, whenpossible, will be least likely to interfere injuriously. The vernier, as usual in standard barometers, reads to the twothousandth (·002) part of an inch. Every long line cut on the verniercorresponds to ·01 part; each small division on the scale is ·05; thehundredth parts on the vernier being added to the five when its loweredge is next above one of the short lines; or written down as shown bythe figures on the vernier only, when next above one of the divisionsmarking tenths. In placing this barometer, it is only necessary to fix the instrumentcarefully, as indicated in the above directions, and give a few gentletaps with the fingers on the bottom, to move the mercury. Withoutfurther operation it will usually be ready for observation in less thanan hour. When moving the barometer, or replacing it in its case, the mercuryshould be allowed to run gently up to the top of the tube, by holdingthe instrument for a few minutes inclined at an angle. The verniershould be brought down to the bottom of the scale. No other adjustmentfor portability is required. During carriage, it ought to be kept withthe cistern end uppermost, or lying flat, the former position beingpreferable. If the mercury should not descend at first by a few gentle taps, usesharper (but of course without violence), by which, and two or threetaps, with the finger ends, on the tube--between the scale and thetangent screw--the mercury will be made to begin to descend. In reading off from a barometer, it should hang freely, not inclined byholding, or even by touch. Sometimes, though rarely, at sea the mercury seems _stopped_. If so, take down the instrument (after _sloping_), reverse it, tap the tubegently while the cistern end is upwards, and then replace as before. * * * * * TESTING BAROMETERS, HYDROMETERS, AND THERMOMETERS. In the year 1853 a conference of maritime nations was held at Brussels, on the subject of meteorology at sea. The report of this conference waslaid before Parliament, and the result was a vote of money for thepurchase of instruments and the discussion of observations, under thesuperintendence of the Board of Trade. Arrangements were then made, inaccordance with the views of the Royal Society and the BritishAssociation for the Advancement of Science, for the supply ofinstruments properly tested. In the barometers now in general use by meteorologists on land, thediameters of the tubes are nearly equal throughout their whole length, and a provision is made for adjusting the mercury in the cistern to thezero point, previous to reading the height of the top of the column. Theobject of the latter arrangement, it is well known, is to avoid thenecessity of applying a correction to the readings for the difference ofcapacity between the cistern and the tube. At sea, barometers of thisconstruction cannot be used. Part of the tube of the marine barometermust be very much contracted to prevent "pumping, " and the motion of theship would render it impracticable to adjust the mercury in the cisternto the zero point. In the barometer usually employed on shore, the indexerror is the same throughout the whole range of scale readings, if theinstrument be properly made; but in nearly all the barometers which havetill recently been employed at sea, the index correction varies throughthe range of scale readings, in proportion to the difference of capacitybetween the cistern and the tube. To find the index correction for aland barometer, comparison with a Standard at any part of the scale atwhich the mercury may happen to be, is generally considered sufficient. To test the marine barometer is a work of much more time, since it isnecessary to find the correction for scale readings at about each halfinch throughout the range of atmospheric pressure to which it may beexposed; and it becomes necessary to have recourse to artificial meansof changing the pressure of the atmosphere on the surface of the mercuryin the cistern. The barometers intended to be tested are placed, together with aStandard, in an air-tight chamber, to which an air pump is applied, sothat, by partially exhausting the air, the Standard can be made to readmuch lower than the lowest pressure to which marine barometers arelikely to be exposed; and by compressing the air it can be made to readhigher than the mercury ever stands at the level of the sea. The tube ofthe Standard is contracted similarly to that of the marine barometer, but a provision is made for adjusting the mercury in its cistern to thezero point. Glass windows are inserted in the upper part of the ironair-chamber, through which the scales of the barometers may be seen; butas the verniers cannot be moved in the usual way from outside thechamber, a provision is made for reading the height of the mercuryindependent of the verniers attached to the scales of the respectivebarometers. At a distance of some five or six feet from the air-tightchamber a vertical scale is fixed. The divisions on this scalecorrespond exactly with those on the tube of the Standard barometer. Avernier and telescope are made to slide on the scale by means of a rackand pinion. The telescope has two horizontal wires, one fixed, and theother moveable by a micrometer, screw so that the difference betweenthe height of the column of mercury and the nearest division on thescale of the Standard, and also of all the other barometers placed bythe side of it for comparison, can be measured either with the verticalscale and vernier or the micrometer wire. The means are thus possessedof testing barometers for index error in any part of the scale, throughthe whole range of atmospheric pressure to which they are likely to beexposed, and the usual practice is to test them at every half inch from27·5 to 31 inches. In this way barometers of various other descriptions have been tested, and their errors found to be so large that some barometers read half aninch and upwards too high, while others read as much too low. In somecases those which were correct in one part of the scale were found to befrom half an inch to an inch wrong in other parts. These barometers wereof the old and ordinary construction. In some the mercury would notdescend lower than about 29 inches, owing to a fault very common in theconstruction of the marine barometer till lately in general use, thatthe cistern was not large enough to hold the mercury which descendedfrom the tube in a low atmospheric pressure. The practice which has long prevailed of mounting the marine barometerin wood is objectionable. The instrument recently introduced agreeablyto the recommendation of the Kew Committee, is greatly superior to anyother description of marine barometer which has yet been tested, asregards the accuracy with which it indicates the pressure of theatmosphere. The diameter of the cistern is about an inch and a quarter, and that of the tube about a quarter of an inch. The scale, instead ofbeing divided into inches in the usual way, is shortened in theproportion of about 0·04 of an inch for every inch. The object ofshortening the scale is to avoid the necessity of applying a correctionfor difference of capacity between the cistern and the tube. Theperfection with which this is done may be judged of from the fact, thatof the first twelve barometers tested at the Liverpool Observatory withan apparatus exactly similar to that used at Kew (whence theseinstruments were sent by railway, after being tested and certified), theindex corrections in the two pressures of 28 and 31 inches in three ofthem were the same; two differed 0·001 of an inch; and for the remainderthe differences ranged from 0·002 to 0·006 of an inch. The correctionsfor capacity were therefore considered perfect, and, with oneunimportant exception, agreed with those given at Kew. In order to check the pumping of the mercury at sea, the tubes of thesebarometers are so contracted, through a few inches, that, when firstsuspended, the mercury is perhaps twenty minutes in falling from the topof the tube to its proper level. When used on shore, this contraction ofthe tube causes the marine barometer to be always a little behind anordinary barometer, the tube of which is not contracted. The amountvaries according to the rate at which the mercury is rising or falling, and ranges from 0·00 to 0·02 of an inch. As the motion of the ship atsea causes the mercury to pass more rapidly through the contracted tube, the readings are almost the same there as they would be if the tube werenot contracted, and in no case do they differ enough to be of importancein maritime use. The method of testing thermometers is so simple as scarcely to requireexplanation. For the freezing point, the bulbs and a considerableportion of the tubes of the thermometers, are immersed in pounded ice. For the higher temperatures, the thermometers are placed in acylindrical glass vessel containing water of the required heat; and thescales of the thermometers intended to be tested, together with theStandard with which they are to be compared, are read through the glass. In this way the scale readings maybe tested at any required degree oftemperature, and the usual practice is to test them at every ten degreesfrom 32° to 92° of Fahrenheit. For this range of 60° the makers whosupply Government are limited to 0·6 of a degree as a maximum error ofscale reading; but so accurately are these thermometers made, that ithas not been found necessary to reject more than a very few of them. * * * * * Hydrometers are tested by careful immersion in pure distilled water; ofwhich the specific gravity is taken as unity. In water less pure, more salt, dense, and buoyant, the instrument floatshigher, carrying more of the graduated scale out of the fluid. The zero of the scale should be level with the surface of distilledwater, and rise above it in proportion as increase of density causesless displacement. The scale is graduated to thousandths--as far as ·040 only--because thesea water usually ranges between 1·014 and about 1·036. Only the lasttwo figures need be marked. LONDON: Printed by GEORGE E. EYRE and WILLIAM SPOTTISWOODE, Printers to the Queen's most Excellent Majesty. For Her Majesty's Stationery Office. FOOTNOTES: [1] In South latitude the South wind corresponds to our North wind inits nature and effects. The Easterly and Westerly winds retain theirrespective peculiarities in both hemispheres. [2] Exclusive of local land and sea breezes of hot climates. [3] Glass, barometer, column, mercury, quicksilver, or hand. [4] Or atmosphere, or the atmospheric fluid which we breathe. [5] Or exhaustion. [6] A vacuum. [7] See pages 24 and 25. [8] Thirty-two degrees is the point at which water begins to freeze, orice to thaw. [9] Evaporation. [10] The two thus combined making a hygrometer: for which some kinds ofhair, grass, or seaweed may be a make-shift. [11] It stands lower, about a tenth of an inch for each hundred feet ofheight directly upwards, or vertically, above the sea; where its averageheight, in England, is 29·94 inches (at 32°). [12] In an Aneroid, a metallic, or a wheel barometer, the hand's motionshould correspond to that of mercury in an independent instrument. [13] Southerly in South latitude. [14] In the best columns, those of standards for example, no concavityis seen, at any time: but it is otherwise with many barometers, which doshow a concavity. [15] In these cases there is usually a combination or a contest ofcurrents in the atmosphere, horizontally, _or_ one _above_ the other, ordiagonally. [16] Thunder clouds sometimes rise and spread against the wind(lower-current). It is probable that there is a meeting, if not acontest of air currents, electrically different, whenever lightning isseen. Their concurrence, when the new one advances from _polar_ regions, does not depress the barometer, except in oscillations of the mercury, which are very remarkable at some such times. [17] Aneroids, metallic barometers, and oil sympiesometers, seem to bemuch more affected than mercurial barometers by electrical changes. [18] Southerly, in North latitude; the reverse in the Southernhemisphere. [19] A "high dawn" is when the first indications of daylight are seenabove a bank of clouds. A "low dawn" is when the day breaks on or nearthe horizon. The first streaks of light being very low. [20] Indications of weather, afforded by colours, seem to deserve morecritical study than has been often given to the subject. Why a rosy hueat sunset, or a grey neutral tint at that time, should presage thereverse or their indications at sunrise;--why bright yellow shouldforetell wind at either time, and pale yellow, wet;--why clouds seemsoft, like water colour; or hard edged, like oil paint, or Indian ink onan oily plate;--and why such appearances are infallible signs--are yetto be shown satisfactorily to practical men. [21] In the trade winds of the tropics there is usually a countercurrent of air, with light clouds, --which does not indicate anyapproaching change. In middle latitudes such upper currents are not soevident, except before a change of weather. [22] _Much_ refraction is a sign of Easterly wind. _Remarkable_clearness is a bad sign. [23] The "young moon with the old moon in her arms" (Burns, Herschel, and others) is a sign of bad weather in the temperate zones or middlelatitudes, because (probably) the air is then exceedingly clear andtransparent. [24] Even in ordinary changes of weather it is interesting, as well asuseful, to mark the formation or disappearance of clouds, caused bycolder and warmer currents of air mixing: or intermingling. [25] Depending on pressure and temperature. [26] Sir James Ross--M. Daussy. [27] Williwaw (Whirl-awa?) of the old sealers and whalers. [28] Seamen call the light sails, used only in very fine weather, "flying kites. " [29] Herschel. [30] Dové. [31] For a barometer of this kind, Admiral Milne has inventedself-registering mechanism, that answers well. [32] A small turnscrew being applied gently to the screw head at theback. This is often necessary, on receiving or first using an aneroidthat has long been lying by, or that has been shaken by travelling. [33] It is a good weather glass--to be suspended on or near the upperdeck, for easy reference;--and is unlikely to be injured by mereconcussion of air, or vibration of wood, when guns are fired. [34] Allowing 0, 0011 of an inch for each foot. [35] The manufacture of these useful auxiliary instruments (all Frenchoriginally) has increased much latterly: and now the patent has expired. They might be so improved so to be worth more than double their presentvalue. [36] Like the sun's edge or limb, touching the sea horizon, as seeninverted when using a sextant.