A. The bright metal lid of the kettle is an admirable conductor of heat; and, therefore, the heat from the boiling water pours into our hand the moment we touch it.

A. The carbon of the fuel (which flies off in smoke) naturally blackens all culinary vessels set upon the fire to boil, and thus renders them fit for use.

(“Culinary vessels” are vessels used in kitchens for cooking, as saucepans, boilers, kettles, &c.)

A. If it were not for the smoke, (which gathers round a kettle or saucepan) heat would not be absorbed, and the process of boiling would be greatly retarded.

A. Because bright metal being a bad radiator will not throw off the heat of the boiling water from its surface.

A. Because bright metal will not absorb heat from the hot air, like an earthen vessel; in consequence of which, the water is kept cooler.

A. Light-coloured and highly-polished metal is a very bad radiator of heat; and, therefore, bright tin or silver will not allow the heat of the cooked food to escape through the cover by radiation.

A. If the cover be dull or scratched it will absorb heat from the hot food beneath it; and (instead of keeping it hot) will make it cold.

A. If the cover be chased, it will absorb the heat of the food covered by it; and instead of keeping it hot, will make it cold by absorption.

A. Dew is the vapour of the air condensed, by coming in contact with bodies colder than itself.

A. The earth is more heated by solar rays than the air, during the day; but at night, the earth parts with more heat than the air, and becomes (in consequence) 5 or 10 degrees colder.

A. As soon as the air touches the cold earth, its warm vapour is chilled, and condensed into dew.

A. On a fine clear star-light night, heat radiates from the earth freely, and is lost in open space: but on a cloudy night, the clouds arrest the process of radiation.

A. Because, when the night is clear and fine, the surface of the ground radiates heat most freely; and (being cooled down by this loss of heat) chills the vapour of the air into dew.

A. The clouds arrest the radiation of heat from the earth; and (as the heat cannot freely escape) the surface is not sufficiently cooled down to chill the vapour of the air into dew.

A. Because the clouds prevent the radiation of heat from the earth; and, therefore, the surface of the earth remains warmer on a dull cloudy night.

A. Because the radiation of heat is not arrested by houses, trees, hedges, or any other thing.

A. The shady head of the tree both arrests the radiation of heat from the earth, and also radiates some of its own heat towards the earth; and, therefore, the ground (underneath a tree) is not sufficiently cooled down to chill the vapour of the air into dew.

A. 1st—Because the wall or hedge acts as a screen, to arrest the radiation of heat from the earth: and

2ndly—The wall or hedge also radiates some portion of heat towards the earth.

A. As the ground (beneath a wall, tree, or hedge) is not cooled by the radiation of heat, it remains of the same temperature as the air above it; in consequence of which, the vapours of the air are not chilled by it into dew.

A. 1st—Because the awning arrests the radiation of heat from the ground beneath: and

2ndly—It radiates some of its own heat downwards; in consequence of which, the ground beneath an awning is not sufficiently cooled down to chill the vapour of air into dew.

A. Because any covering prevents the radiation of heat from the tree; and if the tree be not cooled down by radiation, the vapour of the air will not be frozen as it comes in contact with it.

A. The bass or canvass covering radiates heat both upwards and downwards; and is, therefore, so cooled down, that it readily chills all the vapour of the air (which passes over it) into dew.

A. Because the hedge or wall radiates heat into the snow beneath, which melts it.

A. 1st—Because the wind evaporates the moisture, as fast as it is deposited; and

2ndly—It disturbs the radiation of heat, and diminishes the deposition of dew thereby.

A. The surrounding hills prevent the repose of air (in the valleys) from being disturbed; but do not overhang and screen them, so as to arrest their radiation.

A. Because some things radiate heat more freely than others, and therefore become much cooler in the night.

A. Because the vapour of the air is chilled into dew, the moment it comes in contact with them.

A. Grass, wood, and the leaves of plants, radiate heat very freely: but polished metal, smooth stones, and woollen cloth, part with their heat very tardily.

A. No. Rough woolly leaves (like those of a holly-hock) radiate heat much more freely, than the hard smooth polished leaves of a common laurel.

A. As vegetables require much moisture, and would often perish without a plentiful deposit of dew, God wisely made them to radiate heat freely, so as to chill the vapour (which touches them) into dew.

A. No. While grass and the leaves of plants are completely drenched with dew, a piece of polished metal, or of woollen cloth (lying on the same spot) will be almost dry.

A. Because the polished metal and woollen cloth part with their heat so slowly, that the vapour of the air is not chilled into dew as it passes over them.

A. Grass, (being a good radiator) throws off its heat very freely; but gravel (being a very bad radiator) parts with its heat very reluctantly.

A. Yes. When the vapour of warm air comes in contact with the cold grass, it is instantly chilled into dew; but (as the gravel is not so cold as the grass) the vapour of air is not so freely condensed as it passes over the gravel.

A. Rocks and barren lands are so compact and hard, that they can neither absorb nor radiate much heat; and (as their temperature varies but very little) very little dew distils upon them.

A. Because cultivated soils (being loose and porous) absorb heat freely during the day, and radiate it by night; and (being much cooled by the rapid radiation of heat) as the vapour of the air passes over them, it is plentifully condensed into dew.

A. Every plant and inch of land which needs the moisture of dew, is adapted to collect it; but not a single drop even of dew is wasted, where its refreshing moisture is not required.

A. If polished metal collected dew as easily as grass, it could never be kept dry, and free from rust. Again, if woollen garments collected dew as readily as the leaves of trees, we should be often soaking wet, and subject to constant colds.

A. The fleece of wool (which is a very bad radiator of heat) was soaking wet with dew: when the grass (which is a most excellent radiator) was quite dry.

A. Yes; and was, therefore, a plain demonstration of the power of God, who could change the very nature of things at his will.

A. Because the vapour (condensed by the cold earth) lights upon them, like dew.

A. The temperature of the external air always falls at sun-set, and chills the window-glass, with which it comes in contact.

A. As the warm vapour of the room touches the cold glass, it is chilled and condensed into mist; and the mist (collecting into drops) rolls down the window-frame in little streams of water.

A. Yes; because the air is kept warm by fires, and the animal heat of the people in the room; in consequence of which, the air of a room suffers very little diminution of heat from the setting of the sun.

A. 1st—The very air of the room contains vapour:

2ndly—The breath and insensible perspiration of the inmates increase this vapour: and

3rdly—Hot dinners, the steam of tea, &c. contribute to increase it still more.

A. From every part of the human body an insensible and invisible perspiration issues all night and day; not only in the hot weather of summer, but also in the coldest day of winter.

A. If you put your naked arm into a clean dry glass cylinder, the perspiration of your arm will soon condense on the glass, like mist.

A. The warm vapour of the carriage is condensed the moment it touches the cold glass, and covers it over with a thick mist.

A. Because the inside of the carriage is much warmer than the outside, and the glass window is made cold by contact with the external air.

A. The warm breath and insensible perspiration of the persons riding in the carriage, load the air of it with warm vapour.

A. The breath and insensible perspiration of the sleeper (coming in contact with the ice-cold window) is frozen by the cold glass, and forms those beautiful appearances seen in our bed-rooms in a winter morning.

A. Glass is a very excellent radiator; and, therefore, most rapidly parts with its heat.

A. Because the hot vapour of the room (coming in contact with the cold tumbler) is condensed upon it; and changes its invisible and gaseous form for that of a thick mist.

A. The insensible perspiration of the hot hand is condensed upon the cold glass, and thus made perceptible.

A. The hot vapour of the room (coming in contact with the cold wine-glasses) is condensed upon them, and covers them with vapour like dew.

A. Because the glass becomes of the same temperature as the air of the room, and will no longer chill the vapour which touches it, and condense it into mist.

A. The vapour of the hot air is condensed by the cold glass, and covers it as a thick mist.

A. Because the hot breath is condensed by the cold glass; and, therefore, covers it with a thick mist.

A. The walls (being thick) cannot change their temperature so fast as the thin air can; and, therefore, they retain their cold after the thaw has set in.

A. As the vapour of the warm air touches the cold wall, it is chilled and condensed into water, which sticks to the wall, and sometimes trickles down in little streams.

A. Because the walls are much thicker; and (if the frost has penetrated far into the bricks) it takes a long time to reduce them to the same temperature as the air.

A. The wooden banister (being made of some very close-grained, varnished wood) cannot change its temperature so fast as the air; and, therefore, remains cold some time after the thaw has set in.

A. The vapour of the warm air (coming in contact with the cold banister) is chilled, and condensed into water upon it.

A. In winter the coldness of the air condenses our breath into visible vapour; but in summer the air is not cold enough to condense it into visible vapour.

A. The breath (issuing from our mouth and nose) is condensed into drops, as it comes in contact with our cold hair or hat; and (being condensed) hangs there in little dew-drops.

A. The steam from the steam-pipe (when the air is cold) is condensed by contact with the chill air, and falls like fine rain.

A. Easterly winds cross the continent of Europe, and, (as they pass over land) are dry and arid; but westerly winds cross the Atlantic Ocean; and (as they pass over water) are moist and full of vapour.

A. As the easterly winds are dry, they imbibe the moisture of the air; and, therefore, there is very little left to be condensed into dew.

A. As the westerly winds are saturated with vapour, they require a very little reduction of heat to cause a copious deposition of dew.

A. After a hot day in summer or autumn, with the wind in the west.

A. Because the surface of the earth radiates heat very freely at sunset; and (becoming thus much colder than the air) chills its vapour, and condenses it into dew.

A. No. The air never radiates heat, nor is the air itself made hot by the rays of the sun.

A. By convection of hot or cold currents.

A. The air (which is heated by the surface of the earth) ascends, warming the air through which it passes. Other air (being warmed in a similar way) also ascends, carrying heat; till all the air is made hot.

A. Yes. The air resting on the earth is made cold by contact: this cold air makes the air above it cold; and cold currents or winds shake the whole together, till all becomes of one temperature.

A. In a bright moon-light night, meat radiates heat very freely; and is, therefore, soon covered with dew, which produces rapid decomposition.

A. In bright moon-light nights rapid radiation is carried on, and dew is plentifully deposited on young plants, which conduces much to their growth and vigour.

A. Because the condensed vapours are always laden with noxious exhalations from the earth: this is especially the case in marshy countries.

A. No. Honey-dew is a sweet liquid shed by a very small insect (called the aphis), and deposited in autumn on the under surface of favourite leaves.

A. It injures them very much, because it fills the pores of the leaf with a thick clammy liquid; and, therefore, prevents the leaf from transpiring and absorbing.

A. After a little time, the leaf (being smothered and starved) begins to turn a dingy yellow.

A. Yes; and they crawl up the loftiest trees, in order to obtain it.

A. If the night has been very calm, a rapid radiation of heat has taken place in the earth; in consequence of which, the air (resting on the earth) is made so cold, that its vapour is chilled, and condensed into a thick mist.

A. Because the chill of the air is so rapid, that vapour is condensed faster than it can be deposited; and (covering the earth in a mist) prevents any further radiation of heat from the earth.

A. No; the air (in contact with the earth) becomes about equal in temperature with the surface of the earth itself; for which reason, the mist is not condensed into dew, but remains floating above the earth as a thick cloud.

A. The air resting on the earth is first chilled, and chills the air resting on it; the air which touches this new layer of mist being also condensed, layer is added to layer; and the mist seems to be rising, when (in fact) it is only deepening.

A. Because the condensed vapour is again rarefied by the heat of the sun, and separated into invisible particles.

A. Because every part of the drop is equally balanced; and, therefore, there is no cause why one part of the drop should be further from the centre than another.

A. Whenever two or more drops of dew roll together, they make one large spheroid (or flattened drop).

A. The leaves of cabbages and poppies are covered with a very fine powder; and the dew-drop rolls over this fine powder, as a drop of rain over dust, without wetting the surface.

A. Because it is driven from grain to grain by capillary repulsion.

A. Because it is driven from grain to grain by capillary repulsion.

A. The leaves of a rose contain an essential oil, which prevents them from absorbing the dew immediately.

A. Because their feathers are covered with an oily secretion, which repels the water.

A. When currents of air from land mix with currents of air from water, the currents from the water are condensed into mist by the colder currents blowing from the land.

A. Because the earth radiates heat very freely, and (being greatly cooled down) cools the air also which comes in contact with it.

A. Because water does not cool down at sun-set, so fast as the land does; and, therefore, the air in contact with it is warmer.

A. 1st—Because the surface of water is perpetually changing, and as fast as one surface is made cold, another is presented: and

2ndly—The moment water is made cold it sinks, and warmer portions of water rise to occupy its place: therefore, before the surface of water is cooled, the whole volume must be made cold; which is not the case with land.

A. These fogs (which occur generally in the winter time) are occasioned thus:—Some current of air (being suddenly cooled) descends into the warm streets, preventing the rise of the smoke, and forcing it back in a mass towards the earth.

A. Because the air will always hold in solution a certain quantity of vapour, (which varies according to its temperature): and when the air is not saturated with vapour, it may be condensed without parting with it.

A. If the air be pretty well saturated with vapour during the day, as soon as its capacity for holding vapour is lessened by the cold night, it deposits some of the superabundant vapour in the form of dew or fog.

A. The air of marshes is almost always near saturation; and, therefore, the least depression of temperature, will compel it to relinquish some part of its moisture in dew or fog.

A. In dew, the condensation is made near the earth’s surface:

In rain, the drops fall from a considerable height; but the cause of both is the same, viz.—cold condensing the vapour of the air, when it is near the point of saturation.

A. Because the condensed particles are again changed into invisible vapour, by the heat of the sun.