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| Alphabetical [« »] given 2 gives 11 giving 6 glass 85 glasses 1 gliding 1 glittering 1 | Frequency [« »] 90 very 89 particles 86 heat 85 glass 84 together 84 was 82 more | Michael Faraday Lectures on the Forces of Matter IntraText - Concordances glass |
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1 I | have before me a little glass vessel and scales [nearly 2 I | which contained a half-pint glass vessel], and the glass vessel 3 I | half-pint glass vessel], and the glass vessel is at present the 4 I | several lumps of marble into a glass jar, and poured water and 5 I | carbonic acid out of the glass in which it was being generated 6 I | having been avoided, the glass bottle and gold leaf all 7 I | upper part of this long glass vessel, and I have the means 8 II | for here is a piece of glass (for what was true of the 9 II | is true of the piece of glass, and is true of every other 10 II | I take these portions of glass which I have reduced to 11 II | ounces of finely pounded glass standing as an upright wall: 12 II | I will pour it into this glass basin, and you will, to-morrow, 13 II | solution of alum into the glass dish, and when the latter 14 II | advise you to do if you use a glass vessel, namely warming it 15 II | cohesion.~ ~Here is a piece of glass [producing a piece of plate-glass 16 II | some of the same sort of glass differing only in its power 17 II | There! you see the solid glass has suddenly become powder, 18 II | has knocked a hole in the glass vessel in which it was held. 19 II | experiment. I have here some more glass which has not been annealed [ 20 II | annealed [showing some thick glass vessels] 11, and if I take 21 II(10)| drops of a melted green glass into cold water. They were 22 II | and if I take one of these glass vessels and drop a piece 23 II | drop a piece of pounded glass into it (or I will take 24 II | advantage of being harder than glass), and so make the least 25 II | crystal into one of these glass vessels, when the bottom 26 II | will first take a bit of glass, and if I give it a blow 27 II(11)| Thick glass vessels - They are called 28 II | of a body this piece of glass. We perceive the outside 29 II | you might understand how glass attracts light, and might 30 II | may be bent by a piece of glass. [The electric lamp was 31 II | through this piece of plain glass, A, it goes straight through 32 II | without being bent (unless the glass be held obliquely, and then 33 II | if I take this piece of glass, B [a prism], you see it 34 II | by the attraction of the glass upon it; and you see I can 35 II | beautifully that piece of glass not only bends the light 36 II | understand that this piece of glass [the prism], being perfectly 37 II | instance, put a piece of common glass into the polarized ray so 38 II | screen remains dark. The glass, then, internally, has no 39 II | effect upon light. [The glass was removed and a piece 40 II | more transparent than the glass, but because of the different 41 II | experiment. Here is that piece of glass which before had no action 42 II | of all show you that the glass has no effect upon it in 43 II | Tyndall will press that bit of glass between three little points, 44 II | experiment that if we heat the glass in one part, it will alter 45 II | Here is a piece of common glass, and if I insert this in 46 II | nothing. There is the common glass [introducing it]. No light 47 II | I am going to warm this glass in the lamp, and you know 48 II | you pour warm water upon glass you put a strain upon it 49 II | Prince Rupert's drops. [The glass was warmed in the spirit 50 III | from the bottle down to the glass - a continuous rod of fluid 51 III | through the air down to the glass itself; and if I pour water 52 III | water on this piece of plate glass, and then take another plate 53 III | then take another plate of glass and put it on the water; 54 III | introduce one end of this glass tube into the bubble, that 55 III | grains of iodine into a hot glass globe, which immediately 56 III | lecturer here inverted a glass cylinder full of binoxide 57 III | there. Here is a strong glass vessel (G), and into it 58 III | gas has passed into the glass vessel. I will now shut 59 III | put some of it into this glass retort, and Mr. Anderson 60 IV | dimness on the sides of the glass, which will soon produce 61 IV(19)| need only be touched with a glass rod dipped in oil of vitriol. 62 IV | the two together into this glass, and you will at once see, 63 IV | however, [holding up a small glass tube containing lead pyrophorus21], 64 IV | fine powder, and put into a glass tube, and hermetically sealed 65 IV(21)| which has been heated in a glass tube to dull redness as 66 IV | ether, and put it into a glass tube, and then take a piston 67 V | substance; for if I take a glass rod, and rub it with a piece 68 V | and take this piece of glass and rub it with silk, and 69 V | lecturer held the excited glass near the excited shellac, 70 V | you place a piece of flat glass upon that, you have a very 71 V | lath and put it on the flat glass (you see I am searching 72 V | shellac with flannel or glass with silk.~Now there are 73 V | saw the shellac and the glass did, with the exception 74 V | for the purpose of rubbing glass with silk, and for obtaining 75 V | cylinder of brass by the glass handle, and touch the conductor 76 V | all, take these pieces of glass and metal, and you will 77 V | understand how it is that the glass does not lose the power 78 V | I touch it with a rod of glass, no power is drawn away, 79 V | electricity is conducted by the glass and the metal in a manner 80 V | have these columns made of glass? Because they obstruct the 81 V | top of the pole, upon a glass rod, and connect it with 82 V | easily understand that we use glass legs because these are capable 83 VI | You see there are in this glass jar two leaves of gold, 84 VI | light as we had in that glass vessel.~Now besides this 85 VI | pour part of it into this glass, and you will find that