Le Miroir Alchimique: NEWTON Notes Alchimiques

Isaac Newton
(1643-1727)
Portrait par Godfrey Kneller, 1689

I S A A C N E W T O N

Notes Alchimiques

Isaac Newton's Alchemical Notes in "Laboratory Notebook" 1664-1696
Portsmouth Collection Add. MS. 3975, Cambridge University Library, Cambridge University

PART 1

Note informative de L.A.T. - Avril 2012

Sa théorie de la gravitation universelle, la création (avec Leibniz) du calcul infinitésimal, diverses recherches en optique, en astronomie, en mathématiques, font d'Isaac Newton une figure emblématique des sciences.

Les recherches qu'il effectua en alchimie sont moins connues. Son "Laboratory Notebook" (MS Add.3975), qui contient également des notes sur l'optique, les pierres précieuses et les couleurs, et dont je vous propose ici la lecture en version originale, démontre cependant un intérêt prononcé pour la Tradition hermétique. Il tente également, à travers ces notes, d'effectuer une synthèse entre le mécanisme philosophique et l'alchimie.

Notons encore qu'Isaac Newton fut membre en 1699 et président en 1703 de la Royal Society of London (créée en 1660 et toujours active de nos jours), dont l'influence dans le processus de "création" de la Franc-Maçonnerie dite spéculative, en 1717, fut sans doute prépondérante.

Of a table booke of & i

To the Diamonds

Ruby 1::6 . 5
Espinela 1 . 5
Balax 1 . 6
Esmerald orient 1 . 10
Saphire 1 . 40
Topaz 1 . 20
Jacynt 1 . 240
Amatyst 1 . 360
Crisolin 1 . 660
Pearle 1 . 40
Seed pearle under a
Quilate = the price of
Gold & more.

Other stones

Beryll.
Chrysoprasus.
Granate.
Jasper. <illeg.>
Chrysolith.
Sardonix
Onyx = Chalcedony.
Onyx = Sardius.
Turquois
Agate.
Opales.
Cornelian.
Crystal.
Cats Eyes.

Query Is not the Crisolin the
Chrysolith or Grisolett. Ruby the
zar name of the Carbuncle
Anthrax. Balax. (Roberto Vallensi
(Theat. Chem. Vol. 1. p 26) a la
sive Palatius, the Opale
a stone of various colours, shining
gloriously wth a mixture of
thin fire of the Carbuncle the
fulgent purple of the Amethist
& the green sea of the Emerauld
to which ( Emerauld)
Pliny) tis next in value. P
sets down the value of Gemms
this order. Diamond. Pearl
rald, Opale, Carb
Topaz. Schroder reccons the To
& Chrysolith all one.

The hardest Gems are
diamonds Next to them in
hardness are Rubies. Topazes as
Saphires & these seem to equal
one another in hardnes
to differ only in their colour
Red yellow & Blew. Whence
some Jewellers take them
be one kind of stone diff
only in their colour. For stones
distinguished by the hardness
more certainly then by the
colour. So that coloured stone
which equal Diamonds in
hardness (as some do being yellowish
blewish greenish) are accounted Diamonds & coloured
stones which equal Saphires in hardness are white
saphires & sometimes Saphires have the colour of
Chacedonian. The Jasper Sardonix Onix Turquois are p
The Agat Opales Cats eyes Cornelians Spar
<The rest of this page is beneath a repair and is illegible.>

stone The Grisolet is a hard Gem of a
blewish colour brought from the East Indies
Rock crystal will cut glass, & is in weight
to Rain water as 2 3/5 or 2 5/8 to 1; & so are
white flints & allmost all solid pure
transparent stones. Those which are heavier (as
Granates) have their weight from metallick tinctures.
Chymists tell us the Crystal, Granate, Topaz, Saphire
Emerauld, Ruby, Carbuncle are
related to 263f

respectively. Pliny
l 37 c 5 tells us that in Cyprus a stone was
found which was one half an Emerauld the other
half a Jasper the humours not being wholy
transformed: & reccons Berylls of the same nature with Emeraulds & those Berylls the best which
are purely green like the sea, those next which are
paler with a glittering verging to a golden colour &
which are called Chrysoberilli, those next which are
paler verging more from a green to a golden
colour & which are called Chrysoprasi & after
them he puts the Hyacintizontes, the aeroides the cerini & the
oleagini, that is of the colour of a Hyacinth, of aer
of wax & of oyle. A Topaz (our Chrysolith) is the largest of
gemms & the only gemm (of pretious ones) cut with a
file It weares with use & is of two sorts, the
Prasois & the Chrysopteros like the Chrysoprasius
llr the proper colour of this stone is that of a
Leek. The Callais or Turquois is of a pale
green: the greener the better. the Jasper is sometimes
pellucid, tho not so much as other stones & is purple,
Indico blew or green. The best has an eye of purple.
the next of the colour of a rose the next to that of an
emerauld. the next of blew or sky colour. Its sorts are the
Saphire (one of which is the Cyanus of a sky-like blew)
the Amethist of a violet or purple inclining to
the colour of wine, the Jacynth of the colour of
wine, the Chrysolite pellucid with a golden colour.
One had a rare saphire of mixt colours blew & reddish purple
another a saphire mixt with a carbuncle which the
lapidaries d phire or saphirorubinus. See Pliny
commentator Lib. 37.

Of Colours

1. The rays reflected from Leafe Gold are yellow
but those transmitted are blew, as appeares by holding
a leafe of Gold twixt your eye & a Candle.

2. Lignum Nephriticum sliced & about a handfull
infused in 3 or 4 pints of faire water for a Night the
liquor (looked on in a cleare violl) reflects blew
rays & transmits yellow ones. And if the liquor
being too much impregnated appeares (when looked through)
of a darke red it may bee diluted with faire water
till it appeare of a Golden Colour.

3 The flat peices of some kinds of Glase will
exhibit the same Phaenomena with Lignum Nephriticum.
And these Phaenomena of Gold & Lignum Nephriticum
are represented by the Prisme in the 37th experiment
as also in the 22th & 24th Experiment.

4 But Generally bodys which appeare of any colour
to the eye, appeare of the same colour in all
positions; Nay Gold if it bee not soe very thin
as to bee transparent appeares onely yellow
& perhaps the yellow colour of Lignum
Nephriticum would vanish if the tincture bee strong
& the liquor of a greate thicknesse. And perhaps
there are many coloured bodys which if made so thin
as to bee transparent would appeare of one colour
when looked upon & of another when
looked through. Perhaps Motes in the Sun doe so, for
they appeare coloured. And

5 The tincture of Lignum Nephriticum may bee
deprived of its blew colour without any alteration
made in the yellow by putting a little of any
acid salt into it (as spirit of Salt, of vinegar, of Vitrioll,
Lemmon juice, oyle of Vitrioll, Aqua fortis etc). And
Sulphureous Salts (whither Urinous (i.e. Volatile salts of
Animal substances) as Spirit of hartshorne of Urin, of blood, of
Sal Armoniack; Or Lixiviate Unctuous Alcalizate & fixed
salts made by incineration, as the Solution of Salt of Tartar
of pot ashes, of common wood ashes, of lime water, Oyle of
Tartar etc) doe restore the blew colour without making
any change in the yellow.

Of Colours.

Experiments with the Prisme

6 On a black peice of paper I drew a
line opq, whereof one halfe op was
a good blew the other pq a good deepe red
(chosen by Prob. of Colours). And looking on it
through the Prisme adf, it appeared broken in
two betwixt the colours, as at rst, the blew parte rs being
nearer the vertex ab of the Prisme then the red parte st.
Soe that blew rays suffer a greater refraction then red ones.
‡ <in mg:>Note ‡ [I call those blew or red rays etc, which make the Phantome of such colours.

The same Experiment may bee tryed with a thred of two
colours held against the darke.

7 Taking a Prisme, (whose
angle fbd was about 60°)
into a darke roome into
which the sun shone only
at one little round hole
k. And laying it
close to the hole k in such manner that the rays, being
equally refracted at (n & h) their going in & out of it,
cast colours rstv on the opposite wall. The colours should
have beene in a round circle were all the rays alike
refracted, but their forme was oblong terminated at
theire sides r & s with streight lines; theire bredth rs
being 2 1/3inches, theire length tv about 7 or eight
inches, & the centers of the red & blew, (q & p) being distant
about 2 3/4 or 3 inches. The distance of the wall trsv from
the Prisme being 260 inches.

8 Setting the Prisme in the midst twixt the hole k & the
opposite wall, in the same posture, & laying a
boarde xy betwixt the hole k & the Prisme close
to the Prisme, in which board there was a small hole
as big as the hole k (viz: 1/8 of an inch in Diameter)
soe that the rays passing through both those holes to the Prisme might
all bee almost parallell (wanting lesse then 7',
wheras in the former experiment some rays were
inclined 31'). Then was the length & breadth of the
colours on the wall every way lesse then halfe the former by
about 2 inches viz rs = 3/8inch, tv = 2 3/4 inch , &
pq = 1 1/4inch. Soe that the Red & blew rays which
were parallel before refraction may bee esteemed to be

generally inclined one to another after refraction (some
more some lesse then) 34' And that some of them
are inclined more then a degree, in this case. And
therefore if theire sines of incidence (out of glass into
aire) be the same, theire sines of refraction will
generally bee in the proportion of , to
& for the most extreamly red & blew rays, they
will bee as 130 to 131 +, . For by the
experiment if their angle of incidence out of the glasse
into the aire bee 30°. The angle of refraction of the red
rays being 48° 35': the angle of refraction of the blew
rays will bee 48°, 52', generally: but if the rays bee
extreamly red & blew the angle of refraction of the
blew rays may bee more then 49°, 5'.

9 In the 7th Experiment the
colours appeared in this order,
but in the 8th experiment where the
rays were more distinct &
unmixed

10 Painting a good blew & red colour on a peice of paper
neither of which was much more luminous then the other (for
carrying them gradually into the darke, both grew faint alike
almost & disappeared together) if the Prismaticall blew
fell upon the colours they both appeared perfectly blew
but the red paint afforded much the fainter & darker
blew, but if the Prismaticall red fell on the colours they
both appeared perfectly red but the painted blew afforded
much the fainter Red. The Prisme was ordered as in the
8th experiment. Note that the purer the is the lesse tis
visible with rays.

Of Colours

11 If the plate abcdsr bee
painted with any two colours
& abcd bee the lighter
colour, the partition edge
of the Colours, cd will
appeare through the prisme txy of a redd colour, but
if cres bee the lighter colour, their common edge cd
will through a prisme looke blew.

12 And this will
happen though the colours differ not in species but only
in degrees, as if acdb bee black & cdsr darkness or
‡ <in mg:> 261e

‡ blacker then abdc the edge dc will bee red & much
more conspicuous then the black, which is strange.

13 But if in a darke roome (as in Experiment 10) the
prismaticall blew or redd fall on a paper abdc
the edges of the paper will not appeare otherwise coloured
through another Prisme then to the naked eye, viz: of the
same colour with the rest of the paper. [For the first
Prisme perfectly seperats the blew & red rays
whereas I beleive all the colours proper to bodys are a little
mixed.]

14 Prismaticall colours appeare in the eye in a contrary
order to that in which they fall on the paper.

15 If a foursquare vessell abcd bee
made with two parallell sides of
well pollished glasse AC BD, & bee
filled with water; And if the sunns
rays passing into a darke roome
throughe the hole k doe fall very
obliquely on the glasse sides of the vessell
the rays at their egresse shall paint colours on
the paper EF on which they fall. [The blew & red
rays being seperated by the first refraction.]

16 The colours are not made broader (as they would be
were the prisme triangular) by removing the paper
farther from the vessell. [becaus the blew & red rays
become parallell againe after the second refraction]
if the rays pass through two holes near or close to the vessell on either side the colours

Of Colours.

17 The window k being opened that the Sun or other terminated light might shine in freely,
If I limited the rays by an opace body held twixt the wall
& the vessel the edge of that bodys shaddow would not appeare
coloured. But if the said body were on that side the vessel
towards the sun its shaddow would be coloured on its edges

18. But in the Triangular Prisme whither the said body bee
held on the one side or on the other the edges of its
shaddow appeares coloured.

19. If you looke upon some uniformely luminous body (as
on the cleare sky or a sheet of white paper etc) through a
triangular prisme. & hold the said opace body on the
further side of the Prisme soe as to obscure parte
of the said luminous body; the farther the said opace
body is held from the Prisme, the more its edges will bee
coloured; & the nearer, the lesse; untill the colours almost
vanish when the said body is held close close to
the Prisme.

20 But if instead of the triangular Prisme you use the
said 4square vessell ABDC, held obliquely that the rays
may bee much refracted in passing through it to your eye;
when the opake body is placed as neare to the vessell
as you can distinctly see it, your eye being close to the
vessell, the edges of the said body will appeare coloured:
which colours are diminished by removing the said body farther
from the vessell, & quite vanish when the distance of
the said body is very greate. Thus the Sun, by
reason of his distance, appeares not coloured on his edges when looked
on through the said vessell, & yet in the 15th Experiment
hee trajects colours on a peice of paper.

21 The colours made by this vessel appeare
immediatly to the eye in the same order in which they fall on paper.
but by the triangular Prisme that order is divers.

Note, That the more the glasse sides of the vessell ABCD are distant, the
better it is; that distance should not bee lesse then 6 or 8
inches to make the Phaenomena conspicuous. Some of the
Phaenomena may bee tryed by tying two Prismes thus
together: But the distance of theire sides is two little to exhibit them all

Of Colours

22. If the sun S shine upon the Prism
def, some of his rays being transmitted
through the base ef will make colours
on the wall cb at b, others will bee
reflected to
the wall at c making only a white
without colours; Now if the Prisme bee soe inclined as that
the rays ab bee refracted more & more obliquly, the
blew colour will at last vanish from b; soe that the
red alone being refracted to b, the blew will bee
reflected to c & make the white coloure there to
appeare a little blewish. But if the Prisme bee yet more
inclined, the red colour at b will vanish too & being
reflected to c will make the blewish colour
turne white againe.

23. If in the open aire you looke at
the Image of the Sky reflected
from the basis of the Prism
ef, holding your eye O almost
perpendicular to the basis you will see one part
of the sky ep (being as it were shaded with a thin
curtaine) to appeare darker then the other qf.
[ For all the rays which can come to the eye from
qf, fall soe obliquly on the basis as to bee all
reflected to the eye. Whereas those which can come
to the eye from ep are so direct to the basis as to
bee most of them transmitted to g]: & the
partition of those two parts of the Sky, pq, appeares
blew; [For the rays , which can come
to the eye from pq, are so inclined to the basis that
all the blew rays are reflected to the eye whilst
most of the red rays are transmitted through to g,
as in Experiment 22].

24 Tying two Prismes basis to basis
def & bef together: I
so held them in the
sun beames, transmitted
through a hole into a
darke roome, that they

Of Colours.

falling pretty directly upon the base ef (in fig 1) were
most of them transmitted to B on the paper CB; though
some of them were reflected to C by the filme of aire
ef betwixt the Prismes. But both C & D were white Then I inclined the Basis
(ef) of the Prismes more & more to the rays untill
B changed from white to Red, & the white at C
became blewish; & inclining the Prisme a little more
the Red at B vanished, & the blewish colour at C became
white againe. As in the 22th Experiment.

25 If I held the said Prismes in the open air as in the 23d
experiment, holding my eye at O (in the 2d fig) to see
the reflected sky the Phaenomena were the same as in that
23d experiment; ep appearing darker then qf, & pq being
blew. But if I held my eye at N to see the sky
through the base of the Prismes ef (or rather through the
plate of aire betwixt those bases) there appeared the
contrary Phaenomena but much more plaine; ep being very light, qf very
darke, & pq very red. [The reason was given in
the 23d experiment

Note, That the 22th & 24th (& all such like experiments that
require that the rays coming from a
luminous body be all wholly or almost parallell) would
bee more conspicuous were the suns Diameter lesse, &
therefore for such like experiments his rays may bee
straitned through two small holes at a good distance
assunder, as was done in the 8th Experiment.

Also the 23th & 25t Experiment (most most other such like
in which the rays passe immediatly from
the prisme to the eye) would bee more conspicuous were the
Pupill lesse then it is, And therefore it would bee
convenient to looke through a small hole at the Prisme.

26 The colours in the partion pq appeared to the Eye O in
this order

Of Colours.

27 The two Prismes being tyed harder together
then in trying the 24th Experiment, there appeared
a white spot in the midst of the red colour
B, & a darke spot in the blewish colour C.
And after the base ef of the Prismes was more
inclined to the rays , so that the red colour
vanished & that (by the laws of Refraction) noe light could
penetrate the filme of aire ef, yet the white spot
remained at B & the darke one in the midst
of the light at C.

28 Holding my eye at O or N (in trying the 25t Experiment)
very obliquely to the basis ef; To my
eye at O appeared a black spot (R) in the midst of the
white basis (or filme of aire) ef, & to my eye at N
appeared a white spot (R) in the midst of the black basis
(or plate of aire) ef; through which spot (as through a
hole in the midst of a black body) I could distinctly see
any object, but could discerne nothing through any other
parte of the appearingly black basis ef.

29 By variously pressing the Prismes together at one end more
then at another I could make the said spot R run
from one place to another; & the harder I pressed the
prismes together, the greater the spot would appeare.
to bee. [Soe that I conceive the Prismes (their sides being
a little convex & not perfectly plaine) pressed away the
interjacent aire at R & becoming contiguous in that
spot, transmitted the Rays in that place as if they
had beene one continuous peice of glasse; whereas the
plate of aire (ef) is a very reflecting body: soe that the
spot R may bee called a hole made in the plate of
aire (ef)].

32 The colours of the circles (in the 30th & 31th Experiment) appeared
more distinct at C then at B, & to the Eye O then to the
Eye N. There being I conceive
some colourlesse light reflected with the coloured light to
O, & C but much more colourlesse light transmitted to
N & B; which must needs whiten & blend
the colours.

Of Colours

30 In the 27th Experiment when the colour white or red was
trajected on B, there would apeare severall circles of
colours about the white spot at B & also about the darke
one at C. But those colours vanished together with the red colour
at B: Growing greater & distincter untill they vanished.

31 Likewise in the 28th Experiment when the spot was on that side the
partition pq next the eye, it appeared to my
eye both at O & N, encompassed with divers circles of
colours. Which circles would grow greater & distincter by
how much the coloured partition pq came nearer & nearer
to them (that is by how much the base ef was more &
more oblique to the rays) & soe vanished by degrees
as the said limb pq came to them. Before they began
to vanish they appeared round or Ellipticall thus
See Manuscript

But in their vanishing (especially if looked on
through a hole much smaller
then my pupill) they appeared
incurved thus.
See Manuscript

But I could see the most circles when I
looked on them through a long slender
slit, held parallel
to the coloured limb pq, when the circles
halfe disappeared: for then I have numbered 25
circles esteeming each consecution of red & blew to bee one circle & could perceive there were
many more so close together that I could not number
them; whereas with my naked eye I could not discern
above nine or ten .

33 The circles are the broadest
nearest to the center & so beeing
narrower & narrower doe (I conceive
by the exactest measure I could make)
increase in number as the interjacent aire doth in
thicknesse. (Sit cd = radio curvitatis vitri; efghik circuli
colorum; & el = fm/2 = gn/3 = hp/4 = iq/5 = kr/6 = crassitiei aeris <.)
And this I observed by a sphaericall object glasse of a
Prospective tyed fast to a plaine glasse, so as to
make the said spot with the circles of colours appeare.

Of Colours.

34 By the fore named Prospective glasse
I observed (though not very exactly) that
the more obliquely the ray tc was
incident to the filme of aire ef twixt
the glasses, the greater the coloured
circles are in this proportion:

35 When the rays were perpendicular to the aire ef, the
diameter of 5 of the circles was one parte, whereof
400 was the radius dC of the glasses curvity. the said
radius being 25inches Soe that (el) the thicknesse of the aire
for one circle was 1/64000inch, or 0,000015625.
[which is the space of a pulse of the vibrating medium.]by measuring it since more exactly I find 1/83000 = to the said thicknesse.

36 Accordingly as the glasses are pressed more or lesse together
the coloured circles doe become greater or lesse.
& as they are pressed more & more together new circles
doe arise in the midst untill at last the said pellucid
spot R doth appeare.

37 The circles of colour appeare in this order from the
center to the eye O Or on the paper at C viz
Darke (or pellucid), white,        yellow, greene, blew, purple,
Red, Yellow, greene, blew purple, Red, Yellow, Greene, blew etc.
But to the eye N or on the Paper at B they appeare in
this order Light (or pellucid) black,        blew, Greene,
yellow, Red, purple, blew, greene
soe that those circles which appeare Red to the eye O, appeare
blew to the eye N, & thos which appeare blew to the
eye O appeare of the contrary colour red to the Eye N.

Of Colours.

38 Those circles which appeare Red to the eye O, & blew
to the eye N are almost as broade againe as those
which appeare blew to the eye O & Red to the eye N.

39 Holding the said circles in a darke roome in the
blew rays made by a Prisme (as the 10th Experiment)
all the said circles appeared blew but those which in the
discoloured light appeared red appeared of a blew
much more diluted then the others. And if the
Red Prismaticall rays fell upon those circles all the
circles appeared red but those circles which in the clear
light appeared blew, in the Prismaticall red rays
appeared of a much darker & obscurer
red then the others.

40 Whither these circles were held in the
Prismaticall blew or red rays they still appeared of the
same bignesse.

41 Putting water betwixt the two Prismes instead of
the filme of aire; There appeared all the Phaenomena
of the said circles, & also of the 22, 23, 24, & 25t
Experiments etc. Onely somwhat more obscurely because
there is lesse refraction made out of glase into
water then into aire; & yet

42 The coloured circles appeared as big when
there was a filme of water as when there was
a filme of aire betwixt the Prismes.

43 If you make the pellucid spot R nimbly to run to
& fro, There will appeare another spot S
to follow it, which spot S exhibits such
Phaenomena as it ought to doe were it a Spot of
aire, viz: To the eye O it appeares white next the
Spot R & then Red etc, But to the eye N it
appeares black next the Spot R & then blew etc: which
colours it ought to have were it a filme of aire
(by experiment 37). But it is not a filme of aire because
if the Spot R rests a little, the water creepes into the
said spot S & makes it vanish. It seemes therefore that the
water cannot nimbly enough follow the spot R, but leaves

Of Colours

the space S empty to bee possessed by Aether alone, untill
the water have time to creepe into it.

44 Refracting the Rays through a Prisme into a darke
rome (as in the 7th Experiment) And holding another
Prisme about 5 or 6 yards from the former to
refract the rays againe I found First that the blew
rays did suffer a greater Refraction by the second Prisme then the Red
ones.

45 And secondly that the purely Red rays refracted by the
second Prisme made noe other colours but Red & the
purely blew ones noe other colours but blew
ones.
See Manuscript

46 If three or more Prismes
A, B, C, bee held in the sun soe
that the Red colour of the Prisme B
falls upon the Greene or yellow colour
of the Prisme A & the Red colour of the
Prisme C falls on the Greene or yellow
colour of the Prisme B; the Said colours falling
upon the Paper DE at P, Q, R, S. There will
appeare a Red colour at P & a blew one
at S but betwixt Q & R where the Reds,
yellows, Greenes, blews, & Purples of the severall
Prismes are blended together there appeares a white.
See Manuscript

47 Or if you cleame a peice of

Of Colours

Paper on one side of the Prisme with severall
slits a, b, c, d, in it parallel to the edges of the Prisme
soe that the light passing through those slits make colours
on the Paper DE; If the said paper be held neare
to the Prisme there will appeare for each slit
a, b, c, d, a coloured line r, s, t, v. The paper being
held farther of untill the said coloured lines bee
blended together, there will appeare white twixt
p & q where those colours are blended; at m
there appeares Reds & at n blews. But if
the paper bee still held farther of the white
colour (pq) will appeare narrower & narrower untill
it vanish. & then gh on one side appeares Red
& gf on the other side is blew.

49 A single superficies of Glasse reflects many
rays whither they passe out of glasse into aire or
out of aire into Glasse & yet two surfaces
of Glasse when contiguous (by the 27th 28th &
29th Experiment) reflect the Rays noe more then
if the glasses had beene one entire peice without
such a superficies betwixt them.

48 As white was made by a mixture of all sorts
of colours (in the 46th & 47th Experiment) Greene is made
by a mixture of blew & yellow, purple by a
mixture of red & yellow, etc

50 Thin Flakes of Muscovy Glasse, Bubbles which
children make of sope & water, the thin skum
of molten leade, of cooling iron, water wiped
very thin on glasse, glasse blowne very thin, etc
represent the Phaenomena of the coloured circles in the
30th and 31st Experiments etc. To which may bee referred coloured
motes in the Sun or in liquors, or pouders, or sollid
bodys; the slender coloured threds of some
cobwebbs, of silke wormes, & of flax finely dressed
(though the flax in spining looseth its glosse, because
the flat thredds cleave together againe into
two greate a thicknesse see Experiment 49).

Of Colours

51 If the Sun S shine
upon a large glasse
Globe abd filled with
water And if you
hold your eye very
neare to the globe, the
rays bp will
appeare coloured redd & the farther you hold your eye from
the glasse the lesse they appeares coloured, untill the
colour vanish. But the Rays rd & fq appeare
coloured at what distance so ever your eye bee placed
from the Globe. The like you may observe by letting
the colours fall on a peice of paper.

52 Though one termination of light trajected through
the Prisme will not make both blews & reds; yet
in this globe it doth (see Cartesii Meteora
cap 8 sec 9) For the rays rd & fq make all sorts
of blews & reds; indeed by the rays bp the red is
very distinct but the blew is scarce discernable.

53 The colours of the Rainbow must bee
explicated by the rays rd & fq (vide Cartesii Meteor
Cap 8 sec 1, 2, 3, 9, 10, 11, 12, 15<) For the bow may bee mad by drops of water forcibly cast up into the aire.

54 The spot R (mentioned in Experiment the 52d) grows
lesse & lesse by how much the rays fall more &
more obliquely on the intermediate filme of aire ef.
[which seemes to intimate that the thinness of the
intermediate filme of aire (or rather Aether) augments its
refraction, untill (when the glasses become contiguous) it
bee aequall to that of glasse]

55 The surfaces of Glasse doe not reflect soe much light
when the glasse is in water as when it is in aire
& the lesse any two mediums differ in refraction the
lesse their intermediate surface reflects light [which
intimates that tis not the superficies of Glasse or any
smoth pellucid body that reflects light but rather
the cause is the diversity of Aether in Glasse &
aire or in any contiguous bodys though the parts
of the Glasse must necessarily reflect some rays.

Of Colours

56 The pouders of Pellucid bodys is white soe is a cluster
of small bubles of aire, the scrapings of black or cleare
horne, etc: [because of the multitude of reflecting surface]
soe are bodys which are full of flaws, or those whose
parts lye not very close together (as Metalls, Marble, the
Oculus Mundi Stone etc) [whose pores betwixt their parts admit
a grosser Aether into them then the pores in their parts], hence

57 Most Bodys (viz: those into which water will soake as
paper, wood, Marble, the Oculus Mundi Stone, etc) become
more darke & transparent by being soaked in water
[for the water fills up the reflecting pores]

58 I tooke a bodkin gh
& put it betwixt my
eye & the bone as
neare to the
backside of my eye
as I could: & pressing
my eye with the end of
it (soe as to make the
curvature a, bcdef in my
eye) there appeared severall
white darke & coloured circles
r, s, t, etc. Which circles were
plainest when I continued to rub my eye with the
point of the bodkin, but if I held my eye & the
bodkin still, though I continued to presse my eye
with it yet the circles would grow faint
& often disappeare untill I renewed them by moving
my eye or the bodkin.

59 If the experiment were done in a light roome so
that though my eyes were shut some light would
get through their lidds There appeared a
greate broade
blewish darke circle outmost (as ts), & within that
another light spot srs whose colour was much
like that in the rest of the eye as at k. Within
which spot appeared still another blew spot r,

Of Colours

espetially if I pressed my eye hard & with a small
pointed bodkin. & outmost at vt appeared a verge of light

60 But on the contrary if I tryed the Experiment in very
darke roome the circle ts apeared of a Reddish light
sr of a darkish blew & the middle spot r appeared
lighter againe; & there seemed to be a circle of
darke blew tv without the circle ts the outmost of all.
[I conceive (in the 60th experiment) where the curvature of the Retina at
ma & fn began & was but little the blew colour
tv was caused; at ab & ef where the Retina was
most concave, the bright circle ts was caused: at bc,
& de where the Retina was not much incurved nor
strained the darke blew circle sr was caused &
at cd where the Retina was stretched & made
convex the light spot r was caused. In the
59th Experiment the spirits were perhaps strained
out of the Retina at ab, ef, & cd or otherways made
incapable of being acted upon by light & soe
made a lesse appearance of light then the rest of the Retina]

61 That the same circle ts which appeared light in
the darke, appeared darke in the light I found
by suddenly letting in light into a darke
roome for then the bright circles would imediatly turne
into darke ones & the darke ones into bright ones.

62 I could sometimes perceive vivid colours of blew
& red, made by the said pressure & perhaps a criticall eye might have
discerned this order of colours. in the 60th
experiment viz from the center greene, blew, purple,
darke, purple, blew, greene, yellow, red like flame,
yellow, greene, blew, broade purple, darke.

63 Looking on a very light object as the Sun or his
image reflected; for a while after there would
remaine an impression of colours in my eye: viz:
white objects looked red & soe did all
objects in the light, but if I went into a dark
roome the Phantasme was blew.

64 That vision is made in the retina appeares because colours are
made by pressing the bakside of the eye; but when the eye turns
towards the pressure soe that it is pressed before the colours cease.

Of Colours.

The Tunica Retina grows not from the sides of the opticks
nerve (as the other two which rise one from the dura, the other
from the Pia mater) but it grows from the middle of the nerve
sticking to it all over the extremity of its marrow. Which
Marrow if the nerve bee any where cut cross wise twixt the eye
& the union of the nerves, appeares full of small spots or
pimples, which are a little prominent, especially if the nerve
be pressed or warmed at a candle. And these shoot into the very
eye & may bee seene with in side where the retina grows to the
nerve: and they also continue to the very juncture EFGH.
See Manuscript

But at this juncture they end on a
suddein into a more tender white
pap like the interior part of the
braine & soe the nerve continues
after the juncture into the braine
filld with a white tender pap
in which can bee seene noe
distinction of parts as betwixt
the said juncture & the eye.

Now I conceive that every point
in the retina of one eye hath
its correspondent point in the
other, from which two very
slender pipes filld with a most lympid liquor doe
without either interruption or any other
uneavenesse or irregularity in
their processe, goe along the
optick nerves to the juncture EFGH where they meete
either twixt GF or FH, & there unite
into one pipe as big as both of them, & so continue in one
passing either twixt IL or MK into the braine where they are
terminated perhaps at the next meeting of the nerves twixt
the Cerebrum & cerebell e114

, in the same order that their extemitys
were scituate in the Retinas. so there are a vast multitud
of these slender pipes which flow from the braine the one halfe
through the right side nerve IL till they come at the juncture
GF where they are each divided into two branches the one passing
by G & T to the right side of the right eye AB the other
halfe shooting through the juncture EF & soe passing by X to
the right side of the left eye α;β. And in like manner
other halfe shooting through the left side nerve MK divide
themselves at FH & their branches passing by EV to the
right ey & by HY to the left, compose that 1/2 of the Retina

in both eys which is towards the left side, CD, & γδ.

Hence it appears 1 why the two images of both eyes make but
one image abcd in the braine. 2 Why when one eye is
distorted objects appear double, For if the image of any object
bee made upon A in the one ey & β in the other, that
object shall have two images in the brain at
a & b. Therefore the pictures of any object ought to
bee made upon the corresponding points of the two Retinas
if upon A in the right ey then upon α; in the left. If
upon B then also upon β. And soe shall the motions
concurr after they have past the juncture GH & make one
image at a or b more vivid then one ey alone
could doe. 3 Why though one thing may appeare in two
places by distorting the eys yet two things cannot appear
in one place. If the picture of one thing fall upon A
& of another upon α;, they may both proceed to p but
noe farther, they cannot both be carried on the same pipes
pa into the braine, that which is strongest or most
helped by fantacy will there prevaile & blot out the
other. 4 Why a blew seene by one eye & a yellow by
the other at the same time produces a greene unlesse
the fantasy make one colour praedominant. 5tly Why if
one of the branches of the nerve beyond the juncture as at
GF or FH should bee cut: That halfe of both eys
toward the wounded nerve would bee blind, the other halfe
remaing perfect. 6tly Why the juncture is almost as broad again twixt
G & H then twixt E & F, becaus all the tubuli of both
eys pass twixt G & H & but 1/2 of them twixt E & F. It is not quite so broad again because the tubuli crossing etc: also the thicknes of the tunicks
7tly why the nerve GILF buts not directly
upon the nerve XEHY, but deviates to stand deviates
a little towards TV because its Tubuli are to passe only into
that side of the nerve EHYX towards EX. The like of FMKH 8thly why the
marrow of the nerve TVEG grows soft on a suddein when
it comes at the juncture EF & more suddenly on that side
towards G then towards E. And the like of the nerve EXYH
For it being necessary that the nerve TVEG should bee stretcht
& bended severall ways by the motion of the eye: Therefore
the tubuli are involved or wrought up with in the
substance of severall tough skins which being foulded up
together compose the marrow of the nerve, pretty sollid & flexible
least the tubuli should be prejuced by the severall motions
of the nerve. And those small pimples or prominences which
appeare in the nerve cut crosse wise I conceive to bee made
by the foldings of these crasser skins. But the nerve at the
juncture EGFH being well guarded from all violence &

motion by the bones into which it is
closely adapted: tis not necessary the said membranus substance
should be continued any further then EG therefore the tubuli
there on a suddein unsheath themselves those on the inner side
of the nerves towards VE & XE may severally crosse
twixt EF & bee united with their correspondents on the other
sides YH & TG. Now because the inner tubuli must first crosse
before they can convene with the outmost tubuli of the opposite
nerve hence it is that the nerves grow soft sooner on the inner
side at E then on the outer side at G & H.

9thly why the two nerves meet a second time in the braine,
because the two half images caried along IL & MK may bee
united into one complete image in the sensory.
Note that the nerves at their contact meeting are round about disjoyned
from the rest of the braine, nor are they soe thick there as a
little before their meeting. But by their externall figure
they seeme as if the capillamenta concentered like the radii of a hemisphere to a point in
the lower part of the juncture. And tis probable that the visive
faculty is there for else why doe the nerves swell there to so great a bulke as
it were preparing for their last office, why doe they run directly crosse
from eitherside the braine to meet there if the designe was to have the motions coveyed by the shortest
cut from the eye to the sensorium before they grew too weak.
If they were to proceed further , they might have gone a shorter cut & in a lesse
channell. There is indeed a marrow shoots from under them toward
the cerebrellum to which they are united but the greatest part of
their substance if not all of it lys above this marrow
& also shoots cross beyond it to the center of the brain where they meet.
Lastly the substance here is most pure, the scituation in the mist of
the brain, constituting the upper part of that small
passage twixt all the ventricles. where all superfluous humors have the
greatest advantages to slide away that they may not incumber that
precious organ

Light seldom striks upon the parts of grosse bodys (as
may bee seen in its passing through them), its reflection &
refraction is made by the diversity of aethers, & therefore it effect
on the Retina can only bee to make this vibrate which motion then
must bee either carried in the optick nerve to the sensorium or produce other
motions that are carried thither. Not the latter for water is too
grosse for such subtile impressions & as for animall spiritts

though I tyed a peice of the optick nerve at one end &
warmed it in the middle so see if any aery substance by that
meanes would disclose it selfe in bubbles at the other end, I
could not spy the least bubble; a little moisture only & the
marrow it selfe squeezed out. And indeed they that know how
difficultly aire enters small pores of bodys, have reason to suspect
that an aery body though much finer then aire can pevade easily &
without violence (as it ought to doe) the small pores of the braine
& nerves, I should say of water, because those pores are filld with
water, & if it could it would bee too subtil to bee imprissoned
by the dura mater & Skull, & might passe for aether. However,
what need of such spirits much Motion is ever lost by
communication especially twixt bodys of different constitutions: and
therefore it can noe way bee conveyed to the sensorium so
entirely as by the aether it selfe. Nay granting mee but
that there are pipes filld with a pure tranparent liquor
passing from the ey to the sensorium & the vibrating motion
of the aether will of necessity run along thither. For nothing
interrupts that motion but reflecting surfaces, & therefore
also that motion cannot stray through the reflecting
surfaces of the pipe but must run along (like a sound in
a trunk) intire to the sensorium. And that vision bee thus made
is very conformable to the sense of hearing which is made
by like vibrations.

From the whitenes of the brain & nerves the thicknesse of it vessells may
be determined & their cavitys guessed at. And its pretty to
consider how these agree with the utmost distinctnesse in vision.
As also with the extent of nature in conveying distinctly the
motions of the Aether.

<Apart from the page number, this page is blank except for possible shelfmarks and indications of library ownership.>

Of colours

If rays be incident out of glasse upon a film of
air terminated twixt two glasses, the thicknesse of
a vibration is 1/81000, or 1/80000 part of an inch

If water was put twixt the glasses the thicknes of
a vibration was 1/100000inch, of 3/4 of its former
dimensions. viz as the densitys of the interjected mediums.

If the rays were incident obliquely, the circles increase
so that their diameters are as the secants of the
rays obliquity
within the film of air, or reciprocally as their
celerity within the said film.

And the thicknesse belonging to each vibration is as
the squares of those secants of celeritys, And the
lengths of the rays belonging to each vibration
as their cubes.

The first pulse ends at the first dark circle

The thicknesse of a pulse of extream rubiform rays to that
of purpuriform ones perpendicularly incident is greater
then 3 to 2 & lesse then 5 to 3. viz as 9 to
14 or 13 to 20. And the thicknesse belonging to
each coulour is 13, 14 14 1/2, 15 1/2 16 1/2. 17 1/2. 18 1/2. 19.
for extreame purple, intense purple, Indico, blew,
green, the terminus of green & yellow, yellow,
orange, red, extream red.

Mr Boyle mentions one that by sickness became so
tender sighted as in the dark night to see & distinguish plainly the
colours of ribbans (& other objects) on purpose pinned on the
inside of his curtains against he awaked. Of the determinate
nature of Effluviums p 26, And of another that by a feaver
became of so tender hearing as to hear plainly soft whispers
at a distance which others could not at all perceive, but
when he grew well his hearing became but like that of other
men. Ibid.

Stipic vegetables, as gall, oaken bark, red roses,
Logwood, Sumach & turn vitriol to a black precipitate

To make excellent Ink.

1/2lb of Galls cut in pieces or grosly
beaten, 1/4 2114

of Gumm Arabick cut or
broken. Put 'em into a Quart of strong
beer or Ale. Let 'em stand a month
stopt up, stirring them now & then. At
the. end of the moneth put in 2125

1 or

1 1/2 of copperas (Too much copperas
makes the ink apt to turn yellow.) Stir
it & use it. Stop it up for some
time with a paper prickt full of
holes & let it stand in the sunn.
When you take out ink put in so
much strong beer & it will endure
many years. Water makes it apt to
mold. Wine does not. The air also
if it stand open inclines it to mold.
With this Ink new made I wrote this.

<This page is blank except for possible shelfmarks and indications of library ownership.>

Of Cold & Heate

To know the present density of the aire (whither it bee caused by heate
See Manuscript

& cold or by the gravity of the Atmosphaere or pressure of the Moone etc) use
an open weather=Glasse either with the included
aire above (fig A), or Below (fig B), or having
it seperated from the outward aire by a
movable drop of water onely (fig C) soe that the
instrument may bee capable of all positions.

The like may bee done (by filling the Glasse C with water etc)
if you would know the present density of water or any other
liquor. Or if you would know the present density of any sollid
body; fill one Glasse with water, & another with water & that solid
together, soe that the quantity of water in both glasses bee knowne
etc. AND note that heate & cold or the Atmosphaers gravity etc may
cause the glasse it selfe to rarify or Condense perhaps considerably
which may render the instruments the lesse exact & certaine untill
the expansion of Glasse be knowne

To know the Density of Liquors caused by heate etc without the
See Manuscript

weight of the Atmosphaere; seale those liquors up (fig D),
leaving a little aire in the top of the Glasse which may
give leave to the water to contract & dilate. And this
May pretty exactly discover the heat & coldnesse of the
weather, or of any sollids or liquors tis Applyed too; but
to find how much hotter or colder any body is then the present
aire is better don by the former instruments (fig C or B)

To know the present Elasticity of any spring weakened
See Manuscript

or strengthened by heate or cold; hang
a weight at the spring (fig E), or to
a spindle to which the (spirall) spring is
fastened (fig F) & the point of the
spring (fig E) or the handle of the spindle
(fig: F) will shew its strength &weakness & consequently the heat & coldnesse of the weather.
But note that it is heare supposed that
the weight of a body is always the same, & that tis only the
variation of heate & cold which varys the strength of a spring.
Which things deserve a further inquiry after. And indeed the
weight of the Atmosphaere varying will somwhat vary the weight
of other Bodys though not much. & this may bee remedyed by

Of Cold & heate

sealing up the instrument in a glasse receiver.

There may bee made a Staticall Baroscope to find
the Gravity of aire water or other liquor occupying a given quantity
of space at all times. see Fig G

And a Mercuriall Baroscope to find the weight of all the
Atmosphaere above us. & a Hygroscope for the moisture of the
aire. All which instruments being observed & compared together
in the same or divers times altitudes & places may discover
many things about heate & cold, vapors, rarity & density of bodys,
their gravity, & Elasticity the pression of the Moone, state
of the weather etc.

The Best liquor for the sealed Thermoscope is highly
rectifyed spirit of wine, brought to a lovely red with
Cochineele opened by the most subtile volatile spirit of Urin
by which meanes the liqour becomes visible, free from freezing
& yet very apt to bee rarifyed by the least impressions
from externall bodys such as would but faintly worke
on water though that bee easily apt to freeze. Boyle, p: 57

Mr. Boyle onece poyzed a Bubble of Glasse soe
exactly in water that it would ascend or descend more or
lesse accordingly as the water was more or lesse heated.
And in some parts of France watermen observe that Rivers
beare boats heavyer loaden in winter then in sommer
And some seamen observe their ships to draw lesse water
on the coasts of frozen Regions (though the water bee
fresher there) then on our British Seas. Mr. Boyle; pag 69 & 70 History of Cold

Our Senses are noe competent judges of cold because
our bodys doe heate those things to which they are contiguous
& hence things appeare lesse cold then others which are
more easily susceptible of the heate of our bodys (though really
they bee more cold. Thus aire appeares warmer then water
& water then quicksilver & yet by the Thermoscope tis
evident that quicksilver is warmer then water & water then aire.
& thus wee see the more sollid any Body is, the higher
degree of heate it will receive from fire or the sommer sunn
& retaine it the longer as also tis the longer in acquiring it
Mr. Boyle pag 6, 9, 10, 11, of his History of Cold

Of cold & heate

Hence winds are cold because they remove the contiguous
warmed aire from our bodys faster then our bodys can warm the
adventitious aire. And if wee blow violently on our hands it appears
cold because our breath agitating the neighbouring aire into vortices
makes it suceede the warme aire contiguous to our hands. But if
wee breath gently soe that our warme breath come to our hands
without agitating the neighbouring cold aire then wee feele it
warme.

But besides there may bee other causes of our senses being
imposed upon, as severall steams in the aire. Thus a little opium
is able to chill & coole the whole masse of blood in a man
though ten times a greater quantity of it dissolved in ten
times a lesse quantity of water is not able sensibly to coole
it. & in China (whose greatest latitude is but 42°) from the
midst of November to the begining of March the Rivers are
all so frozen up that ships are laid fast where the frost
first seizeth them & carts & horses etc securely passe
over them: & yet the inhabitants feele not so much cold
as would produce ice in Europe or compell an European
to the Chymney Corner. Which divers effects on theires & our
senses must bee referred to subterraneous exhalations. The
frost is mostly made in one day though dissolved in many.

Also hee that compares the reports of his senses to that of a
sealed Thermoscope will find some disagreement twixt them
that often shewing the aire to hotter when men judg it
colder & colder when they judg it hotter. Boyle: p: 6, 7, 15, 16,

And if heat bee nothing but the agitation of a bodys parts
there may be frigorifick steames which by fettering the parts of a
body may coole it (as well as the adjacency of cooler bodys)
& steames which are frigorifick to one body neede not bee
soe to another. as the instances of Opium & China seeme to
prove, thus the steames of leade deprive Mercury of it
fluidity but not water & yet water will freze when mercury
will not. And there bee severall liquors which mixed with
the agitated spirit of wine will bring it to a consistency etc
& there is a certaine substance which mixed with a certaine
liquor makes it appeare cold to sense, which has noe such effects
on water. Boyle: pag 50, 51, 52, 53.

And there may bee calorifick steames too which are so to one
body & not to another. for there are severall liquors & other
substances, which when mixed with other bodys produce an intense degree of heat in some but not in all bodys.

Of cold & freezing

And a sealed Thermoscope filled with spirit of wine beeing put
into a certaine liquor, the included liquore rose exceding slowly
& to a wonderfull height (8 or 9 inches in a stem of 12
inches long) & the Thermoscope being taken out & put into
cold water that       the liquor might subside in 5 or more
howers it              subsided not more then halfe an inch
& standing           all night in the aire it subsided not
sensibly           more. how much it at last subsided I know
not. Boyle      pag 60, 61.

Oyle of Annis=seeds which is a very hot & strong liquor freezes
sooner then water, & some liquors noe lesse peircing then aqua fortis
are easlyer congealeable then the generality of Chymicall Oyles &
salines spirits. Boyle: p 49.

Perhaps a wind striking deeper into our skin then the calm
aire may therefore appeare colder then really it is pag 6.

Severall acid Salts (as spirit of Sugar, & vinegar; but better of
Salt, & oyle of vitriol & best the spirit of Nitre)
being mixt with Snow or ice in a thin glasse bottle
would condence vapors on the out side of the Glasse
& freeze it into flakes of ice. The like might bee
done by Urinous salts though not so well (as with spirit
of Urin, & better of Sal Armoniack drawne from quick
lime). Also it may bee done with grosser salts as Sall Gem
with loafe & Kitchin Sugar, with a strong solution of pot
ashes, with a sweet solution of Minium in spirit of vinegre.
& very well with spirit of wine (though Chymists generally
esteeme it a Vegetable Sulphur). In Generall any thing
which hastened the dissolution of the Snow produced the effect
of freezing or condensing vapors with out side the Glasse. & therefore the fyery Oyle of Turpentine had small effect because it
dissolved the Snow or ice noe faster then common water. But warme
water powred into Snow (or heated Sand) produced store of
vapors on the out side of the Glasse & perhaps if prosecuted
might have produced Ice. The same effects were produced
though the Snow & salts were hermetically sealed
up in the Glasse. And the Glasse being weighed during the
experiment A mixture of Snow & Sal Gem or spirit of wine
weighing almost foure ounces produced an
of vapors weighing 18 or 20 graines in about a spoonefull. Boyle
from pag 108 to Pag 132.

Of Freezing

Of all bodys common sea salt dissolves Snow & beaten Ice the fastest
& makes it freze other bodys the soonest & hardest (pag 113), there
being mixed about 1/3 or 1/4 part of soe much salt as snow either at once
or gradually, & if you would freze an inclosed liquor begin at
the bottom or sides & let the top be last frozen least it break the Glasse pag 181.

Common Water, Urin, Beer Milk, Ale, Vinegar freze pretty easily,
French & Rhenish wine will freeze in cold weather but not so
easily, & so will a strong solution of Gum Arabick, white sugar,
nay of Alume Vitriol salt=peter, seasalt, & verdigrease
& so did spirit of Vinegre & Urin, & the lixiviate salt of Pot ashes
The last froze with branches like Christalls of Rocked Peetre some
lying level others shooting downe, & many other salt liquors are
prettily figured in freezing. Oyle of Tartar (at least a strong solution of
fixed salt of Tartar) was once frozen by snow & salt. pag 134, 135.

Common expressed Oyles may be deprived of their fluidity
so as to bee cut in peices but not frozen into truely brittle ice though the cold be more intense then tis
in England ( yet some say they may bee frozen to brittle ice)
And in Muscovy common Annised water and weake
spirits may bee turned into imperfect ice & very strong
spirits to a substance like oyle. pag 137, 139.

Aqua fortis Spirit of Nitre, of Salt, Oyle of Turpentine
& most Chymicall Oyles (yet the essentiall oyle of Anniseds etc freezes sooner then
common water so will the Empireamaticall oyle of common Oyle)
also spirit of wine & sack if very good & a strong brine of
common salt & Quicksilver could not be brought to freze. If the spirits of Sack
were burnt away the Flegme would freze. Traine oyle is
lesse apt to freeze then other Vegetable expressed oyles (which oyle is made of the fat
of animalls commonly of whalls). A solution of sugar of
Lead will not freze though its ingredients lead bee cold & spirit
of Vinegre will freeze. Sea Water will very difficultly
freeze but the ice dissolved is pretty fresh so that divers
in Amsterdam make beere of it. from pag 140 to 148.

The heate of liquors may bee knowne by immersing the
Thermoscope into them & the heate of Sollids by immersing
the Thermoscope into the pouder of the Sollid, or by making
the Thermoscope with a flat bottome so that it may bee closly
applyed to the Sollid. The actuall heat of liquors is lesse divers then one would think

Oyle of Turpentine of a moderate coldnesse being immersed
in water which began to freze shrunke one 94th parte & being
further refrigerated by snow & salt shrunke as much more

Of Cold & Freezing

so that in all it lost one 47th parte. It being put againe into
freezing water, it expanded. Common water of a moderate
state as to warmness could not be bee brought to shrinke more
then one 230th parte before it expanded by freezing. pag 161, 168

As heat extends farthest upwards (by reason that flame
& aire rarifyed with heate ascend) so perhaps cold may act
farthest downwards because the contiguous aire or water etc: condensed by cold
will descend: but experiments doe not manifest much difference twixt
the ascent & descent of cold: but the sphaere of its activity is very
small not reaching to freze much above 1/2 a barly corne length from
a mixture of snow & ice. pag

Perhaps as aire about a hot body (as red hot glasse etc)
ascending in refractive clouds makes remote objects seeme to
quaver soe aire condensed by cold bodys may descend in clouds
& have the same refractive property.

Bodys are preserved from corruption longest in the greatest
cold if they freize not. As in frozen regions beere & meate may
bee preserved in hogsheads under the ice without any decay
for many Months. And Bodys frozen during the time of
theire continuing frozen they manifest noe corruption. As
some say that in Greenland nothing corrupts & frozen carkasses
being buried have continued 30 yeares free from any
rotennesse. Bodys when thawed againe they manifest some chang
in their texture & that much more when thawed suddenly by the
fire then when leisurely of themselves or by being immersed in
water or rubbed over with snow. Thus bere & beef & chese
apples etc if long frozen & thawed by the fire become almost or
wholly insipid (the apples presently rotting etc), if thawed with water or snow
they will bee decayed but nothing neare so much. Frozen meat
layd to the fire to roast would not be well roasted & after
many hours it would yet continue raw in the midst & would
eate scurvily, but if it was first thawed in water it would roast
& eate pretty well. When a mans nose ears cheeks etc: are
frozen hee feeles it not, & if hee goe immediately to a fire
or stove hee loses the parts frozen, but not if hee rub them with
snow or dip them in water. A man frozen all over &
rigid being immersed into a tub of water hee was presently incrusted
with ice all over And soe recovered loosing only his finger & toe
ends. Another was recovered by being rubbed all over with snow

and all the while felt noe paine but a little prickling at his recovery.
Eggs, Apples, Chese men etc well frozen & thawed in water produce
a crust of ice about them; perhaps some solids as Glasse iron etc
may have the same effect pag: 605 etc. Frost makes stones iron (as the laths of
crosbows) mens bones nay horne p. 607 etc brittle, it cleaves wood (perhaps by swelling
it) & makes it very hard so that a tree well frozen cannot bee
cut downe unlesse first thawed with fire. & yet some in
England observe that wood will cleave best in frosty weather.
Things thaw faster in water then aire & therefore produce a
crust of ice in the water though they gather noe vapors on their
outsides in the aire, as a dissolution of snow by salt doth. In frozen
beere the strength & spirits recede into the unfrozen yeast. The
Christtalline humor frozen becoms white & some such thing happens in
frozen eggs, & they have severall concentric sphaeres involving one another from pag 184 to pag 222.

Water Milke urin Rhenish wine a solution of Dantzick Vitriol and perhaps solids etc shrinke with cold untill
they begin to freze & then they swell againe in frezing as appeares
by their breaking Glasses, their rise in the Thermoscope when froze at the bottom, the
convex swelling of ice in broad strong vessells, the swiming
of ice in the liquor unfrozen the standing of frozen clocks the cracking of frozen eggs, wood
pewter or iron vessells filld with water of solid brasse etc. Milk swells more by frezing
then Rhenish wine & Urin then milke, though Urin
is longer before it freze. Spirit of Wine though it will not
freeze yet after it had shrunke much by extreme cold began
to swell againe though not so much as it shrunke before.
Quicksilver by cold shrinks considerably, more then all the aire in its
pores amounts to, but it swells not againe noe more doe any
oyles whither common (expressed) oyles or essential oyles (drawne
in Lymbecks by the helpe of water & fire, or empyreamaticall
oyles driven out of retorts by violent fires; though they
will all shrinke considerably & some of them (as oyle of Anniseeds)
will freze. The ice of that & other oyles sinke in the fluid oyle. from pag 222 to p 244

The ice of common water & of other liquors appeares
full of bubbles (which may bee the cause of its expansion)
Some greate as a pease others like haile Shot mustard seed or
lesse. Which bubbles are not wholly filled with true aire For a glasse
full of water being wholly frozen & then sealed up hermetically
& then thawed againe, the water would subside to its station
before frezing; If you then inverted the glasse & immersed it
in water & broke of the tip of the stem, the externall water
would rush in till it had filled almost all the space of the stem which the
water had deserted (excepting sometimes a 4th, 10th parte or
lesse) so that the aire did not fill more then one 4th 10th parte or less
of the bubbles. whither that aire bee generated by frost (which

Of Freezing

may bee tryed by often frezing the same water sealed up
hermetically) or whither it lurked in the water before frezing
(for that water yeilds ice the most transparent & with fewest
& least bubbles looked on either with the naked eye or Microscope which has beene freed from aire by the aire pump
or whither both together is worth inquiry. Many bubbles ascend from
thawing ice to the top of the water. from pag 245 to p 278.

Water expands about one ninth parte in freezing & noe more
& yet there were Islands of ice 16, 20 etc fathoms above water & but 36, 40 etc
beneath it. (but they were made up of snow & fragment of ice
conteining much aire betwixt them & probably rested on the ground. & from p 279 to p 296

The expansive force of frezing water is so greate as to burst
peuter vessells & iron postell barrells etc And water being
hermetically sealed up with some aire left in the stem of the vessell
the swelling water crouded the aire into 19 times lesse roome before
it broke the glasse. At other trialls when the aire was compressed
into 9 times lesse roome the glasse being inverted that the
unfrozen water & the aire might change places, & the tip
of the stem being broken of so much water rushed out
into another vessell till the aire expanded
itselfe into nine times more roome from pag 296 to p 327. & p 587.

Snow & salt will freze through glasse, iron, brasse, space
voyd of aire, or filld with (the not freezing liquors) oyle of
Turpentine, spirit of wine & Brine (though more difficultly through the last)
& Tunbridg Minerall waters feele cold to the hand through
the abdomen. from pag 345 to pag 363.

Frost in England seldom peirces the earth more then a yard
in Charlton Iland 2 yards & water not so much yet a
pipe of water frezes not so deepe when thrust into the earth
as when swiming on the earth: (water has beene frozen to many cubits pag 389) Dubito&lt. pag 329 etc.

A peice of Ice inches broade & inch thick being
laid on two leavers 3 inches distant was broke by the weight
of 17 lib: Averdupois & ounces Troy hanging on its midst
which argues ice much stronger then one would thinke so soft
a body. Ice two fingers thick beares a man, 3 fingers a
horsman, 6 fingers a Regiment, 12 vel< 16 fingers an
army. but all ice is not alike strong, & when it thaws it
grows brittle. A corne of bay salt layd upon
ice by dissolving it sinks into it & makes it freze in that
place to the board or stoole that the ice lys upon the like doe common salt & Saltpeter. Oyle of
Vitriol dropped on ice quickly soakes through it & appeares
in corrosive drops on the other side. So dos good aqua fortis but
not so powerfully & yet it makes a cracking in the ice which Vitrioll
doth not; soe salt throwne upon ice makes a cracking &

Of cold Freezing Subterraneous vapors, etc

besides a steame to ascend like the smoak of warme meate
The icy islands (which are 1, 10, 20, 50, 100, 200 miles long etc in
some places mixed with earth, eggs etc& some peices the ice being of
an azure colour etc) make a very great noyse sometimes like canons
perhaps partly by islands clashing together or peices falling downe or
being burst by rarefyed warme exhalations or by the swelling power
of extreame cold etc. from pag 364 to 394.

Equall peices of ice were dissolved in oyle of Vitrioll in 5min
spirit of wine in 12min, Aqua fortis in 12 1/2min, Water in 12min
Oyle of Turpentine in 44min, aire in 64min. Again ice of the same
bignesse was dissolved in Oyle of Vitriol in 3min, Spirit of wine 13min water 26m
Oyle of Turpentine 47m, Sallet oyle 52m, aire 152min. Ice is not so
easily dissolvable as one would imagine In Italy they
preserve it in conically barded pits flat at the bottom with a grate for
the melted water to run through, twixt every cake of
ice well & hard beaten together they lay a layer
of straw & thatch it, they are usually 25 foot wide at the top
& 50 in depth from pag 396 to 412.

Water begins both to freze & thaw next the aire & land it never
frezes at the bottom or midst of maine seas though never so
northward yet water apeares extreamely cold to Divers at the bottom
of the sea to which the suns rays scarcly penetrate, & those countrys are coldest (ceteris paribus<) which are
nearest the seas & shores are colder then maine land or sea & maine Sea colder then maine land. &
the icy islands are generated in straights & neare shoares. The
suns heate scarce penetrates more then six or seaven foot into the
earth whence to about 80 or a 100 fathoms reaches a pretty coole region
of earth, & after that they feele it perpetually hotter then in the
open air & in some places intollerably hot accordingly as
the earth abounds with veines of vitriol or other hot mineralls. And this is observed
in all the Hungarian Mines some of which are 1800 or 2400 foot
deepe. After about 180 foot the heate of the Mine is not sensibly
increased by its greater depth. Out of these mines there ascends a vapor
visible enought above the mouth of the pit & sensibly warme though
it hath passed through 100 or 500 feet of the cold upper region. Perhaps both that steame
& heate may arise from a dissolution of Vitrioll or other mineralls
in water (Or bee the ascent of the gravitating streames in another
forme & impregnated with minerall vapors) And yet there is found
the same heate in a salt mine of Poland (50 ladders deepe or more
in the mountaine) where there is noe vitrioll. These exhalations are
mostly saline fretting noysome & combustible though they much differ
in divers mines for out of a gaping peice of ground in Hungary there
issue such mortall fumes as kill even birds that fly over it & in
the North of England is a ditch where fumes ascend that take fire
at a Candle & burne as long as you please. so at the fresh opening
of some close vaults & cellars ascends a very visible dampe vapor (which will
sometimes take fire at a Candle) and the stagnating fumes in many

Of Cold Freezing & Subterraneous vapors

mines are often soe grosse as to suffocate men & very often in
most (or all) deepe mines they take fire which will bee hot enough to
scorch a mans skin (unlesse hee nimbly retire or fall flat downe
whilst the inflamed vapor ascend with a report at the top like a
musket. Miners can foretell by the more or lesse copious ascent
of these steames (which they perceive by the blewness of their
candles) when & how great stormes shall ensue though the present sky bee cleare. And the fishermen in Conwell
(where the tin mines abound with most pestilent damps) when
they perceive shining fires in the night make to shore to
shun the ensuing storme. And not long since some royall ships
in a Calme neare Ireland were almost wracked by a sudden
tempest which a Pilot predicted from a black cloud ascending
out of the water not much unlike & unequall to a Barrell. Cellars are
Much cooler in sommer then the free aire & somwhat
cooler in winter then in sommer though somtimes they may
be a little warmer in winter by reason of subterraneous
vapors pent up by exteriors frosts which closes the pores of the earth as some country men
observe that snow keeps the ground warmer, thus the
Lake Vetor (pag 777) when the weather grows warmer on a
suddeine boyles at the bottome with horrible noyses & the
ice cracks & becomes clifted & presently dissolves. And at
‡ <in mg:>See p: 502 & 778 ‡ The Royall City in China Peking the Lakes & Rivers which
were many days in frezing are thawed in one beginning at
the bottom of the ice which must needs bee effected by the sudden
ascent of vapors pent up with cold till their copiousnesse &
warme weather caused an eruption. Water newly drawne out
of wells in winter reeks especially if a little agitated, not
because it is warmer then in sommer but because the vapors
like our breaths are quickly made invisible being rarifyed
by the hot summer aire. Thus a steame may bee seene upon
rivers in a summer morning which disappears at noone. A
solution of Salt peter in water is warmer then common aire but it may be frozen.
& perhaps saltpeter sea salt & severall other bodys volatile in the
aire may cause frezing by driving the frigorifick attomes into
water out of the aire & earth (or evocating some active subtil
matter from the water). From pag 412 to pag 463 & from pag 741 to pag 803.

The thermoscope subsides but very little more in the Receiver
exhausted then full of aire which perhaps too may not bee so much
caused by the coolness of the vacuum above aire as by the streaching
of the Glasse thermoscope freed from externall pression, For the
liquor suddenly ascended at the intromission of the aire. Yet aire
conveys heate through it perceptibly better then a vacuum. Aire
contracted one 22th parte by the cold of a very frosty night &
one 10th parte by the application of ice & salt: (as
much as water swells by freezing). neare the Line there are
high hills on whose tops at noone day men & beasts are benumbed

Of cold & freezing.

with cold & yet Greenland (whose Lattitude is 80°) is habitably warme
& beares grass which Nova Zembla (whos Latitude is 74°) by reason of its
great cold doth not. In Russia where the Summer is warmer then in
England the winter is so cold as to freze spittle or water throwne
up before it fall to the ground. The like of of new England whos latitude is 43° & Charlton Island (whos
Latitude is 52°) nay in the same day that Island is intollerably hot in
the day time & freezes an inch thick in the night. Constant
winds may perhaps have as much influence on the Temperature
of places as theire Latitude; but yet winds much partake of the
nature of the place they move over & the same wind (pag 511) in
divers countrys may have divers qualitys. Thus aire blowne through
the refrigerating mixture is colder then otherwise; & in some parts
of the Indys there are winds which fret & rust Iron & make it
friable. From pag 464 to pag 520. & some winds feele hot pag 824.

In one night at Nova Zembla the salt sea was frozen two inches
thick & the Holanders burnt their clothings before they could feel fire. At Musco the Market place cracked by frost one foot
wide & many yards long. At Charlton Island a brass pan of
water set so neare the fire as to be warme on one side
was frozen an inch thick on the other. Extreame Cold alters
mens voyces, makes the skins of many animalls white, the gutts
of men (frozen there to death with much torment) black. from p: 520, to p: 549.

The weight of water frozen & unfrozen seems to bee
the same pag 550 etc & yet in frosty weather the Atmosphaere
seems to bee heaviest (though it is then clearest & freest from
vapors) pag 483.

The ice of fragrant or stinking liqours Smells much fainter
then the liquors pag 579, 581. The Russians in winter usually goe naked
out of their stoves (if ready to faint with heate) & cast themselvs
into snow or cold water. p 583. A large concave discovers not
the Moones beames to bee either hot or cold though trajected
on a Thermoscope. p 584.

Nitre dissolved in thrice as much water cools it sensibly
during the solution (yet nothing neare to congelation) but after the
Nitre is dissolved the water grows warme againe. p: 594 & see
pag 458. Cold water sooner freezeth then hot & as soone as
cold water that once was hot. p 615, 621. The pure & cold wind in
Iceland (with the Sun) hardens & preservs fresh flesh & fish better then
if it were salted p. 627. Fishes (Gudgeons) though quite frozen
up as to become rigid yet recovered, & perhaps if they dy in
Ponds frozen up the cause may bee subterraneous vapors or a
stifling sudor from themselves pag 635 etc. Cold retards
fermentation making beere tast new & preserving wine in
the must a long time; nay wine if before fermentation begin
it bee put under water in a Coole well for 6 or 8 weeks is
so satled in its constitution of Must that it continues so without
fermenting for many Months after p 649.

A solution of Minium or quick lime in water will coagulate a
just proportion of good (expressed) Sallet Oyle to an Unguent

Of heate cold & freezing.

which by a Thermoscope appeares noe colder then the liquors before
coagulation p. 688. The liquid parts of frozen apples by swelling bruize
their sollid parts now an apple quickly corrupts where tis bruized p:663.
the ice of severall liquors is variously branched with pretty figures
& severall fumes diversly ascending (according to more or lesse
heate) depaints various figures of trees etc though the fumes bee
minerall, but to make the shape of a tree by freezing water
tinged with the juice or ashes of that tree is improbible or accidentall
pag 675 etc. The pores & texture in severall vegetable & animall
substances (as carrots greene wood neves the braine eyes
muscles livers tongues etc) may perhaps bee best discovered by
frezing the juice in the pores & then cutting it squezing it out etc
pag 657. A glasse egg filled almost with water & sealed
Hermetically, & frozen at the bottom to try if the unfrozen water
was capable of compression, when the apex of the stem was broken
of the compressed aire flew out with greate noise & the stem
where the water reached not was filled with white smoke & froth many
bubbles also rising from the bottom of the water (as when
bottle beere is opened) & the water it selfe rose 3/4 inch more
then the lurking aire could expand it selfe, but it is dubious
whither to ascribe that expasion to the water or ice or the glasses
contraction pag 691.

If a man drinke in summer (when hot) it presently maks him sweat.

Quick lime quenched in cold water maks it hot, in hot water
maks it hotter, in water just done boyling makes it boyle againe
vehemently. It grows much hotter if quenched in spirit of salt then
in water but in oyle of Turpentine or spirit of Wine etc it
produces scarce any heate at all, though for many howers immersed
because it was not dissolved by those liquors.

Towards the end of January in frosty weather fell a verygreate haile storme
(though they fall most in summer) in which storme a maid was
misled by an Ignis fatuus&lt);. In those parts of Egypt where it
raignes plentifully (as about Alexandria & Pelusium etc but not
at Grand=Cairo), it never snows nor hailes & so in hotter
Countrys. Haile has often snow in the midst. p 737. 739.

Water freezes almost as soone in Boyles exhausted receiver as in the
open aire, but the ice in the Receiver appeared whiter & fuller of bubbles
A solution of Alume frezes sooner then water & to a milk white & very firme
ice Solutions of Vitriolls freeze sooner then that of Allum & almost to as
white & firme an ice pag 4 of Dr. Merret. Most Stinking & sweet liquors
frozen when thawed againe their scent is almost lost p. 6. And frost
often makes the salt, spirits & colours of divers liquours recede from the
ice to the unfrozen liquor p. 6, 9, 12, 13, 29, 48.

Perhaps severall salts where they abound in water or aire etc most
by heating those mediums coole the vicine regions (as may
appeare by the solution of snow & salt) & tis worth trying whither

saltpeeter or common salt etc agited much in water to
dissolve doth not expand the water by heate though it seme cold
to the touch & Thermoscope. For such solutions are very difficult to
bee frozen & perhaps would hasten the freezing of other liquors though themselves freze not. Sal Gem is most difficult of all salts to bee frozen p 8

Oyle of Vitriol frezes neare as soone as water whose ice (or
coagulum) shrinks in freezing has a strong vitriolate tast & is paler then the unfrozen oyle
& much longer in thawing then any other ice. This frozen &
unfrozen oyle mixed together well in glass violl heated it so hot
then none can endure to touch it p 8.

Some Liquors are not impaired by frost p: 11 & 48

Freezing may bee of great use (in cold countrys) for seperating salt or
spirits from the flegmatick water, a stinking bottle filled with water &
frozen becoms sweete.

Some Ice has bubbles like haile shot with sharpe tailes
pointing towards the outside of the ice p 21.

Snow balls moistened with water & then strongly crouded
together & frozen will somtimes sinke in water. p 34. Newcastle
cole preserves from freezing better then sand or ordinary earth.

Speculums of ice like burning glasses produce noe (sensible) heat
in their focus, but water frozen in sphaericall glasses would heat
a little p 38. Distilld Snow leaves a foule earth behind it. p 40
White of Eggs or water beaten to a froth & frozen looks like snow.

The Duke of Tuscany distilld spirit from wine without fire
by putting snow on the Alembick. & the Duke of Mantua had a
pouder which in summer congealed water quickly into ice p 44

Apples etc frozen & immersed in water bee
cased with ice. p: 50. If water bee often spread thinly over ice it makes
ice of a far greater thicknesse then otherwise it would bee. p: 51.

Aqua fortis without any sensible heate will make Camphire
cast on it assume the forme of a liquor distinct from it, & a
strong fire will but melt Camphire. & there is a liquor into which
certaine bodys being put (though both it selfe & they are
actually cold) will speedily dissipate many of their parts into
smoke & leave the rest black & burnt almost like a Coale
pag 55 of Mr. Boyles Origin of formes. Two peices of
Resinous wood rubbed hard & long one against another will
visibly smoke & turne their superficiall parts into a kind of
Coale. pag 77

A pound (or lesse) of Sal Armoniack put into 3
or 4 times as much water will produce a considerable
degree of cold both to the sence & Thermoscope
condensing vapors into dew on the out side of the vessell & sometimes
(if the weather bee not too hot) producing ice. If you would
have an intense (but short) degree of cold, pouder the salt
finely, put it in all together & stir it well to hasten
the dissolution. But if you would have the cold rather

lasting then intense: put the salt in grosly beaten at
3 or 4 severall times, & stir it but a little, &
to make the cold both longer & more intense you
must use the more salt & water. And this may
serve to coole drinks, the hands of Patients, or the aire to
adjust weather glasses. etc. March 27 A Thermoscop
(whose ball was big as a walnut its shank 16inches long
& 1/8 or 1/9inch diameter) stood at 8 5/8inches in the aire, & at
7 5/8 in water but when the Salt was put in
it begun in 1/8 of an howr to freeze the vapors without
the vessell. & in 1/4ho the thermoscope descended to 2 11/16inch
& water thinly placed without would (while the mixture
was nimbly stirred) freez in 1/4min by a minute watch.
after 3/4 hower the Thermoscope stood at 3 3/4inch. afer
2 1/2ho at 5 1/8; after 3ho at 5 1/2inch, the mark at
which water begins to freeze in winter; The hardest
frost making the liquor descend but to 4 3/4inch.

In Christmas January 28, 29, & 30, 1669
It being extreame cold weather I tooke
a violl bottle & filling it with water
up to the mouth I put a glasse pipe into
it AE soe that the bottom of it E
might reach almost to the midst of
the glasse or about a third part into
it, & I sealed it close with wax soe that
noe aire or water could get in twixt the
pipe & bottle. Then I set it up almost to the mouth in snow & salt
well mixed & stirred together & often supplyd
afresh to make the freezing the smarter. & when
the bottom was frozen above haff way up
I applyed snow & salt higher & higher till
I froze it up to the mouth; in the meane while
putting a wier downe the pipe &
often stirring it to keepe the passage open for
the water to ascend freely as it was swelled by

freezing, which it did to a considerable height,
Then I set the glasse in warme
water to halfe its height to thaw the ice at
the bottom first that there might bee noe violence
done to the wax at the mouth D to let in any aire there. And I observed
1st that the ice thawed fastest by much towards the superficies
of the water though in all probabily the water
was couldest there being contiguous to the cold
aire. 2dly That the bubles with which the
ice was full (& thereforelooking white) that those bubles I
say continually ascended to the top of the
thawed water & contined in the forme of
permanent aire. When the ice was thawed up to the
bottom of the pipe & a little higher that the said
aire might rest above the mouth of the pipe
I put a wire downe the pipe to thrust the ice
out of the pipe into the bottle that the thawed
water might move freely in the pipe, & I
observed that the water sunk suddenly a pretty way
in the pipe & afterwards it sunk gradually
as the remaining ice thawed. But it not halfe
soe much as it ascended in freezing The ice being all thawed
there remained a considerable quantity of aire
in the top of the violl which
extruded the water to a pretty height in the pipe
Suppose D the height of the water in the pipe
before it was frozen B its height when frozen
C its heigh when thawed againe, FGD the aire
made by freezing. I froze the same water again
after I had let it stand some howers to observe
whither there would bee any change made in the new

produced aire, & all the same effects suceeded
againe & about as much aire was produced
more so that now there was twice as much aire as
before & I doubt not but by repeating the
freezing the aire three or foure times more there might bee aire enough
produced to reach down to the bottom of the pipe

Not having measured the quantitys of aire &
water in these two tryalls (for I made
them only to satisfy my selfe whither those bubbles
made in Ice were true aire or noe) I repeated the
experiment with other water,
first I weighed the water that filled the bottle &
found it foure ounces, 1/64 parte; Then freezing it
it ascended from D to B 13 2/3 inches, then thawing it
it descended from B to C 4 1/2 inches, where it
stayed descending only a little for an hower or
two till the water had recovered it selfe from the
effects of the cold. By weight I found the
cavity CD to conteine 1/4 ounce & BD 3/8ounce of
water, Soe that of the 3 3/5 ounces of water which was
frozen (for about one tenth part thereof in the
pipe was not frozen) tooke up about a tenth part
of space more when frozen then before, then it
lost about a 30th part of that space by its
contraction in thawing & the aire which it yeilded
tooke up the remaining 15th part. But these
proportions I conceive may vary 1st according the various
degrees of freezing for a violent freezing by snow
& salt makes a white ice fuller I beleive of aire
then otherwise. 2dly By the nature of the water. 3dly
by the temper of the weather which according to
its more or lesse coldnesse may variously condense
the aire in the glasse after the water is thawed.

I further observed that in the action of frezing
severall bubbles ascended from the increasing ice to
the top of the glasse & there stayed in the forme of
aire

A Bolt head filld with spirit of wine up to
half its stem & set in water ready to freeze shrunk
not after ward in the freezing of the water, though
it was frozen round about, nor did it rise in the chang
of weather till the ice was thawed. Being set in snow
it shrunk a little, perhaps by reason that there was made
a little dissolution of the snow; & being set in snow
& salt it shrunk very much below the mark it
stood at when frozen round in water.

A furnace of sand grows hotter at top for some
considerable time together, (it may bee a 1/4ter of an
hower) after the fire is taken out or decays, then
when it was hottest: & if the fire bee put in againe
it grows colder at the top

There are liquors which will grow hot by the bare
mixing of cold water, & a mentruum into which nothing
but flesh being put without ebullition cause an
intens heat. Boyles Philos. part 2. p 44.

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Rarity, Density, Elasticity, Compression etc

Hot water (though not boyling hot) put into the Receiver, when
the aire was exhausted, it seemed to boyle afresh & very
vehemently Mr. Boyles Experiments, Experiment 43. And spirit of
vinegar when it corroded Corrall in the exhausted Reciver
boyled vehemently, though it did not so in the aire, & yet
for all its boyling the liquor was not sensibly warme

Spirit of wine in the exhausted Receiver (after it had
emitted a very great number of aeriall bubbles, for spirits
are most apt to have aire intersperced) seemed to bee
considerably expanded beyond it former dimensions
& the aire being let in it yet retained its expansion or
lost but very little of it in a nights time. Experiment 24

Silver etc by Hammering attaines a Springinesse pag 169 of Form Boyle
& by fire becomes flexible againe

The sealed Thermometer or another wholy like it but made with oyle with the heat of my
body (to which I equal that of a bird hatching her
eggs) stands at the degree of 17 3/4. March 10 1692/3
When water begins to freez it stands at the
degree      When water begins to boyle, at
the degree      When water boyles vehemently
at the degree      When water is as hot
as the hand can endure to stay long in
at the degree 26. When tin begins to melt
at the degree      When wax begins to
melt at the degree.      When molten
tin sets, at the degree      When molten
lead sets, at the degree      When molten
wax sets, at the degree

By dipping a bolthead with a short neck
into hot water & holding it with its neck under
water for 6 or 8 minutes till the glass be as hot
as the water; then stopping the glass with my
finger, inverting it into a vessel of cold water,
taking away my finger letting it stand for an hour
to cool; putting my hand into the cold water &
stopping it again with my finger when the

water within & without the glass, taking it out &
weighing the water drawn up into the glass &
the water which will fill the glass & making
allowance for the ascent or descent of the
Barometer I found how much the air
was rarefied by the heat of the the water: &
by a barometer of Lintseed oyle I
found also how much the oyle was
rarefied by the same heat. The experiment
I made twice & found the first time that the
rarefaction of air was to the rarefaction of
water in equal heats as 10 1/9 to one, the second time as
9 14/15 to one. Tis therefore in round
numbers as 10 to 1. By another way of
recconing I found that the rarefaction of this oyle
was to the rarefaction of spirit of wine
in equal heats as 15 to 1 or thereabouts for I did not
mesure this proportion accurately. So then the
rarefaction of air was to that of e308

in equal
heats as 150 to one.

The space which Lintseed oyle took up with
such a heat as I could give to a little bolthead
with my body was to the space which it took
up in such a degree of coldness as made water
begin to freez, as 41 to 40. And therefore
the spaces which Air took up in the same
degrees of heat & cold were as 50 to 40 or
5 to 4.

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Of fire, flame, the heate & ebullition of the heart &
Divers mixed liquors & Respiration

The flame of spirit of wine is hotter then one would imagine,
being able to distill liquors & melt crude Gold. post (after) Experiment 41.

Drebble made a vessell for King James saile under water with 12 Rowers
besides other passengers, & to continue the included aire fit for
Respiration hee often unstopped a bottle of a certaine liquor whose
spirits flying about into the aire made it againe fit for
respiration untill those spirits were spent upon the lungs &
heart. Digression after the 41 Experiment

A Bitch big with whelps dissected. & One of the puppys
taken out into the free aire began presently to open its mouth
wide, move its tongue & exercise respiration & being opened
hee continued an endeavor to respire moving his Diaphragme
& intercostall mustles notably & his heart continued beating
4 or six howers. But the other puppys
being taken out & opened before they could
have time to breath shewed noe perceptible motion of their
heart, (whereas had they beene kept much longer in the
secundines after the opening of the bitch, they might have livd
& at their being taken out of the liquor into aire
might have began to breath & livd. Digres: to Experiment 41.

Fire Coles, & flame goe out much quicklier in the
receiver emptied then full of aire. soe Animalls dy
speedily upon the exsuction of the aire, though indeed small
insects recover againe after the aire is let in though they
have long beene kept in the Receiver exhausted of aire
Experiment 40, 41 & Digress to Exper 41.

It may bee worth trying how long peices of the same heart
continue beating in the free aire, in the Receiver & in water.

A man having drawne in his breath & detained it as
long as he can: if hee then expire it, it him not
unless hee immediatly draw in fresh aire. But if a man expire his
breath & continue as long as hee can without it & then draw
in fresh aire that refreshes him & hee may continue as long
before hee expire that aire as hee did before hee drew it in.
& a man may continue with his lungs full of breath longer
then hee can with them empty

Observing that a match of brimstone being melted soe
as not to burne, that it might send forth its exhalation if
it were held in a place but moderately hot soe that the

match it selfe did not fire yet the exhalations issuing
from tooke fire & made a faint blew & large flame
not so hot but that one might endure one finger in it for
some time. Hence I conclude that flame is nothing
but exhalations set one fire & that a burning coale
& a burning flame differ onely in rarity & density.
flame being nothing but a company of very
little burning coales dispersed about in the aire. And that
flame & vapour differ onely as bodys red hot & not red
hot or cold. Flame seemes to bee nothing but the particles of vapor
made so hot as to shine

And this seems to bee confirmed in that the flame burnt
at a distance from the match & kindled first at the top of all
when the fume was thinnest, the like may be some times
observed of a candle when its going out that the flame
riseth from the weeke. That the fumes of a candle
are more crasse & stinking when the flame is out then
when its in: which difference must arise from the
beeing burnt in the flame. 3 that a candle newly out
will catch fire at a distance from annother candle
by meanes of its fume, especially if the candle
bee held over it, for so you shall see flame
manifestly descend by the fume. That spiritous
fumes as of strong beere wine strong water etc
will take fire at a candle. That bodys which fume
not flame not, as metalls which yet if they can bee soe
opend as to fume they will flame: as may bee
seene in metalline filings which (by reason of their grat
proportion of superficies to their bulk) emit fumes more
plentifully then greater bulks of metall. That any fume
eaven that of water may by heat bee made
a flame. It might bee tryed whither vapor of water
driven through a pretty long red hot pipe will not come out a
flame. In a word that degree of heat which can make
a gross body luminous must needs make the parts of that
body when raised into fume become luminous, for the
smaller bodys are, the more they are capable of the
impresse of heat as may bee seen in making gunpouder etc

Hence it appeares why flame in the exhausted receiver descends
not. That were fumes permanent as grosse shing bodys
(suppose coales) are the flame would need noe supply: Unlesse
perhaps to conserve the heat which I guesse is made by division of
parts: for when two particles are parted it makes the Aether rush
in betwixt them & so vibrate: just a drop of 263f

(if lively & cleare)
when tis gently parted into two the parts will leap assunder
& that to a good distance if the drop bee very small & laid
upon an eaven smooth plane.

The Phosphorus

Take of Urin one Barrel. Let it
ferment in the sommer for thre months. Then
evaporate it to a dry masse. Take of
this masse eight ounces, Of sand or
Bole Armenic two pounds. Put them
mixed together into a Flanders Retort
& place it in a reverberatory fire.
Lute to it a Receiver full of water,
& give a very strong fire & the
Phosphorus will come over.

Note the Retort must be good & close
which you will know if you put it
into water & blow into it.

The fire must be exceeding strong

When the desillation is done put
the receiver into a sand heate & the
Phosphorus will melt together.