PHOTOGRAPHIC INVESTIGATIONS
OF FAINT NEBULAE

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Publications of the Yerkes
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VOLUME IV PART II

PHOTOGRAPHIC INVESTIGATIONS
OF FAINT NEBULAE

BY
EDWIN P. HUBBLE

THE UNIVERSITY OF CHICAGO PRESS
CHICAGO, ILLINOIS

Copyright 1920 By
The University of Chicago

All Rights Reserved
Published January 1920

Composed and Printed By
The University of Chicago Press
Chicago, Illinois. U.S.A.

PHOTOGRAPHIC INVESTIGATIONS
OF FAINT NEBULAE[ [1]

By Edwin P. Hubble

The study of nebulae is essentially a photographic problem for cameras of wide angle and reflectors of large focal ratio. The photographic plate presents a definite and permanent record beside which visual observations lose most of their significance. Perhaps the one field left for the older method is the measurement of sharp nuclei deeply enshrouded in nebulosity. New nebulae are now but rarely seen in the sky, although an hour’s exposure made at random with a large reflector has more than an even chance of adding several small faint objects to the rapidly growing list of those already known. About 17,000 have already been catalogued, and the estimates of those within reach of existing instruments, based on the ratio of those previously known to those new in various fields, lie around 150,000.

Extremely little is known of the nature of nebulae, and no significant classification has yet been suggested; not even a precise definition has been formulated. The essential features are that they are situated outside our solar system, that they present sensible surfaces, and that they should be unresolved into separate stars. Even then an exception must be granted for possible gaseous nebulae which appear stellar in the telescope, but whose true nature is revealed by the spectroscope. It may well be that they differ in kind and do not form a unidirectional sequence of evolution. Some at least of the great diffuse nebulosities, connected as they are with even naked-eye stars, lie within our stellar system; while others, the great spirals, with their enormous radial velocities and insensible proper motions, apparently lie outside our system. The planetaries, gaseous but well defined, are probably within our sidereal system, but at vast distances from the earth.

In addition to these classes are the numberless small, faint nebulae, vague markings on the photographic plate, whose very forms are indistinct. They may give gaseous spectra, or continuous; they may be planetaries or spirals, or they may belong to a different class entirely. They may even be clusters and not nebulae at all. These questions await their answers for instruments more powerful than those we now possess.

Our present hope is to study them statistically, but until motions, either radial or transverse, have been detected we must content ourselves with the problem of their distribution. The first step is to make a systematic survey with powerful telescopes. Fath made a beginning by photographing each of the Kapteyn fields within reach of the Mount Wilson 60-inch reflector with uniform exposures of one hour. He discovered more than eight hundred new nebulae, and confirmed the fact that the small nebulae avoid the Milky Way. This last is vital in its bearing on the question of whether or not these objects belong to our system. A survey with long exposures suggests itself, analogous to that of Kapteyn, but based on the Milky Way rather than on the equator. The writer attempted such a program with the Yerkes 24-inch reflector, giving two-hour exposures. Little progress was made, but one fact stood out, namely, that in the fields of galactic latitude -60° nebulae were very scarce when compared to the numbers met with in galactic latitude +60°.

The tendency of small nebulae to gather in clusters has been known for some time. Stratonoff’s map of the distribution of faint nebulae in the Northern Hemisphere shows it very plainly. Max Wolf’s more detailed study of the ecliptic regions with the 16-inch Bruce camera and the 30-inch reflector demonstrates that within these larger regions of the sky where nebulae tend to congregate there are points of accumulation about which the clustering is more marked. He measured the positions of more than four thousand new nebulae, and devised a classification which, while admittedly formal, offers an excellent scheme for temporary filing until a significant system shall be constructed.

The present paper has to do with certain clusters of small, faint nebulae which the writer found during the years 1914 to 1916 while photographing with the 24-inch reflector of the Yerkes Observatory. From about 1000 uncatalogued objects, 512 in 7 well-defined clusters were chosen for measurement. Known nebulae in the clusters numbered 76; hence there were, in all, some 588 objects, or an average of 84 per cluster. The fields are as given in [Table I].

The problem of measuring and reducing accurate positions of objects at a considerable distance from the center of plates taken with a reflector of so large a focal ratio, 1:4, presented serious difficulties. The area covered by each plate is a square of some 110´ to the side. With the full aperture the stellar images are sensibly round only within 5′ of the optical center of the plate. From there outward the coma becomes more and more prominent, distorting the images first into an oval, and finally, near the edge of the plate, into the shape of an arrow, while the point about which the images build up becomes more and more eccentric. For images of various sizes this point will be at various distances from the centers of figure, and at 40′ from the center will fall very nearly at the point of the arrow. This introduces at once an overwhelming magnitude-error, masking whatever distortion of the field may exist.

TABLE I

FieldCenter (1875.0)Number
αδ Known New Total
I0ᵐ30ˢ +31°44′ 21 57 78
II1 42 20 32 0  3 81 84
III11 3 54 29 27  8178186
IV13 37 10 56 21 21 52 73
V14 57 10 23 47  3 49 52
VI17 11 22 43 50  5 43 48
VII23 14 16 7 27 15 52 67
Total 76512588

If very faint stellar images could be used for reference, this error could be largely reduced. It was necessary, however, to use stars from the catalogues of the Astronomische Gesellschaft for reference, and with the long exposures required for the faint nebulae the images of these stars were very large. At the edge of the plate, for instance, the arrow-shaped image of a star of the ninth magnitude would often be fully a minute of arc in length.

It seemed inadvisable to make an exhaustive study of this magnitude-error, whence the alternatives were to use a restricted portion of the field or to sacrifice accuracy in the reduced positions. The second of these evils was chosen. The positions of the optical centers of images at various distances from the center of the field were determined empirically. Pairs of plates of a region were taken with apertures of 9 inches and with the full 24 inches and were compared in the Zeiss “blink” comparator. With the smaller aperture, and hence the smaller focal ratio, the images near the edge of the plates were sensibly round and small. Superimposed on the 24-inch images, they indicated where the wires should be set in measuring the larger distorted images. Trials were then made, measuring positions of A.G. stars all over the 24-inch plates, until a kind of technique was acquired. Judged by the aims in view and the results obtained, this empirical scheme fully justified itself.

At least two plates of each field were taken. In any case the two best plates were put on the “blink” comparator, and only those objects clearly nebulous on both plates were marked. The better plate was then placed on a Gaertner measuring machine. The nebulae and all the A.G. stars fainter than the seventh magnitude were measured in X and Y with the same screw. After an interval of a day or two the plate was remeasured. Settings were read to 0.01 mm, corresponding to about 0.87" on the scale of the plate. The two measures of a nebula differed but seldom in this unit, and if faint reference stars could have been used, a higher degree of accuracy could have been maintained throughout the work.

In order to orient the plate, two stars were selected with as large a difference in right ascension and as small a difference in declination as possible. The difference in X was then computed in millimeters, assuming a scale-value of 87.4″ per mm. The plate was placed in the measuring machine with the meridian roughly perpendicular to the screw, and adjusted with the tangent slow-motion until the setting on the two stars gave the computed difference to the limit of accuracy of the settings. This method reduced the constant of orientation of the plate to an almost negligible quantity.

Turner’s method (The Observatory, 16, 373, 1893) was used as the basis for reducing the measures. The six plate-constants for each field were determined from the five or six A.G. stars most symmetrically distributed about the optical center, and graphs were constructed from which the values of Y-Y₀ and X-X₀ were corrected. The Δα and Δδ were then added directly to the α₀ and δ₀ of the assumed center, and final corrections to the positions were read from graphs constructed from Turner’s formulae. Any A.G. stars not included in the determination of plate-constants furnished checks.

Since the distribution of the stars was about the same as that of the nebulae, it was hoped that the reduced positions of the latter would be of the same order of accuracy as those of the stars. For the 62 A.G. stars on the seven plates measured, the average difference from the A.G. positions was 1.0″ in either co-ordinate. The settings on the nebulae could be made with greater precision than on the stars, hence these results justify placing the accuracy of the nebular positions at about 2.0″ in either co-ordinate, except for such as were near the edge of the plates.

The positions are given for the epoch of the A.G. catalogues, 1875.0. Two of the N.G.C. nebulae had been measured by Lorenz from photographs made at Heidelberg. A comparison of his measures with the present measures shows the same second of arc in declination and the same tenth of a second of time in right ascension. The agreement is perfect to the last units used in the present paper, but as the nebulae, N.G.C. 7619 and 7626, are situated near the center of the plate, they cannot serve as a test of the accuracy of those near the edge. In several cases comparisons could be made with positions from visual measures, as given in the Strassburg Annals, Vols. III and IV. Here the agreement is not so good.

In one case, on the same night, positions of four objects were measured with reference to a certain star, which was, in turn, tied up to an A.G. star some distance away. The objects are given as N.G.C. 3550, 3552, 3554, and a nova which is designated as K₁₂. The photograph shows N.G.C. 3550 and 3554 properly placed with reference to the star, both in distance and in position-angle; there is nothing at all in the place given for N.G.C. 3552; K₁₂ is properly placed from the star, but is in the N.G.C. position for No. 3552. The position of the reference star is given as about 17″ too small in declination. K₁₂ is clearly N.G.C. 3552, and evidently the fourth object does not exist in the published position. As these objects were all in the same field of view in the telescope, one is at a loss to account for the discrepancy. A list of the comparisons is given in [Table II].

The descriptions indicate form, brightness, and size, and occasionally the location of a neighboring star. Wolf’s classification was used. It is, as he remarks, wholly empirical and probably without physical significance, yet it offers the best available system of filing away data, and will later be of great service when a significant order is established. One class was interpolated between g and h, and was designated g0. Brightness was estimated in the order B, pB, pF, F, vF, eF, eeF, and eeeF. The range is from Herschel’s Class II down to the limit of the plates. For several of the fields diameters were estimated to the nearest 5″. Otherwise the size was given in the order L, pL, pS, cS, S, vS, eS.

The classification given in [Table III] is illustrated in [Plate III], copied from Wolf’s engraving in Band III, No. 5, of the Publicationen des Astrophysikalischen Instituts Königstuhl-Heidelberg. The most striking feature is the great predominance of the classes e and f. These two classes form a continuous sequence from the brightest in the list to the very limits of the plates, where they are but mere faint markings on the films. Eleven are clearly spirals, and the spindles are unexpectedly common. These results are typical.

The frequency of the classes e and f may merely be a way of stating that the scale of the telescope is too small to show the ordinary structure, but it must be remembered that many members of these classes are pretty large and bright and that the gradation in the series is apparently continuous. As far as telescopes of moderate focal length are concerned, the predominant form of nebulae as we know them at present is not the spiral, but is this same “e, f” class, described as round or nearly so, brightening more or less gradually toward the center, and devoid of detail. The brightest of the class are probably Messier 60 and N.G.C. 3379. Their spectrum, as derived from objective-prism plates, is continuous, and is probably of the same type as those of the spirals and the globular clusters. A detailed study on an adequate scale of the brighter members of the class will throw considerable light on the problem of the small nebulae.

TABLE II

Hubbleminus Strassburg
N.G.C. Δα Δδ
 379 0ˢ.0  + 3
 380+0.1+ 3
 382+0.2+ 1
 383+0.10
 384+0.1+ 1
 385+0.1+ 2
 386-0.2- 2
 387+0.2+ 3
3550[2]+0.5+24
3552+0.1+19
3554-0.2+15
3558-0.3- 1
6329-0.3+ 3
6332-0.3+ 6
6336+0.1+ 8
7586+0.2+ 1
7608-0.3+ 6
7611-0.2- 1
7612[3] 0.0+ 2
7617+0.1+ 1
7619[4]+0.1- 1
7623[5] 0.0+ 1
7626[6]-0.2- 2

TABLE III

Distribution of Varieties or Classes of
Nebulae in the Seven Clusters or Fields

Class Field
I II III IV V VI VII Total
a 1 1
c 1 1 13
d 1331 641
e273910941272120284
f3335171981221145
g734 125738
g₀5 8 3117
h2221011422
h₀324 12214
i 123
k1 2 3
n 11
q 1 23
r 2 2
v 1 1
w 14 2 7
irreg 12 3

Messier 60 has a spiral as a very near neighbor—H III 44. The contrast in the two classes is well shown; so also in the case of N.G.C. 3379 mentioned above. Here there is a group of three fairly bright nebulae: N.G.C. 3379, a globular nebula of class e; 3389, an open spiral; and 3384, which might be called a spindle, except that the wings flare out from the nucleus.

The three irregular forms are N.G.C. nebulae and are commented upon in the descriptions accompanying the positions.

Very little can be said concerning the surface-brightness of these objects. It is independent of the distance so long as the angular diameter is sensibly greater than that of a faint star. The photographic plate therefore records the absolute surface-brightness of the nebulae. High luminosity is a comparatively rare attribute and there is some relation between luminosity and absolute size; that is to say, the brighter usually have the greater angular diameter. Since it is hard to conceive of a relation between distance and absolute brightness, the fact that the faint nebulae are usually the smaller can be interpreted only in the light of a relation between luminosity and absolute size.

The clustering of the nebulae here recorded is very pronounced. In the center of Field III there are some 75 nebulae scattered over an area equal to that subtended by the full moon.[7] In order to examine the distribution of the different sizes, diameters were plotted against frequencies. The small scale of the plates renders the number of smallest diameters very uncertain. Nebulae less than 10″ in diameter might easily be mistaken for stars and overlooked, especially if they are at some distance from the center of the field. The curves resemble probability-curves, as one would expect for random distribution in a cluster at a definite distance.

TABLE IV

Distribution According to Size
of the Nebulae in Three Fields

Diameter Field Wolf’s Field
in Perseus
I II III
5 ″  3
10 738 534
1527671252
2025421826
25 61910 6
30 5 9 4 2
35 3 2 4 1
40 4 5 4 2
45 1 3 3
50 1  3
60  3
90  1

Exposures of two hours gave all of the nebulae recorded. Five-hour exposures brightened the images somewhat, but revealed no new ones. The conclusion would seem to be that the limits of the clusters had been reached. This, however, is uncertain, for the longer exposures gave relatively few stars which were not on the plates of shorter exposures. As a matter of fact, the 24-inch reflector at this altitude seems to have a maximum working efficiency at slightly over two hours. Save for very exceptionally clear and steady skies, the longer exposures add much labor for negligibly greater results. The diameters of the faintest stars near the center of the field, with the full aperture, fine sky, and an hour’s exposure, which are of about magnitude 17.5, are about 2.0″. Longer exposures are apparently subject to change of focus, differential refraction, and other disturbances which tend to increase the size of the images unduly, and hence to spread the total light over a larger area. The result is that the value of p in the reciprocity equation Itᵖ = iTᵖ does not remain constant throughout the exposure, but varies, beyond a certain value of T, depending on the adjustments of the telescope, the position of the field, and the condition of the sky. However, the effect should be more noticeable on the stars than on nebulae which present surfaces.

Fig. 1.—Distribution of size in Wolf’s
Nebel Listen Nos. 3 to 14

I have plotted Wolf’s lists of nebulae, Nos. 3-14, in the same manner, converting estimates of size into seconds of arc according to his table. These lists were made from plates taken with the 16-inch (41 cm) Bruce camera, of focal length 203 cm, of the Heidelberg Observatory. The curves ([Fig. 1]) take the same form, save that for most the maximum frequency is for diameters between 20″ and 25″. One of his lists was made from plates taken with the 30-inch reflector at Königstuhl. It is of a field in Perseus, α = 3ᵸ12ᵐ, δ = +41° 6′. Diameters of the 124 Wolf nebulae and five others were measured from plates taken with the Yerkes 24-inch reflector. This plot ([Fig. 2]) gives a maximum for diameters around 15″, and the longer focus of Wolf’s 30-inch apparently does not add to the number of small nebulae distinguishable on the plates made with the shorter telescope.

TABLE V

Wolf’s Nebel Listen Nos. 3-14

List Diameter
4″ 6″ 15″ 25″ 60″ 200″ >200″
3205322291280195366
4 1691531961
5 6991062313
6 1411472221
7 910315635412
8 80372243343
9 4817416019
10 331262
11 1360191
12 14611622710
13 2061263
14 31602964311

The evidence, while far from conclusive, appears to indicate the existence of actual clusters of these small nebulae in the sky. If this is true, it is natural to suppose them physically connected, as is the case in star-clusters. It is not possible to form a conception of this state of affairs until some idea of their distance is acquired. Suppose them to be extra-sidereal and perhaps we see clusters of galaxies; suppose them within our system, their nature becomes a mystery.

Fig. 2.—Distribution of size of nebulae in Wolf’s Perseus
and three Yerkes fields

The question of nebular distances is of first importance, for it is in terms of this quantity that the various dimensions may be expressed. The dark nebulosities, by their very nature, and the great diffuse clouds, some obviously connected with even naked-eye stars, may safely be considered as galactic, and this view is in accord with their low radial velocities with reference to our system.

The planetaries have repeatedly been measured for proper motion, with negligible results. Taking a value of 40 km/sec. for the average radial velocity, and an assumed lower limit of 0.02″ for the average annual proper motion, a tentative lower limit for the average distance of the largest, and hence probably the nearest, is found to be about 2000 light-years. There is thus no reason on this ground for placing them outside our system, especially in view of their decidedly systematic galactic distribution.

Rotation of these nebulae, as detected by the spectroscope, furnishes a means of relating mass and average density with distance. Assume an axis perpendicular to the line of sight, the mass as concentrated in the nucleus and the individual distant particles as rotating in equilibrium; let α be the radius, P the period of rotation, M the mass, and suppose the rotation to be circular. Then

α³/P²M = C, a constant.

Let the unit of distance be the light-year (LY); of time, the year; of mass, that of the sun (S), then C, as computed from the earth-sun system, is about 4 × 10⁻¹⁵.

Let

Then the following relations hold:

The velocity of escape for the nebula is proportional to α/ρ and hence to v. This follows from the assumption that the particles are rotating in equilibrium, and therefore the factor of proportionality is the ratio between parabolic and circular velocity, that is, 1.4, and is independent of the distance. The value of v for those nebulae so far observed is small, ranging from 5 to 10 km. Hence, if the assumptions held only approximately, the velocity of escape would be small and of the same order as that for the earth. Since these nebulae are composed of the lightest gases, it follows that at any save very low temperatures the molecules would escape at a very rapid rate. Certainly the nebulae would dissipate if the temperatures were of the order of that of our own atmosphere.

TABLE VI

dDiameterMass Period Density
10 LY  0.001 LY     1.2S 1.5×10² year1.8×10⁻⁷ρ
10²0.0112. 1.5×10³1.8×10⁻⁹
10³0.1120.  1.5×10⁴1.8×10⁻¹¹
10⁴1.01200.   1.5×10⁵1.8×10⁻¹³

For an assumed typical planetary nebula, 20″ in diameter, rotating with a velocity of 6 km at 10″ from the perpendicular axis, [Table VI] has been constructed from formulae (1)-(3), expressing the order of magnitude of dimensions in terms of distance.

The velocity of escape would be about 8.4 km per second, whatever the distance.

Spectroscopic rotation of spirals furnishes an analogous set of formulae, and here the inclination of the axis may be roughly determined from the ratio of the two diameters of the nebulae. Let β be the semi-minor axis, then the formulae will be:

(4) M = 3.4 × 10⁻⁴ dαv²

(5) ρ = 1.4 × α × 10¹² v² in suns per cu. LY, or
β dα
= 2.8 × α × 10⁻⁶v² in atmospheres
β dα
(6) P = 9.15 dα
v

The spirals form a continuous series from the great nebula of Andromeda to the limit of resolution, the smaller ones being much the more numerous. Considering them to be scattered at random as regards distance and size, some conception may be formed of their dimensions from the data at hand. The average radial velocity of those so far observed is about 400 km, while the proper motion is negligible. Putting the annual proper motion at 0.05″, the lower limit of the average distance is found to be about 7500 light-years. If they are within our sidereal system, then, as they are most numerous in the direction of its minor axis, the dimensions of our system must be much greater than is commonly supposed.

The observations point to very large values for the rotational components of velocity, although the necessarily small scale of the instruments employed in their study renders the measuring difficult. Pease has determined the velocity of rotation for N.G.C. 4594 with some degree of accuracy. At 120″ from the nucleus it amounts to 300 km and varies linearly with the distance outward. V. M. Slipher reports that for the Andromeda nebula the angular rotation is fastest near the nucleus, and that this type of rotation promises to be the more common.

Assume a typical spiral 400″ in diameter, with the ratio of the axes of figure as β/α = 0.1, and with rotation perpendicular to the line of sight at a velocity of, say, 200 km at the periphery. These figures are apparently not very different from the average of the two dozen brighter spirals. [Table VII] gives the dimensions in terms of distance.

The velocity of escape is 280 km/sec.

At the lower limit of average distance of spirals the typical nebulae would be fifteen light-years in diameter, forty-five million times as massive as our sun, and 3 × 10¹³ as dense as our atmosphere. On the other hand, if the typical spiral nebula is placed at a suitable distance, its dimensions assume the same order of magnitude as those of our own stellar system.

The conception of our galaxy set forth by Eddington in his book Stellar Movements and the Structure of the Universe is that the Milky Way forms a ring around a central, slightly flattened cluster. This ring is supposed to rotate in equilibrium so that the stars may remain concentrated in the configurations they now form. Assuming the ratio of the two radii as one to five, and using Eddington’s figures of 2000 parsecs for the distance of the Milky Way, and 10⁹ suns as the mass of the inner cluster, the period and density may be computed and compared with those of the typical nebula placed at a distance such as will make the diameter the same as that of our system. The results are given in [Table VIII].

TABLE VII

d  α  Mass Period Density
10²10⁻¹2.7 × 10⁵9 × 10²1.4 × 10⁹ suns per cu. LY
10⁴10¹2.7 × 10⁷9 × 10⁴1.4 × 10⁵
10⁵10²2.7 × 10⁸9 × 10⁵1.4 × 10³
10⁶10³2.7 × 10⁹9 × 10⁶1.4 × 10¹

TABLE VIII

DistanceRadiusMass Period Density
Nebula 6 × 10⁶ LY 6 × 10³ LY 1.6 × 10¹⁰ S5.4 × 10⁷ year5.6 × 10⁻¹
Galaxy 6 × 10³  10⁹2.5 × 10⁸1.2 × 10⁻²

The velocities of escape would be about 280 km for the nebula and 170 km for the galaxy. Considering the problematic nature of the data, the agreement is such as to lend some color to the hypothesis that the spirals are stellar systems at distances to be measured often in millions of light-years. The computations by O. H. Truman[8] and by R. K. Young and W. E. Harper[9] of the motion of our system with respect to the spirals, based on the radial velocities of the spirals, are another and stronger argument for the hypothesis.

The principal objection lies in their apparently systematic distribution with respect to the Milky Way. The matter is usually stated in the form that “spirals avoid the Milky Way.” There are less than 300 nebulae known to be spiral in form. The greatest of them all is just on the border. It is suggested that the spirals seem to follow the distribution of the small faint nebulae. If this is true, the most that can be definitely stated is that they tend to cluster in certain regions of the sky, in one of which the north pole of the galaxy is located.

As the small nebulae and the spirals inhabit the same regions of the sky, it is probable that the order of distance of the two classes is the same. Classes e, f, may even turn out to be spirals themselves. This, however, is a question for large instruments, and is outside the scope of the present paper.

TABLE IX

Field I of Nebulae

No. (1875.0) Class Description
αδ
10ᴴ 56ᵐ 35.1ˢ+31°36′39″fpF, R, 20″d, *14m 20″p.
239.331 38 24eF, R, 20″d, *12m 20″n.
349.031 22 14 h₀F, mE110°, 60″l.
40 57  5.732 4 12eeF, st. *13m 30″np.
554.532 17 41evF, R, 25″d, *14m 30″sf.
60 58  8.932 8 33evF, R, 25″d, *9 1′nf.
722.331 33 12eeF st.
841.831 45 33fpF, R, S, Δ2 faint*, bM.
942.731 17 58fpF, st. 2*13, 14 1.5′p.
1054.731 16 30gF, cE0°, 30″l.
1158.031 43 5gF, cE130°, 30″l, bM.
1259.732 5 33evF, R, 30″d.
130 59 13.931 56 21fvF, st. *16m40″sf.
1428.231 31 43fvF, st. *15m 1.5′f.
1551.632 33 48gvF, E140°, 45″l.
1658.232 1 58fvF, E60°, 20″l 3f*.
1758.831 41 27feF, eS.
181  0  0.731 54 35eF, st.
193.631 18 39evF, st. d. nuc.
206.431 29 19evF, 1E, 20″l.
218.231 42 16evF, st.
2210.931 43 12hvF, E90°, 1′l.
2315.032 24 1eeF, eS 2*10, 11m1′nf.
2418.931 30 22gvF, cE, S, *15m40″s.
2522.031 1 42evF, st.
2622.132 22 51eeF, R, 30″d, *12m1.5′nf.
2722.931 31 29fFcE60°1′l, *16m40″np.
2825.031 45 17feF, E, eS.
2929.031 54 48 h₀Fv, mE160°, 40″l*13m1′s.
3033.331 54 41eeF, E, eS.
3139.331 25 23hF, mE130°, 1′l.
3243.232 17 18evF, R, 40″d, *14m30″s.
3359.131 35 14geF, eS, st.
341  1  3.532 38 9evF, cE40°*11m1′nf.
3511.331 13 16 h₀vF, 310°, 1′l.
3619.631 47 9fF, S, E60°, *14m1′s.
3724.531 25 17fF, st. *14m1′np.
3827.831 52 56feF, vS, *15m20″p.
3932.731 45 48eeF, st. in line with 2f*.
4050.331 45 57eeF, iR, *14m1′s.
4158.831 25 54epF, R, 25″d. no nuc.
421  2  5.531 34 21evF, st. *10m20″s.
4320.431 29 4evF, R, 45″d. no nuc.
4422.331 18 42fF, st. and sev f*.
4526.432 3 22evF, st. *11m20″s.
4632.032 6 19eeF, iR*14m30″sf.
4739.731 30 21gvF, cE80°, S.
4848.531 47 5fF, st. *15m1′nf.
4949.031 41 39feF, vS, *15m30″f.
5049.831 57 3feF, st. *14m1′np.
511  3  5.331 42 7fvF, st. 2*14m1′f.
528.032 14 51eeF, st.
5326.431 43 18fvF, st. Δ2vF*.
5437.631 30 51feF, st. bet. 2*.
5557.631 55 41feF, st. *12m15″p.
561  4 16.432 2 9fvF, st. bet. 2*.
571  5  1.631 48 22eeF, st. *12m1′s.

Nebulae Previously Known in Field I

N.G.C.
370 0ᴴ 59ᵐ 51.6ˢ +31°44′55″gvF, S, cE20°* 14m30″s.
3741  0 12.532 7 35 g₀pB, mE10°bet. 2*13m.
37614.331 40 43fvF.
37922.531 51 8 g₀pB, cE 0°, 60″×30″.
38024.531 48 53epB, R, 40″d.
38230.931 44 8fpB, R, 20″d.
38332.031 44 38epB, R, 1'd bM.
38432.231 37 26 g₀pB, cE135°, 30″l.
38534.331 39 4fpB, R, 40″d.
38638.331 41 35fpF, st.
38854.231 38 28fF, st.
3921  1 29.132 27 59fpF, R, 30″d bM, *11m1′ sp.
39431.632 28 50fF, st.
39736.432 26 32fvF, st.
3981  2 0.031 50 50fF, st.
3995.231 58 1 g₀F E50° 40″l.
40320.032 5 9kpB, mE90°, 60″×20″.
3871  0 40.131 43 23fvF, eS, st.
I.C.
16180  59 3.431 44 31 g₀pF, cE, 150° 25″l, bM.
16191  0 28.632 23 57fpF, st. bet. 2*11, 12m.

N.G.C. 379 and 372 are probably the same object, with α of 370, and δ the mean of the two N.G.C. positions. There is no other object in the immediate vicinity.

400
401Faint stars in these positions; no nebulae near.
402
390, Faint star, 16m. in this position. No trace of a nebula.

TABLE X

Field II of Nebulae

No. (1875.0) Class Description
αδ
11ᴴ 39ᵐ 32.1ˢ+31°52′58″fF, S.
241.732 46 3eeF, pS.
343.432 4 25deeF, S.
446.731 29 2fvF, S.
550.432 7 35eeF, pS.
655.631 24 29eeF, eS.
759.032 10 21fvF, vS.
81  40 27.531 24 17 h₀eeF, S.
948.331 30 29eeeF, vS.
1050.431 37 46eeeF, vS.
111  41  5.631 44 9eeF, S.
128.931 55 48evF, vS.
139.431 59 34fvF, pS.
1420.231 53 23eeF, vS.
1532.632 20 2fvF, S.
1637.131 55 40eeF, vS.
1747.632 16 38feF, vS.
1851.531 55 50eeeF, S.
191  42  0.531 56 38eeeeF S.
200.832 28 25fvF, S.
2115.832 11 28geF, 30″l.
2216.431 52 43eeeF, eS.
2321.131 55 41eeeF, eS.
2423.531 57 24fF, S.
2531.532 0 9gvF, S.
2637.832 42 19eeeF, S.
2741.432 34 24eeeF, S.
2843.531 29 20feeF, eS.
2944.432 10 20gpF, 30″l.
3050.432 19 55fvF, S.
3150.932 47 16eeF, S.
3251.231 24 50eeeF, eS.
3358.032 0 4eeeF, eS.
341  43  2.732 52 33feF, S.
355.331 51 52eeeeF, eS.
367.031 48 17fpF, S.
377.532 32 4weF,40″d.
387.731 56 36fvF, vS.
398.631 54 15eeeF, eS.
409.131 53 1feF, eS.
419.332 6 11eeeF, vS.
4212.031 52 35feeF, eS.
4312.232 22 58feF, S.
4413.131 51 39heeF, S.
4513.231 59 34eeeF, vS.
4613.432 2 32eeeF, eS.
4717.931 57 14fvF, vS.
4819.632 25 39fvF, vS.
4920.731 50 3heeeF, S.
5022.632 36 9eeeF, vS.
5122.631 49 17eeeF, S.
5223.831 47 57eeeF, eS.
5329.531 52 29fvF, S.
5430.532 27 43fpF, pS.
5537.631 53 20eeF, eS.
5639.031 56 43feF, eS.
5739.232 28 21fvF, S.
5839.332 13 46eeeF, vS.
5939.931 53 5eeeF, eS.
6043.431 53 22eeeF, eS.
6146.831 52 18feeF, eS.
6248.932 16 44feF, vS.
6356.432 18 51feF, vS.
6458.832 0 10eeeeF, vS.
651  44  0.732 27 29eeeF, vS.
660.832 9 58eeeF, eS.
671.932 0 17fvF, vS.
684.032 29 4eeeeF, S.
698.432 24 6eeF, vS.
7011.332 24 47fF, pS.
7114.932 12 48eeeF, vS.
7220.732 25 54fvF, S.
7324.632 4 37feeF, eS.
7424.632 9 38feF, eS.
7534.932 5 34feeF, eS.
7643.532 27 34eeeF, pS.
7747.531 33 13feF, eS.
7852.732 24 24eeF, vS.
7956.032 14 24eeeeF, vS.
8057.432 4 2eeeF, S.
811  46  28.631 22 2feeF, eS.

Nebulae Previously Known in Field II

I.C.
1733 1ᴴ 43ᵐ 25.6ˢ +31°56′40″fvF, eS.
173535.531 55 32cvF nuc., iR eeF neb.,60″d.
1 42  20.431 57 55q270″×30″. Found visually by
Barnard. Not catalogued.

TABLE XI

Field III of Nebulae

No. (1875.0) Class Description
αδ
110ᴴ 59ᵐ 59.4ˢ+29°22′40″eeeF, 25″d.
211  0  2.129 23 37e35″d.
314.729 46 56eeF, 30″d.
422.029 15 59evF, 20″d.
523.529 5 59feF, 30″d.
625.829 27 21fvF, 30″d.
742.528 39 11eef, 15″d.
856.129 20 10deeF, 30″d.
911  1  1.028 51 3eeF, 20″d.
105.229 10 31eeF, 25″d.
1119.529 22 46eeeF, 15″d.
1222.428 39 12weF, 30″d, open spiral.
1323.929 12 21evF, 25″d.
1424.829 19 4 h₀eeF, E165°, 35″×10″
1527.329 32 18deeF, 15″d.
1628.429 5 32evF, 30″d.
1728.429 12 58deF, 20″d.
1829.229 31 11eeF, 15″d.
1932.329 6 30 h₀eeF, 3160°.
2036.629 17 52deeF, 20″ d, some structure.
2138.629 17 13feF, 20″d.
2253.429 19 33eeF, E60°, 30″×15″.
2356.629 54 3deF, 30″d.
2411  2  2.229 36 46deeF, 15″d.
255.729 50 3weeF, 45″d, open spiral.
2617.228 57 27eeF, 20″d.
2724.028 45 9geF, E160°, 40″×20″.
2830.329 33 6eeeF, 10″d.
2936.031 14 51evF, 25″d.
3036.429 43 59eeeF, 10″d.
3137.929 24 6deeF, 20″d.
3238.729 26 44eeeF, 15″d.
3338.829 44 12eeeF, 15″d.
3439.829 20 17eeeF, 15″d.
3540.329 54 55eeeF, 15″d.
3641.229 27 20weeF, nuc. 10″d, ring, 30″d.
3741.428 55 57eeF, 15″d.
3842.829 23 45dvF, 15″d.
3944.929 23 51eeF, 10″d.
4047.329 18 17kvF, E150°, 45″×15″.
4148.029 43 23 g₀eeF, E40°, 20″×10″.
4248.329 21 21eeF, 15″d.
4354.029 21 19 g₀eF, 30″×10″.
4455.729 35 33eF, 20″d.
4556.628 55 41eeF, 35″d.
4658.229 13 50geeF, E50°, 30″×10″.
4711  3  4.129 10 39aeeF, 15″d, structure.
484.329 38 56 g₀eeF, E80°, 20″×10″.
4921.629 1 14deF, 15″d.
5022.629 18 15deeF, 20″d.
5123.429 17 21evF, 20″d.
5223.629 39 35eeF, 20″d.
5324.329 40 11eeeF, 20″d.
5427.929 9 3feF, 15″d.
5528.630 7 9feeF, 30″d.
5628.729 0 47deeF, 15″d.
5730.128 49 9eeeF, 20″d.
5831.429 43 22eF, 15″d.
5931.529 28 6eeF, 15″d.
6032.529 14 55eeF, 15″d.
6133.428 57 49eeF, 15″d.
6235.829 18 9fvF, 20″d.
6338.529 23 55eeeF, 10″d.
6439.629 23 9a?eF, 35″×25″. E35°,
a miniature Dumb-bell.
6539.729 25 39eeeeF, 10″d.
6640.129 25 48eeeeF, 10″d.
6740.329 23 57eeeF, 10″d.
6841.329 21 55 g₀eF, E110°, 30″*10″.
6941.929 22 21eeF, 20″d.
7043.730 7 14eeeF, 20″d.
7144.729 22 38eeeF, 20″d.
7246.229 28 7feF, 20″d.
7346.429 30 25deF, 15″d.
7449.829 22 46deeF, 20″d.
7551.6 29 22 53eeeF, 10″d.
7652.429 22 34eeeF, 15″d.
7752.929 43 59eeeF, 20″d.
7853.628 59 39eF, 35″d.
7954.529 26 1deeF, 20″d.
8054.729 23 5eeeF, 20″d.
8155.129 21 50eeF, 15″d.
8256.729 26 22eeeF, 15″d, E50°.
8356.929 34 40eeF, 15″d.
8457.529 16 59e eF, double nebula,
 nuc. 4″ apart.
8557.629 8 7eeF, 30″d.
8657.729 27 19 h₀eeF, E140°, 15″×5″.
8711  4  0.829 17 51eeeF, 10″d.
881.028 56 28eeeF, 20″d.
891.429 22 15eeF, 15″d.
901.429 39 5eeeF, 15″d.
911.828 57 21evF, 30″d.
923.429 27 26eeF, 10″d.
933.729 29 10eeeF, 20″d.
942.729 20 17evF, 20″d.
953.829 2 9eeeF, iR.
964.429 27 33eeF, 10″d.
975.729 28 23eeeF, 15″d, faint extensions.
985.830 14 51eeF, st.
996.929 22 50eeF, 15″d.
1007.628 56 51 h₀eeF, E25°, 30″×10″.
1019.429 14 23e eeF, 15″d.
1029.929 29 29deeF, 10″d.
10310.028 53 55 e?eeF, faint extensions
   60″×40″?
10410.130 0 27deF, 30″d.
10510.629 8 48 g₀eF, E145°, spiral, 40″×20″.
10612.829 28 58heeeF, 20″×10″.
10713.429 23 15eeeF, 15″d.
10813.529 21 19 g₀eeF, E125°, 25″×15″.
10913.829 47 14deeF, 20″d.
11014.230 0 57keF, E40°, 34″×20″.
11114.429 25 24eeF, 15″d.
11215.629 29 36deeeF, 10″d.
11318.628 55 56eeeF, 15″d.
11420.228 53 6feeF, 20″d.
11522.828 54 6eeeF, 20″d.
11627.929 23 25feF, 35″d.
11727.929 26 40 e?eeF, 60″×40″, spiral?
11828.429 22 31eeF, 45″d.
11928.629 21 58deeF, 15″d.
12028.629 25 18eeeF, 10″d.
12130.229 37 42eeeF, 15″d.
12232.029 25 37deeF, 15″d.
12334.429 21 33eeF, 20″d.
12434.929 42 1eeF, 20″d.
12535.529 12 10eeeF, 10″d.
12636.029 21 0eeF, E60°, 20″×15″.
12737.029 27 7deeeF, 15″d.
12838.528 56 22eeF, st.
12939.429 24 33fvF, 25″d.
13040.229 12 57eeeF, 15″d.
13141.829 27 40geeF, E95°, 20″ × 10″.
13246.829 19 18geeF, 30″ × 15″.
13347.929 31 9deeF, 10″d.
13449.329 26 1feF, 15″d.
13549.929 29 19eeeF, 10″d.
13649.929 14 45eeeF, 15″d.
13750.529 25 27eeF, 30″d.
13851.529 22 55eeF, 10″d.
13952.729 23 21eeF, 10″d.
14054.129 29 57eeeF, 15″d.
14111  5  3.028 56 43evF, 30″d.
1424.729 16 36eeF, 15″d.
1436.829 15 53eeeF, 20″d.
1447.628 53 4deeF, 15″d.
14511.629 38 5eeeF, 20″d.
14612.329 10 1deF, 20″d.
14713.530 9 30deF, 20″d.
14814.430 6 28eeF, 20″d.
14914.729 20 38weF, 25″d, spiral.
15015.629 8 19deeeF, 15″d.
15117.129 29 16eeF, 20″d.
15219.429 10 52gvF, E40°, 50″ × 20″.
15334.329 25 10deeF, 30″d.
15435.529 15 0eeeF, 30″d.
15543.628 57 24eeF, 40″d.
15649.228 42 34feF, st.
15751.328 43 12eeeF, 30″d.
15859.628 57 38eeeF, 30″d.
15911  6  6.928 44 55deeF, 30″d.
1609.729 29 30deeeF, 20″d.
16110.628 40 46eeF, 30″d.
16211.829 4 8fvF, st.
16312.830 11 16eeeF, 10″d.
16417.529 25 47eeF, 15″d.
16523.228 43 55feeF, 20″d.
16624.928 39 40eeeF, 30″d.
16727.828 41 26eeeF, 30″d.
16829.028 56 22eeeF, 20″d.
16940.929 20 27deeeF, 20″d.
17037.728 33 23deeeF, 15″d.
17142.729 37 59eeeF, 20″d.
17244.229 5 13deeeF, 15″d.
17350.629 18 31eeeF, 20″d.
174 11 7  11.128 32 54deeF, 20″d.
17514.930 14 45eeF, 20″d.
17619.229 18 25heeeF, 30″×10″.
17727.129 6 26feF, 20″d.
17832.928 51 30eeF, 30″d.

Nebulae Previously Known in Field III

N.G.C.
3527 11ᴴ 0ᵐ 31.4ˢ+29°12′ 6″fvF, 35″d.
3536 11 2   5.329 9 5eF, 40″d.
353922.929 20 56 g₀F, E5°, 60″×20″.
3550 11 3   53.529 26 47 pB, eccentric nuc., 35″ × 25″.
3552 11 3   52.229 24 38eF, 20″d.
3554 11 3   57.729 22 15evF, 25″d.
3558 11 4   10.929 13 17fvF, 15″d, with what appears
to be a faint ring 50″ in d.
3561 11 4   28.429 22 31eeF, 45″d.

TABLE XII

Field IV of Nebulae [10]

No. (1875.0) Class Description
αδ
113ᴴ 32ᵐ 33.0ˢ+56°18′28″eF, eS, *15m10″n.
213 33  0.456 49 46eeeF, pS.
316.055 49 23eeF, S.
441.757 9 1eeF, S.
555.656 5 4evF, eS.
656.956 6 15eeF, S.
713 34  9.155 50 46eeeF, eS.
811.356 32 8feF, eS.
925.956 29 14feF, eS.
1056.656 42 36eeF, vS.
1157.757 0 46feF, vS.
1213 35  4.956 45 21heeF, S.
1349.856 13 38hvF, S.
1452.056 52 58eeF, cS.
1553.156 3 25eeeF, eS.
1613 36 20.155 50 25eeeF, eS.
1729.156 51 25eeF, S.
1833.155 49 59eeeF, eS.
1933.256 43 54feF, eS.
2038.655 46 18eeeF, eS.
2139.056 18 33hF, 30″l.
2241.056 12 2deeF, S.
2343.756 42 11eeeF, S, *15m10″s.
2446.256 48 12eeF, cL.
2549.756 41 26feF, S.
2653.656 48 57eeeF, eS.
2755.756 27 19heeF, S.
2856.156 40 17eeeF, S.
2913 37  7.256 4 29fvF, S.
3011.655 46 36eeeF, eS.
3119.056 24 54eeF, S.
3220.256 26 51feeF, vS.
3335.557 7 6eeF, cS.
3446.056 5 6feeF, S.
3554.056 10 12heeF, S.
3658.256 9 31heeF, S.
3713 38  4.356 7 32feeF, S.
389.856 7 11feeF, eS.
3915.856 13 9eeeF, eS.
4017.156 13 57feF, vS.
4129.156 16 49eeF, S.
4235.256 15 5heF, vS.
4335.456 13 55heeF, eS.
4437.356 14 41feF, vS.
4547.356 41 19eeeF, cS.
4652.855 35 23eeeF, eS.
4756.456 12 58feF, vS.
4813 39  6.956 15 45eeeF, eS.
497.956 16 31heF, vS.
508.156 5 45fvF, S.
519.256 11 45eeeF, eS.
529.455 56 14eeeF, eS.
5313.356 16 32feeF, vS.
5417.656 10 33eeeF, eS.
5519.856 10 50eeeF, eS.
5623.056 11 40eeF, eS.
5725.156 16 43eeeF, eS.
5830.356 26 49feF, eS.
5931.656 20 3eeeF, S.
6045.156 29 5feF, vS.
6145.756 34 46eeeF, S.
6254.256 15 18eeeF, eS.
6313 40  3.256 37 22eeeF, eS.
645.956 30 56eeeF, eS.
655.956 30 29heeF, 30″l.
6627.256 6 27eeeF, vS.
6713 41 27.256 20 38eeF, 60″d.
6838.855 47 15eeF, eS.
6947.455 44 54feF, vS.
7013 42 40.256 15 54eeeF, S.

Nebulae Previously Known in Field IV

N.G.C.
5278 13ᴴ 36ᵐ 59.45ˢ+56°18′3.8″
527937   3.72 56 18 14.5
529440 39.7  55 55 2 feF, S, *15m1′np.
N.G.C. 5278 and 5279 form a double nebula, somewhat
similar to Messier 51. 5278 is the nucleus and 5279 is at the
tail of the arm. The spiral apparently has but one branch.

TABLE XIII

Field V of Nebulae

No. (1875.0) Class Description
αδ
114ᴴ 53ᵐ 52.5ˢ+23°10′16″eeF, S, R.
254.523 57 39evF, R, 20″d, *18m40″nf.
314 54 56.223 53 37g eF, S, m3. *16m1′.np.
458.123 16 56evF, pS, iR.
514 55  6.7 23 24 32feF, S.
616.224 5 30fF, S, *17m30″n.
731.424 6 9wF, 30″d. Spiral.
835.923 58 27gvF, mE, 40″l, bet. 2*.
937.324 12 53eeF, eS.
10 14 56  13.723 52 21gF, E, spiral?
1117.724 2 30gF, E180°.
1226.324 0 51 h₀vF, S, iR.
1327.024 9 28gF, vS, E.
1428.623 23 8evF, S, R, 15″d, no nuc.
1530.023 54 53evF, vS, R.
1632.624 2 47feF, vS.
1746.424 3 54eeF, S, iR.
1847.824 36 4evF, S, iR.
1951.223 40 4evF, vS.
2056.023 51 10eeF, vS, R.
2158.723 49 12feF, vS, R.
2258.723 50 14eeF, eS, R.
2359.023 51 41geF, S, IE.
2414 57  4.323 51 51eeF, S.
254.323 52 8feF, E.
266.124 5 56fF, bet. 2*14, 15m.
278.423 47 22geF, cS, iR.
288.924 16 59eeF, S.
2910.323 50 31eeF, S.
3011.323 46 44eeF, S.
3111.823 49 57eeF, S.
3213.623 53 2heF, S.
3318.823 44 22geF, S.
3424.123 42 42eeF, cS, iR.
3524.324 4 40eeF, S, iR.
3626.823 45 2eeF, vS ,iR.
3735.924 6 37eeF, S.
3841.724 35 7feF, S.
3943.023 24 38evF, R, 30″d, no nuc.
4051.724 0 48geF, vS, Δ with 2*14 and 16m.
4114 58  0.623 18 4cvF, 25″d, spiral?
426.823 11 21gF, cL, mE180°, 80″×15″.
4318.523 26 30geF, S, 20″d.
4419.823 21 55fvF, R? 60″d.
4525.923 25 35eeF, S, R, 20″d.
4648.423 40 57geF, cS, mE.
4754.723 54 12eF, mE 180°.
48 14 59  56.824 10 32evF, S, iR, bM.
4915  0  7.223 52 11eeF, S, iR.

Nebulae Previously Known in Field V

N.G.C.
5829 14ᴴ 57ᵐ 9.6ˢ+23°49′29″wopen 2br, spiral.
I.C.
452614 57  5.923 50 31epB, R, 18″d.
4532  59 21.723 44 43epB, S, E.
I.C. 4526 is connected with N.G.C. 5829. The two form
a double nebula fashioned as a miniature of Messier 51.

TABLE XIV

Field VI of Nebulae

No. (1875.0) Class Description
αδ
117ᴴ 8ᵐ 16.7ˢ+44° 5′35″fvF, vS, *13m, 1′f.
229.943 26 6fvF, vS, st.
335.243 23 8geF, E 60°, *13m40″sp.
452.642 57 44fF, S, st.
517  9  2.644 18 28evF, vS, *16m, 40″s.
614.244 16 11eeF, S, *16m, 40″f.
717.543 50 51fvF, sharp nuc. 30″d.
833.243 2 38eF, pS, *17m, 1′n.
935.144 2 54eF, vS, *15m, 30″f.
1041.143 38 39 g₀pF, S, mE, 60°*14m, 30″p.
1153.843 52 2evF, vS, *17m, 40″n.
1217 10  3.444 12 35feF, eS, *16m, 30″n.
1323.343 49 32evF, vS, bet. 2 vf*.
1425.543 43 7fvF, vS.
1529.143 44 48evF, vS.
1633.044 4 43gvF, S.
1737.744 5 32eeF, vS.
1839.043 42 38gvF, eS, *16m, 40″sf.
1940.244 5 20heF, vS.
2046.743 51 14fvF, vS, *16m, 40″sf.
2152.843 33 9fvF, S, *16m, 40″sf.
2255.744 4 8gF, cE 70°, *14m, 40″n.
2317 11  16.343 10 57fvF, S.
2425.943 25 48fpF, S, *16m, 40″f.
2533.943 47 21gvF, vs, cE 160°, *15m, 40″np.
2636.743 42 51 h₀vF, S, cE 120°, faint nuc.
2743.043 53 35 g₀pF, S, cE 20°, *14m, 1.5′np.
2845.743 55 42fF, vS, *15m, 40″nf.
2948.643 58 50evF, S *13m, 1.5′n.
3057.144 8 50eeF, es.
3157.844 8 6eeF, S.
3257.943 44 57evF, vS, *15m, 30″f.
3317 12  13.344 2 16eF, eS, *12m, 1′n.
3426.244 12 21eF, eS.
3537.244 12 12eF, eS, Δ with 2*12m.
3638.443 28 52fpF, vS, *1.5′s.
3740.943 54 40 h₀eF, cE 150°, no nuc.
3844.943 45 22evF, vS, Δ with 2*16m.
3950.643 39 48fvF, eS, Δ with 2 f*.
4051.043 48 16evF, vS, *16m, 40″nf.
4117  13  4.943 36 37eeF, vS, *15m, 20″s.
4227.243 40 39evF, vS.
4339.243 44 19evF, S.

Nebulae Previously Known in Field VI

N.G.C.
6323 17ᴴ 9ᵐ 30.6ˢ+43°55′42″ipF, mE, ns, 40″l.
632917 10  27.343 49 40fpF, pL, slE.
633217 11  15.243 48 5 g₀pF, pL, E 45°.
633617 12  30.043 55 35vpF, open spiral, 45″d.
I.C.
464517 10  53.0+43°14′40″evF, pS, Δ with 2 faint*.
N.G.C. 6327 is on the plate but was not measured.

TABLE XV

Field VII of Nebulae

No. (1875.0) Class Description
αδ
1 23ᴴ 10ᵐ 25.7ˢ+8°13′28″fst. 14m.
223  11  19.47 34 13eF, S, *17m30″s.
339.37 45 26dvF, R, no nuc., 16m45″ np.
447.37 3 55feF, S, R, no nuc.
523  12  23.17 18 20cvF, st. nuc. with ring 45″d.
642.26 45 7deF, S, R, no nuc.
751.17 2 10qF, 1bM, mE100°, 100, ×20″.
823  13  17.27 24 12 h₀vF, S, 1E50°*14m30″p.
919.47 34 51qF, sharp nuc., mE70°, 80″×20″.
1029.97 31 15fF, S, E150°.
1133.68 6 51deF, pS, R.
1235.47 52 39gpF, bM, mE150° 40″l.
1341.67 32 2geF, vS.
1441.67 18 13evF, vS, Δ2 faint *.
1549.17 2 16evF, S, Δ2 faint *.
1652.77 14 52hF, sharp nuc. vmE20°90″×15″.
1756.67 19 16eeF, pL, no nuc.
1823  14  2.46 51 8fF, S, R, *14m90″n.
192.97 38 55fF, S, R, bM.
2018.47 42 40fF, S, bM.
2124.47 45 35eeF, vS, *16m30″s.
2231.37 27 10eeF, vS, bet. 2*.
2334.97 31 47evF, S.
2436.07 30 3fvF, vS.
2536.27 42 4fvF, vS.
2637.57 41 4fvF, vS.
2741.87 29 40hFN, mE160°, 80″×20″.
2841.87 13 46fpF, vS, bM, Δ with 2 faint *.
2942.47 44 32eeF, eS,*14m1′sp.
3046.17 32 31npFN, eccentric, mE90°.
3146.27 29 21ipF, vS, R.
3252.86 40 49fst. 14m.
3354.97 32 39eF, S, 1E.
3456.27 10 7ivF, S, E, *14m30″sf.
3556.96 47 41evF, 1E, *15m30″s.
3658.57 33 24evF, vS, *17m30″f.
3723  15  5.97 51 23evF, R, lvM,40″d, *12.1′n.
3811.17 20 15fvF, S, E, *14m30″sp.
3916.97 34 23evF, vS, *15m1′np.
4020.47 38 15dvF, vS.
4121.88 18 24hvF, E, *9m, superimposed.
4226.08 23 37dpF, pL, R, lbM.
4328.77 29 43fF, S.
4453.08 15 14eeF, pL, iR, no nuc.
4556.37 46 32eeF, S, *16m40″p.
4623  16  24.27 40 32evF, E, *17m40″f.
4738.88 18 39 h₀eF, no nuc., vmE175°, 150″×30″.
4842.57 33 39gvF, S, E.
4943.47 36 39eeF, pS, no nuc. Trapz. of 4*.
5055.37 51 8evF, S, *12m1′s.
5123  17  14.27 37 37eeF, vS, *12m2′nf.
5234.96 55 40deF, pS, no nuc.

Nebulae Previously Known in Field VII

N.G.C.
7604 23ᴴ 11ᵐ 31.7ˢ+6°44′48″fF, R, bM.
760532.66 41 46fF, R, bM, *15m70″p.
758636.17 54 7fpF, st.
760823 12  55.57 40 6hpF, sharp nuc., mE20°,100″×25″. 
761123 13  16.67 22 45 g₀pB, gbM, mE140°, 80″×30″.
761224.77 53 38gpB, mbM, cE170°, 80″×40″.
761535.07 42 58fF, E130°, * 14m involved.
761749.27 28 54epF, pS, mbM, vlE20°.
761954.87 31 19fB, R, 90″d.
762123 14   5.07 40 56gpF, pS, mbM, E0°.
762310.47 42 45fpB, R, mbM, 60″d.
762622.87 31 56fB, R, bM, 90″d, *14m60″p.
763123 15   7.17 31 59gpB, mbM, mE80°, 110′×40″.
763422.38 12 14fF, R, *10m20″p.
2d I.C.
530923 12  51.87 25 32gpF, mbM, E0°, 50″×30″,
 *14m on south edge.

Yerkes Observatory
May, 1917

Plate III

Wolf’s Classes of Nebulae

(Copied from the Königstuhl [Heidelberg] Publications)

Plate IV

Enlarged Negative of Field III

Center at Center at α=11ᴴ 4ᵐ, δ=+29°30′

For identification of lettered stars [see footnote 7 page 5].

Footnotes:

[1] A dissertation submitted to the Faculty of the Ogden Graduate School of Science of the University of Chicago in candidacy for the degree of Doctor of Philosophy.

[2] Nucleus is eccentric and undefined on the photograph, hence the photographic position is probably in error by several seconds of arc.

[3] Mean of the positions given in Vols. III and IV. N.G.C. 7621 is 5ˢ.4 preceding, and 1′ 49″ south of 7623. There is a double star in the position published in the Strassburg Annals.

[4] Mean of the positions given in Vols. III and IV. N.G.C. 7621 is 5ˢ.4 preceding, and 1′ 49″ south of 7623. There is a double star in the position published in the Strassburg Annals.

[5] Mean of the positions given in Vols. III and IV. N.G.C. 7621 is 5ˢ.4 preceding, and 1′ 49″ south of 7623. There is a double star in the position published in the Strassburg Annals.

[6] Mean of the positions given in Vols. III and IV. N.G.C. 7621 is 5ˢ.4 preceding, and 1′ 49″ south of 7623. There is a double star in the position published in the Strassburg Annals.

[7] [See Plate IV], enlarged from negative R 3352, taken with 120ᵐ exposure on February 26, 1916. The numbers were marked on only those nebulae which promised to be readily visible on the engraving, and which were separated enough to give room for inscribing the number. The B.D. stars are designated by letters, for which the key is as follows.

[8] Popular Astronomy, 24, 111, 1916.

[9] Journal of the R.A.S., Canada, 10, 134, 1916.

[10] Field IV covers the position of a group of 18 small nebulae announced by E. E. Barnard in Astronomische Nachrichten, 125, 369, 1890. The positions there given were rough estimations from the stars B.D. +56°.1679 and B.D. +56°.1682. On the photographs, the nebulae in this region are so small and so crowded that I have been able to identify only three individuals of the group. Barnard’s Nos. 4, 7, and 18 are very probably my Nos. 41, 43, and 62.

Transcriber’s Notes:

Ancient words were not corrected.

The illustrations and tables have been moved so that they do not break up paragraphs and so that they are next to the text they illustrate.

Typographical and punctuation errors have been silently corrected.