Quantitative Determination of Chlorophyll PDF

Summary

This article describes various methods for determining the quantity of chlorophyll in plants. It details different methodologies, including spectrophotometric and colorimetric approaches, and highlights the historical context and key contributions of prominent scientists in the field. The methods described in the document are useful for researchers in plant physiology.

Full Transcript

THE QUANTITATIVE DETERMINATION OF CHLOROPHYLL'
F. M. SCHERTZ

(WITH TWO FIGURES)

Introduction
Up to the present time many methods have been used to determine the
amount of chlorophyll present in a plant or in a given solution. Not one
of the methods has been generally adopted by those who desire to estimate
chlorophyll quantitatively. Each worker apparently has adopted a method
of his own. It is clearly evident then that attempts at standardization
should be made. The methods as given here are an attempt to place the
estimation of chlorophyll on a sound basis, so that all workers may be able
to compare their data. The results reported are not to be considered as
final but only a report of progress in the development of better methods of
quantitative research in this field.

Methods which have been used to estimate chlorophyll
No attempt will be made to refer to all of the methods which have been
used for this kind of work but rather a brief description will be given of
a few of the more important contributions.
Perhaps the first attempt at measuring the concentration of chlorophyll
was made by MONTEVERDE (7) when he photographed the spectra of several
different concentrations of the alcoholic extracts of green leaves. His pur-
pose was not to discover a method for quantitative work but rather to
ascertain the nature of chlorophyll spectroscopically.
In 1910 extinction coefficient values were used by MALARSKI and
¶IARCHLEWSKI (6) to measure the concentration of colored solutions.
Chlorophyll was converted into chlorophyllan (pheophytin) and the ab-
sorption of this solution was measured by means of the Kdnig-Martens
spectrophotometer.
JACOBSON and ATARCIILEWSKI (3) later used the photographic method
in their study of the chlorophyllans from various leaves. By this method
a direct comparison of the amount of chlorophyllan present could be made,
for several photographs could be taken on the same plate. The method was
used to show that chlorophyll consisted of two components, allo- and neo-
chlorophyll. The procedure was then modified by JACOBSON (2) in order
to determine the amount of the two chlorophyllans present in 1 gram or
less of leaf.
'Soil-Fertility Investigations, U. S. Department of Agriculture, Washington, D. C.
323
324 PLANT PHYSIOLOGY
Later MONTEVERDE and LUBIMENKO (8) used a spectrocolorimeter,
which was specially constructed for their use by Leitz, in determining the
amount of chlorophyll, carotin and xanthophyll present in the leaves of dif-
ferent plants.
WEIGERT (10) recognized the practical importance of knowledge regard-
ing the spectrol)hotometric curves of the four chloroplast pigments. His
figures show the extinction curves that are formed by solutions of the leaf
pigments in pure acetone. He also explains how quantitative results may
be obtained from such curves. No practical application, however, has ever
been made of his results.
Considerable work has been done by HENRICI (1) on the chlorophyll
content of alpine and lowland plants. Her methods were based upon those
used by WILLSTXTTER. The chlorophyll standard for the colorimetric de-
terminations was an alcoholic solution of crude chlorophyll made from fresh
nettle leaves. No attempt was made to place the amount of chlorophyll
present in the leaves upon an absolute basis.
Total chlorophyll and total carotinoids were estimated in the red algae
by WURMSER and DUCLAUX (12). They made no attempt to separate the
two chlorophylls or to separate carotin from xantlophyll. The chloro-
phylls as such were determined spectrophotometrically by measuring the
absorption at wave-length 670 mp, and the carotinoids were determined by
using wave-length 450 mp. The amount of pigment present in the red
varieties was expressed as 100 while the determinations for the green varie-
ties were based upon the red and the results are given in per cent. The
separation of the pigment was a modification of the procedure as given by
WILLSTXTTER and STOLL.
MAIWALD (5), by using methods based upon WILLSTXTTER and STOLL 'S
procedure, has determined the amount of chlorophyll present in potato
leaves. A mixture of pure chlorophyll (a + f3) (obtained from WILL-
STATTER) was used as a standard and comparisons were made by using a
Duboseq colorimeter.
By means of the spectrocolorimeter, LUBIMENKO (4) has quantitatively
investigated the amount of chlorophyll present in marine algae. He used
crystallized chlorophyll as a basis for his comparisons. The instrument is
represented as being quite accurate, though no figures are given to show its
degree of accuracy.
It will be observed that most of the methods used are only a modifica-
tion of the procedure described by WILLSTXTTER and STOLL (11). In their
methods WILLSTXTTER and STOLL separated chlorophyll into its two com-
ponents, a and f3, by converting them into their respective derivatives,
phytochlorin e and phytorhodin g. The other workers have all determined
only the total amount of chlorophyll which was present in the material.
 SCHERTZ-QUANTITATIVE DETERMINATION OF CHLOROPHYLL 325

Procedure
In this paper only the data for estimating total chlorophyll will
be given, because the estimation of chlorophyll a and chlorophyll 3 by the
methods of WILLST.XTTER and STOLL have proved quite unsatisfactory. The
manner of preparing a chlorophyll extract from fresh green leaves for use
in such quantitative work has been presented (9). Pure chlorophyll
(a +,) has been used as a basis for the curves obtained by means of the
Duboseq colorimeter and also for those obtained by means of the Hilger
wave-length spectrometer. In either case 0.05072 gm. of pure chlorophyll
(a + L3) was dissolved in 50 cc. of ether. The chlorophyll in the ether was
then saponified by shaking the solution for 15 min. or more with 10 cc. ofl
cold concentrated methyl alcoholic potash. The ether was removed by
evaporation, using reduced pressure. Distilled water was added to make
a volume of 250 cc. Dilutions as required were made from this solution of
potassium chlorophyllin (a + A). and the pure chlorophyll was measured as
potassium chlorophyllin.
The colorimetric method
The solution as described above was diluted and readings were made,
using a combination of 3, 4, and 5 blue plus 10 and 20 yellow Lovibond
slides as a standard. The chlorophyllin solution was matched against the
Lovibond slides by comparing the depth of tint and not by attempting to
match exactly the color of the slides, which would be impossible.
The combination of Lovibond slides used here does not exactly match
the color of the chlorophyll solution. The writer used this combination to
aid in determining the purity of his samples, for some fixed standard was
absolutely necessary since no known pure chlorophyll was at hand. No
combination of Lovibond slides will match all of the samples of chlorophyll,
for the proportions of a and ,3 vary. The tint of the chlorophyll solutions
will vary accordingly. In quantitative work on fresh green leaves the color
variations in the green pigments being tested will be even greater than in
the case of pure chlorophyll. The ideal method, of course, is to use pure
chlorophyll as a standard; but this will not be found to be practicable be-
cause pure chlorophyll is not available commercially, and moreover it is not
advisable for each worker to prepare his own pure product. A company
in America is now attempting to prepare pure chlorophyll and it is hoped
that chlorophyll of known purity soon may be purchasable.
The results of colorimetric readings for six different samples are given
in table I. In the ease of samples 3, 4, 5, and 6, more than one weighing
2 0.0507 gm. was used, for when 0.0500 gm. of chlorophyll
(a + ,) was dried at
1000 C. it lost an average of 0.0007 gm.
326 PLANT PHYSIOLOGY

TABLE I
COLORIMETRIC READINGS OF AQUEOUS SOLUTIONS OF POTASSIUM CHLOROPHYLLIN (Ca + 13)
MEASURED AGAINST A COMBINATION OF LOVIBOND SLIDES

GRAMS PER LITER
SAMPLE NO.
0.20 0.15 0.10 0.05
mm. mm. mm. mm.
1 8.7 12.3 17.7 33.5a
2 8.5 11.6 16.1 35.0
3 9.1 10.6 17.4 33.5
3 8.5...... 16.3 30.2
4 8.4....... 16.8 32.1
4 9.0 12.2 17.8 31.9
5 7.5...... 15.0 29.8
5 7.6 9.5 14.2 29.3
6 9.5.... 17.8 32.8
6 7.7 9.6 15.7 28.6
6 9.6 12.8 19.6 34.9
Average 8.55 11.22 16.76 31.96
a Each number is an average of 3 readings on the calorimeter measured against the
following combination of Lovibond slides, 3, 4 and 5 blue plus 10 and 20 yellow. Mea-
surements were made on different days as well as different times of the day so as to
get an average result.

was made and another set of readings was taken on a different day. This
was done to obtain as good an average as possible, for it is almost impos-
sible to duplicate exactly any set of readings on a given sample. Using the
average of the figures for each concentration in table I, a curve has been

,c U 9,
O 2
ITI -._.p o3
c_
4.c ____ :~ ~ ~ ~ ~ ~ ~ ~ ~ ~-1
z,;.. '

1.20 o.a5O
Swramis of poto msium chlorophyllin0 er lite r_*.

FIG. 1. Colorimetric determination of chlorophyll.

drawn, fig. 1, with grams of chlorophyll (a + f3) per liter represented on the
x-axis and depth of solution in millimeters as measured on a colorimeter
 SCHERTZ-QUANTITATIVE DETERMINATION OF CHLOROPHYLL 327
represented on the y-axis. The curve may be used by those desiring to
know approximately the amount of chlorophyll present in a given solution.
However, it is advisable to use pure chlorophyll as a standard if it
is obtainable.
In order to know the accuracy of the method the maximum error has
been calculated for each of the four concentrations. The high, the low and
the average reading together with their respective values in terms of chloro-
phyll are given in table II. Calculating, using the values for grams of

TABLE II
DATA, OBTAINED FROM TABLE I, USED IN CALCULATING THE PROBABLE ERROR OF A SINGLE
DETERMINATION

CONCENTRATION IN GRAMS PER LITER
0.20 0.15 0.10 0.05
mm. mm. mm. mm.
Highest reading 9.6 12.8 19.6 35.0
Lowest reading.. 7.5 9.5 14.2 28.6
Average reading 8.55 11.22 16.7 31.9
From the curve in fig. 1, these readings are interpreted in terms of grams of
chlorophyll per liter respectively as follows:

0.173 0.133 0.083 0.047
0.235 0.175 0.120 0.054
0.200 0.150 0.100 0.050

chlorophyll per liter in table II, it is found that the maximum difference in
the readings for concentration 0.20 is 0.235-0.173 = 0.062, and 0.062 = 31
per cent.; for 0.15 it is 28 per cent., for 0.10, 37 per cent., and for 0.05, 14
per cent.
From table I, the probable error of a single observation has been calcu-
lated. The calculations are rather lengthy and need not be given here,
since the method of calculating is shown later in connection with the spec-
trometric method. For readings made with the concentrations 0.20, 0.15,
0.10 and 0.05, the respective probable errors in per cent. are ± 7.4 -+- 7.3
+ 7.0 and ± 3.3.
The spectrometric method
The same solutions and concentrations used in the colorimetric method
were used here also. The slit opening was set at 5, and a 200-watt electric
light was used as the source of illumination. The widths of the absorption
band (I) are given in table III. Only one set of readings was taken in
328 PLANT PHYSIOLOGY

TABLE III
POSITION OF THE EDGES OF THE ABSORPTION BAND (I) OF PURE POTASSIU.Ml CHLOROPPIYLLIN
(a + 3) (THICKNESS OF SOLUTION = 10 MM.)
I~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
CONCENTRATION (GRAMS PER LITER)
SAMPLE
0.20 0.15 0.10 0.05
668-605* 660-615 656-619 647-624
1 667-607 659-615 654-619 646-624
666-607 659-615 655-619 646-624
666-609 663-611 656-617 646-625
2 666-609 662-612 656-617 647-623
665-609 661-612 656-618 648-624
665-607 656-614 650-621
3 666-604 656-616 649-621
667-605 655-616 650-622
665-607 656-617 651-624
4 664-608 654-619 648-621
663-608 654-617 649-624
671-605 664-613 656-617 648-624
5 670-605 662-612 656-618 646-624
669-607 662-612 657-618 646-624
670-604 664-611 657-617 648-623
6 670-604 662-611 657-617 647-623
668-606 662-612 657-616 648-624
Average 667-606.4 661.7-612.6 655.7-617.3 647.7-623.3
*
All readings are reported in mut.

the case of each sample of chlorophyll (a + f). From the average results
in table III the graph in fig. 2 has been constructed. From this graph
readings from a solution which contains an unknown amount of potassium
chlorophyllin, may be interpreted in grams of chlorophyll per liter.
In order to find the maximum error in the spectrometric determinations
in table III, the widths of the absorption band have been interpreted in
grams of chlorophyll per liter and are recorded in table IV. From table
IV the maximum difference in the determinations may be calculated as
follows: For concentration 0.20 grams per liter it is 0.2340-0.182 = 0.0520
and =0050- 25 per cent.; for concentration 0.15 it is found to be 18.9 per
0.2055
cent., for concentration 0.10, 19.4 per cent., for 0.05, 53.2 per cent.
 SCHERTZ-QUANTITATIVE DETERMINATION OF CHLOROPHYLL 329
, ft

O ,
's 't 6Y9
+3 -
-C.

Qo -
630 E
Uv).1.a_

S% S0 620___ _ --

t~ q)
,61_
00 0.15' 0.10
aO5
Grarns of potassium chlorophqap'ha Pee llter*-.
FIG. 2. Spectrometric determination of chlorophyll.

TABLE IV
DATA, OBTAINED FROM TABLE III, WHICH WAS USED IN CALCULATING THE ERROR OF A
SINGLE DETERMINATION

SAMPLE mR (X) mRt (X) mj (X) mR (X)
1 604 = 0.200 444 = 0.133 36 = 0.098 221 = 0.040
2 564 = 0.183 514 _ 0.159 36* = 0.107 23 = 0.042
3 604 = 0.200 41 = 0.119 284 = 0.065
4 564 = 0.182 37 = 0.102 26* = 0.057
5 644 = 0.233 504 = 0.158 384 = 0.107 22' = 0.041
6 644 = 0.234 514 = 0.162 404 = 0.116 244 = 0.048
Lowest reading 0.1820 0.1330 0.0980 0.0400
Highest reading 0.9340 0.1620 0.1190 0.0650
Average reading 0.2055 0.1530 0.1081 0.0480
(x) = grams of chlorophyll per liter.
m= width of absorption band in mg.
330 PLANT PHYSIOLOGY

The probable error of a single determination has also been calculated
from table III. The calculations will not be given but the results may be
obtained by using the equation:
r =0.6745 IyV2
N-1
in which r is the probable error, 0.6745 is a constant, N is the number of
determinations and V is the variation of each reading from the average
reading.
The probable error for a concentration of 0.20 gm. per liter is ± 7.5 per
cent., for 0.15 it is + 5.8 per cent., for 0.10 it is ± 5.0 per cent., and for
0.05 it is ± 14.0 per cent.
It will perhaps be best to give an example to explain how the spectro-
metric graph is used. Using a given solution of potassium chlorophyllin
the absorption band is found to extend from 620-652 mpi; then the width of
the band is 32 mp. In fig. 2 a place is found where the distance between
the lines is 32 mp. By inspection of the figure it is seen that this corre-
sponds to 0.08 gm. of chlorophyll. So the solution, the absorption bands of
which have been measured in the spectrometer, contains 0.08 gm. of chloro-
phyll per liter.
In table V a comparison is made of the results obtained by using the
TABLE V
COMPARISON OF THE ACCURACY OF THE COLORIMETER AND THE SPECTROMETER

CONCENTRATION OF POTASSIUM CHLOROPHYLLIN IN GRAMS
ERRORS OF DETER- PER LITER
MINATION
0.20 0.15 0.10 0.05
Colorimeter results
Maximum error...... 31 per cent. 28 per cent. 37 per cent. 14 per cent.
Probable error.±... + 7.4 + 7.3 ± 7.0 ± 3.3
Spectrometer results
Maximum error...... 24.0 per cent. 18.9 per cent. 19.4 per cent. 53.2 per cent.
Probable error......... 7.5 ± 5.8 ± 5.0 ± 14.0

colorimeter with the results obtained on the spectrometer. It is seen that
the results on the colorimeter are best when the concentration is about 0.05
gm. per liter while the results on the spectrometer are best with a concentra-
tion of 0.10 to 0.15 gm. per liter.
In the absence of better methods for the quantitative determination of
chlorophyll either method should give results which are quite satisfactory.
Methods have been used here in which it is not necessary to use pure chloro-
phyll as a standard because of the difficulty of obtaining this pigment pure.
 SCHERTZ-QUANTITATIVE DETERMINATION OF CHLOROPHYLL 331

The preparation of pure chlorophyll would be quite a task for many workers
who are interested in knowing something regarding the pigment content of
plants which are being investigated. Some of the difficulties in preparing
pure chlorophyll will be taken up at a later time. The methods as outlined
should at least aid in any preliminary investigation of chlorophyll. Of
course, the ideal standard is pure chlorophyll; but until the pure pigment is
obtainable commercially workers will have to be contented with other
methods.
Stability of potassium chlorophyllin solutions
In connection with methods for estimating chlorophyll, investigators
should know something regarding the stability of chlorophyllin solutions.
Solutions of chlorophyll which had been saponified with methyl alcoholic
potash were kept for ten days and the resulting decomposition is shown in
table VI. The combination of Lovibond slides described under the colori-
metric method was used here to obtain the colorimetric readings.
TABLE VI
KEEPING QUALITIES OF POTASSIUM CHLOROPHYLLIN, STORED AT ROOM TEMPERATURE
IN DARKNESS, COLORIMETRIC METHOD

DATE NUMBER SAMPLE
OFDAYE lio~n:1
2 3 4

mm. mm. mm. mm.
January 17 0 24.9 27.5 25.6 24.8
January 20 3 26.3 32.9 31.2 29.3
January 23 6 42.3 47.4 38.2 32.2
January 27........ |10 49.0 61.0 49.0 41.0

TABLE VII
KEEPING QUALITIES OF POTASSIUM CHLOROPHYLLIN STORED IN THE
ICE BOX IN DARKNESS

DATE NUMBER OF DAYS READING IN MM.
June 10. 0 10.3
June 12................. 2 10.3
June 26............. 16 11.0
July 22.......... 42 11.4
August 14.................. 65 11.7

However, a solution which had been kept in the ice box showed very
little decomposition (table VII) even when stored for 65 days. The safer
33 2 PLANT PHYSIOLOGY

practice would be to estimate the chlorophyll within a day or two after it
had been prepared from the leaf material, meanwhile keeping the solutions
stored in the ice box.
Potassium chlorophvllin is one of the most easily prepared of the chloro-
phyll products and is much more stable than any of the chlorophyll solu-
tions, consequently it has been used as a basis for the determination of
chlorophyll. Also, in separating chlorophyll from the yellow accompanying
pigments it is necessary to saponify the chlorophyll to ehllorophyllin. If
any other derivative of chlorophyll were used in the estimation of chloro-
phyll our methods of separating the pigments would have to be modified
considerably. Consequently, the methods as offered in this paper have
been based upon the use of potassium ehlorophyllin.

Discussion
This paper is concerned primarily with the methods now available for
determining the amount of chlorophyll. It seems desirable in conclusion
to say something about the future possibilities of determining chlorophyll.
The methods as given here are not very accurate, being only good enough
for preliminary work. Many problems concerning the estimation of
chlorophyll demand an accuracy as great as has been obtained in deter-
mining carotin and xanthophyll. Data showing the complete spectro-
photometric curves for earotin and xanthophyll have been obtained at the
Bureau of Standards and it is hoped that this data will soon be published.
Before much more progress can be made with chlorophyll it will be
necessary to have a complete spectrophotometric curve of chlorophyll
a and chlorophyll j3. This can be accomplished only after much more is
known about chlorophyll than we know at the present time. Practically
nothing is known at l)resent about how to prepare a solution of chlorophyll
so that its spectral transmission properties can be measured before the
chlorophyll is altered by the solvent or by the light used in the study.
Before satisfactory solutions of chlorophyll a or j3 can be prepared,
pigments of undoubted purity must be obtained. The preparation of such
pure pigments demands most painstaking chemical technique. Thus far
only one chemist has succeeded in preparing solutions of the permitted
food dyes pure enough for satisfactory spectrophotometric analysis. It
is not to be expected, then, that the preparation of pure chlorophyll
a and f3 will be easily accomplished. Satisfactory spectrophotometric
curves for the chlorophyll pigments will be obtained only with great effort
and at considerable cost.
Difficult as the problem is, it can be solved if only the determination
to solve it is present, but the solution will not be an easy one. While such
 SCHERTZ-QUA NTITATIVE DETERMINATION OF CHLOROPHYLL 333

work has its practical value, the first consideration should be to gain more
information about a substance so prominent everywhere in nature. Meth-
ods for the absolutely accurate quantitative determination of the green
plant pigments will make it possible to know much more about the role of
chlorophyll in everyday life. It is hoped that many plant physiologists
will become interested in the nature and properties of this pigment which
is known to play so important a role in plant life. It may be possible that
a study of the effect of different wave-lengths of light upon the molecule of
chlorophyll in pure solution will reveal much concerning the real nature
of light effects upon plant growth and the nature of chlorophyll itself.
The work will be most difficult, but since methods are being developed for
investigations of this kind, sustained efforts should be made toward a de-
tailed knowledge of the role of chlorophyll. The possibility for new dis-
coveries is great.
This paper is only a report of progress in the efforts made to estimate
chlorophyll with accuracy, efforts which have not yet met with entire suc-
cess. More means should be available for purely scientific studies of the
nature and functions of the a and 3 chlorophylls. At present we will have
to be contented to work with the tools we have until more and better in-
vestigators become seriously interested in chlorophyll problems. Before
such serious interest may be developed in the field of chlorophyll chemistry,
it may be necessary to develop new points of view of the possible functions
of chlorophyll, and the broad significance it may have in the whole realm
of plant and animal life.
Summary
1. A brief description is given of the more important methods which
have been used to determine chlorophyll quantitatively.
2. A method for determining chlorophyll colorimetrically is described
and a graph is given from which quantitative data may be computed.
3. A spectrometric method of determining chlorophyll is described and
a graph has been constructed from which chlorophyll may be quantitatively
determined.
4. The colorimetric method is more accurate at concentrations of about
0.05 gm. per liter while the spectrometric method is more accurate at con-
centrations of 0.10 to 0.15 gm. per liter.
5. Chlorophyll solutions which have been saponified with methyl alco-
holic potash should not be allowed to stand for any length of time before
their pigment content is estimated, since the saponified chlorophyll is rather
-unstable.
334 PLANT PHYSIOLOGY

6. The spectrophotometric method offers great promise of being a very
accurate method for determining chlorophyll, though the data for the
method are yet to be obtained.
U. S. DEPARTMENT OF AGRICULTURE,
WASHINGTON, D. C.

LITERATURE CITED
1. HIENRICI, MARGUERITE. Chlorophyllgehalt und Kohlensiiure-Assimi-
lation bei Alpen- und Ebenen-Pflanzen. Verhandl. naturf. Ges.
Basel. 30: 43-136. 1919.
2. JACOBSON, C. A. A delicate method for determining minute quanti-
ties of chlorophyll. Jour. Amer. Chem. Soc. 34: 1266-1268.
1912.
3. , and MARCHLEWSKI, L. On the duality of chlorophyll
and the variable ratio of the two constituents. Amer. Chem. Jour.
47: 221-231. 1912.
4. LUBIMENKO, V. Sur la quantite de la chlorophylle chez les algues
marines. Compt. Rendu Acad. Sci. Paris 179: 1073-1076. 1924.
5. MAIWALD, K. Wirkung hoher Nihrstoffgaben auf den Assimilations-
apparat. Angew. Bot. 5: 33-74. 1923.
6. MALARSKI, H., and MARCHLEWSKI, L. Studien in der Chlorophyll-
gruppe. VI. Bestimmung des Chlorophylls in Pflanzenteilen.
Biochem. Zeitschr. 24: 319-322. 1910.
7. MONTEVERDE, N. A. Das Absorptionsspectrum des Chlorophylls.
Acta Horti Petropolitani 13: 123-178. 1893.
8. , and LUBIMENKO, V. Formation of chlorophyll in
plants. III. Application of the spectrocolorimetric method of
quantitative analysis to the study of accumulation of chlorophyll,
xanthophyll, and carotin in the plant. Bull. Acad. Sci. St.
Petersburg 7: 1007-1028. 1913.
9. SCHERTZ, F. M. The extraction and separation of chlorophyll (a + ),
carotin and xanthophyll in fresh green leaves, preliminary to their
quantitative determination. Plant Physiol. 3: 211-216. 1928.
10. WEIGERT, FRITZ. tVber Absorptionsspektren und fiber eine einfache
Methode zu ihrer quantitativen Bestimmung. Ber. deutsch.
chem. Ges. 49: 1496-1532. 1916.
11. WILLSTXTTER, RICHARD, and STOLL, ARTHUR. Untersuchungen fiber
Chlorophyll. Berlin. 1913.
12. WURMSER, RENE, and DUCLAUX, J. Sur la photosynthese chez les
algues Floridees. Compt. Rendu Acad. Sei. Paris 171: 1231-
1233. 1921.