AUTHOR INDEX 577 



L 



Lavoisier, P. A.: Composition of air and theory of oxidation, 12; "fixed air" a compound 

 of carbon and oxygen, 13. 



Lemberg, R.: Investigation of algal chromoproteids, 417, 418, 476^79. 



Lewis, Ch. M. See Emerson, R. 



Liebich, H. See Noack, K. 



Liebig, J. v.: Plant acids as intermediates in photosynthesis, 35, 51; total yield of photo- 

 synthesis on earth, 5. 



Livingston, R.: Reversible bleaching of chlorophyll, 486-493. See also Franck, J. 



and Franck, J.: Photosynthesis under high carbon dioxide pressures, 331. 



Lowenberg, K. .See Fischer, F. G. 



Lubimenko, V. N.: Mechanism of chlorophyll formation in plants, 404-411, 431; ombro- 

 philic and heliophilic plants, 533, 534; preparation of colloidal chlorophyll ex- 

 tracts from plants, 384-388. 



and Shcheglova, O. A.: Effect of wounding on photos3Tithesis, 343. 



Lwoff, A.: Organic nutrition of green flagellates, 261-262. 



M 



McAlister, E. D.: Pickup of carbon dioxide in dark after a period of photosynthesis, 

 206-208; aftereffects of photosynthesis on respiration, 565, 566. 



and Myers, J. Inhibition of photosynthesis by excess oxygen, 328, 531. 



MacKinney, G.: Carotene assay in leaves, 415, 471. -See also Joslyn, M. A. 

 Manning, W. M., and Strain, H. H.: Chlorophyll d in red algae, 407. See also Button, 



H. J.; Strain, H. H. 

 Maquenne, L., and coworkers: Photosynthetic quotient, 32-33. 

 Martius, C. See Krebs, H. A. 



Mayer, Robert: Conversion of light into chemical energy by plants, 24-26. 

 Maz4, P.: Volatile components of leaves, 251, 254. 



Menke, W.: Analysis of chloroplast ash, 376-377; association of carotenoids with pro- 

 teins in the cell, 393, 476; chlorophyll content of chloroplastic matter, 390, 411- 

 412; chloroplasts as thixotropic bodies, 358; laminary structure and birefringence 

 of chloroplasts, 362-363, 365-367; separation and analysis of chloroplastic matter, 

 368-376, 451. 

 Meyer, A.: Acidification cycle of succulents, 264-265; assimilatory secretion, 43, 254; 



size of chloroplasts, 357; total volume of chloroplasts in a leaf, 371. 

 Meyer, K.: Chlorophyll-sensitized photoxidations in vitro, 508, 509, 511. 

 Meyerhof, O.: Metabolism of nitrifying bacteria, 119, 225. 

 Mobius, M.: Size of chloroplasts, 357. 

 Mohl, H. v.: Starch grains in chloroplasts, 42. 



Molisch, H.: Metabolism of purple bacteria, 100-102; oxygen liberation by dried leaf 

 powders, 62-63; phase test of chlorophyll, 459; reduction of silver nitrate in 

 chloroplasts, 254, 270-271; phycobilins as chromoproteids, 417, 476. 

 Mommaerts, W. E. H. M.: Separation and analysis of chloroplastic matter, 361, 369, 370, 



380, 390-391. 

 Montfort, C: Light curves and hght injury of deep water algae, 533, 536, 537. 



and Fockler, H.: Light-stimulated respiration, 567. 



Moore, B. : Iron in chloroplasts, 376. 



Mothes, K., and Sagromsky, H.: Chromatic adaptation of diatoms, 425. 

 Moyer, L. S., and Fishman, M. M.: Electrophoresis of chloroplast proteins, 374, 386, 387. 

 Myers, J., and Burr, G. O.: Aftereffects of photoxidation in algae, 566; photosynthesis 

 and photoxidation in very intense light, 533-536. See also McAlister, E. 



