Resources
Journal papers
Agrawal, D. C. (1984), "The hydrobalance," Am. J. Phys. 52, 184.
Butler, W. A. (1981), "Reverse Cartesian diver "trick"," AJP 49, 92.
Denardo, B., B. Barber, C. Folley, and W. Wright (1989), "Nonfrictional hysteresis in a rotating U-tube," AJP 57, 1126-1130.
Denardo, B., W. Wright, B. Barber, and C. Folley (1990), "A rotating U-tube experiment," AJP 58, 631-635.
Duffy, B. R. (1993), "A bifurcation problem in hydrostatics," AJP 61, 264-269.
Fletcher, R. I. (1972), "The apparent field of gravity in a rotating fluid system," AJP 40, 959-965.
Fox, J. N., J. K. Eddy, and N. W. Gaggini (1988), "A real-time demonstration of the depth dependence of the pressure of a liquid," AJP 56, 620-621.
Garmon, L. B. (1982), "More on Archimedes's principle," AJP 50, 968.
Geballe, R. (1991), "Note on "A thermometer based on Archimede's principle,", by George D. Nickas [Am. J. Phys. 57, 845-846 (1989)]," AJP 59, 90.
Gilson, J. E. and O. Boedtker (1969), "A damped harmonic motion experiment for use in undergraduate general physics laboratories," AJP 37, 1157-1158.
Guemez, J., C. Fiolhais, and M. Fiolhais (2002), "The Cartesian diver and the fold catastrophe," Am. J. Phys. 70 (7), 710-14.
Michaelis, M. M. and T. Woodward (1991), "An inverted liquid demonstration," AJP 59, 816-821.
Nickas, G. D. (1989), "A thermometer based on Archimedes' principle," AJP 57, 845-6.
Orwig, L. P. (1980), "Cartesian diver "tricks"," AJP 48, 320.
Peterson, W. D. (1980), "Falling bubbles demonstrate acceleration of gravity," AJP 48, 888-889.
Sheng-ping He, Se-yuen Mak, and Eqing Zhu (1993), "Depth dependent Cartesian divers," Am. J. Phys. 61 (10), 938-40.
Spagna, G. (1981), "Buoyant force analog: a demonstration for the vertical stage overhead projector," AJP 49, 507-508.
Turner, R. C. (1983), "Toys in physics teaching: Cartesian diver," AJP 51, 475-476.
Vandyck, M. A. (1989), "An alternative type of water barometer," AJP 57, 467-469.
Victoria, L., C. Molina, A. Arenas, and J. A. Ibanez (1996), "Use of pressure transducers in laboratory experiments. I. Experimental verification of the fundamental equation of fluid statics. Application to density measurements," Am. J. Phys. (USA) 64 (3), 317-21.
Wild, R. L. (1981), "Ultimate Cartesian diver set," AJP 49, 1185.
Willis, J. and D. F. Kirwan (1974), "Easily-performed experiment illustrating the effect of the buoyant force of air on laboratory weighings," AJP 42, 910-911.
Zimmermann, W., Jr. (1980), "Buoyancy of air," AJP 48, 319-320.
Dias, C. J. and L. N. Goncalves (2014), "The concept of negative mass and its application to Helium-balloon-type dynamics," Am. J. Phys. 82 (10), 997 - 1000.
Snoeijer, J. H. and K. Van der Weele (2014), "Physics of the granite sphere fountain," Am. J. Phys. 82 (11), 1029 - 39.
Theodorakis, S. and C. Aristidou (2012), "The paradox of the floating candle that continues to burn," Am. J. Phys. 80 (8), 657 - 63.
Bourrier, P., E. Guyon, and J. P. Jorre (1984), "L'effet'pop off': ou differents regimes d'accleration d'une balle legere dans l'eau," EJP 5, 225-231.
Chialvo, D. R., A. Vinet, D. Michaels, and J. Jalife (1991), "Bifurcations in a simple hydraulic oscillator: the 'Tantalus cup'," EJP 12, 297-302.
Hughes, S. and D. Pearce (2015), "Investigating sea level rise due to global warming in the teaching laboratory using Archimedes' principle," Eur. J. Phys. (UK) 36, 065033 (9 pp.) .Kliava, J. and J. Megel (2010), "Non-uniqueness of the point of application of the buoyancy force," Eur. J. Phys. (UK) 31 (4), 741 - 62.
Pintao, C. A. F. and M. P. de Souza Filho (2007), "g - acceleration of gravity: its measurement from the shape of water by using a computerized rotational system," Eur. J. Phys. (UK) 28 (5), 915 - 21.
Akridge, R. (1993), "Water baramoter," PT 31, 110-111.
Benenson, R. E. (1975), "Direct-reading Archimedes' principle apparatus," Phys. Teach. 13 (6), 366.
Burgstahler, A. W., T. Wandless, and C. E. Bricker (1987), "The relative lifting power of hydrogen and helium: a gas buoyancy demonstration experiment," Phys. Teach. 25 (7), 434-5.
Edge, R. D. (1988), "A siphon demonstration," Phys. Teach. 26 (2), 114.
Greenslade, T. B., Jr. (1993), "The buoyancy balance: nineteenth century textbook illustrations - LIV," PT 31, 160-161.
Guerra-Vela, C. and D. J. Bord (1988), "Composite samples for an Archimedes' principle experiment," Phys. Teach. 26 (2), 95-6.
Hageseth, G. T. (1987), "The liquid pendulum," Phys. Teach. 25 (7), 427.
Prigo, R. B. (1988), "Liquid beans [buoyancy]," Phys. Teach. 26 (2), 101.
Shult, D. (1981), "Simple pressure demonstrations," Phys. Teach. 19 (5), 330-3.
Atkin, J. K. (1988), "The great water-jet scandal (L)," PE 23, 137-138.
Hellemans, J., M. De Kelver, and L. Sterckx (1992), "Demonstrating Archimedes' principle for air," PE 27, 38-39.
Koenings, F. F. R. (1984), "Determination of liquid densities and volumes of solid bodies by the reaction force on a vessel," PE 19, 83.
Moore, G. S. M. (1988), "Amplifying sound with water jets," PE 23, 329.
Rickus, A. R. (1988), "Demonstrating pressure at depths," PE 23, 328-329.
Shadmi, Y. (1981), "Archimedes' Law as a problem in statics," PE 16, 270-273.
Tamuli, A. K. (1988), "Liquid flow from orifices," PE 23, 190-191.
Putranta, H., Y. Wiyatmo, X. X. Supahar, and W. S. B. Dwandaru (2020), "A simple liquid density measuring instrument based on Hooke's law and hydrostatic pressure," Phys. Educ. 55 (2), 025010 (9 pp.) .
Ivanov, D. and S. Nikolov (2020), "Once more about the Cartesian diver," Phys. Educ. 55 (2), 025006 (9 pp.) .
Ramos, L. M., F. B. Rodrigues, C. R. N. Reis, D. F. Bozano, D. D. Reis, and A. M. B. Goncalves (2020), "An experiment to observe Stevin's law with an Arduino," Phys. Educ. 55 (3), 033004 (4 pp.) .