Publications

Citation statistics

[1] Jordan K. Pommerenck, Tanner T. Simpson, Michael A. Perlin, and David Roundy. Stochastic approximation monte carlo with a dynamic update factor. Phys. Rev. E, 101:013301, Jan 2020. [ DOI | http ]
[2] Jordan K. Pommerenck and David Roundy. Flat-histogram method comparison on the two-dimensional ising model. Phys. Rev. E, 102:033306, Sep 2020. [ DOI | http ]
[3] Tevian Dray, Elizabeth Gire, Mary Bridget Kustusch, Corinne A Manogue, and David Roundy. Interpreting derivatives. PRIMUS, pages 1--21, 2019.
[4] Jonathan Carney, David Roundy, and Cory M Simon. Statistical thermodynamic model of gas adsorption in a metal-organic framework harboring a rotaxane molecular shuttle. submitted to Langmuir, 2019.
[5] Jeff B Schulte, Rene W Zeto, and David Roundy. Theoretical prediction of disrupted min oscillation in flattened escherichia coli. PloS one, 10(10):e0139813, 2015.
[6] David Roundy, Eric Weber, Tevian Dray, Rabindra R. Bajracharya, Allison Dorko, Emily M. Smith, and Corinne A. Manogue. Experts' understanding of partial derivatives using the partial derivative machine. Phys. Rev. ST Phys. Educ. Res., 11:020126, Sep 2015. [ DOI | http ]
[7] David Roundy, Tevian Dray, Corinne A. Manogue, Joseph F. Wagner, and Eric Weber. An extended theoretical framework for the concept of derivative. In Proceedings of the 2015 Research in Undergraduate Math Education Conference, 2015.
[8] David Roundy, Eric J Krebs, Jeff B Schulte, and Greg S Mulder. Look ma, no templates! problem-based learning of computational physics for novice programmers. In Frontiers in Education Conference (FIE), 2015. 32614 2015. IEEE, pages 1--5. IEEE, 2015.
[9] David Roundy, Mary Bridget Kustusch, and Corinne Manogue. Name the experiment! interpreting thermodynamic derivatives as thought experiments. American Journal of Physics, 82(1):39--46, 2014. [ .pdf ]
[10] Mary Bridget Kustusch, David Roundy, Tevian Dray, and Corinne A Manogue. Partial derivative games in thermodynamics: A cognitive task analysis. Physical Review Special Topics-Physics Education Research, 10(1):010101, 2014. [ .pdf ]
[11] Eric J. Krebs, Jeff B. Schulte, and D. Roundy. Improved association in a classical density functional theory for water. J. Chem. Phys., 140(12):124507, 2014. [ arXiv | .pdf ]
[12] David Roundy, Eric Weber, Grant Sherer, and Corinne A. Manogue. Experts' understanding of partial derivatives using the partial derivative machine. In 2014 PERC Proceedings, 2014.
[13] Paho Lurie-Gregg, Jeff B Schulte, and David Roundy. Approach to approximating the pair distribution function of inhomogeneous hard-sphere fluids. Physical Review E, 90(4):042130, 2014.
[14] Mary Bridget Kustusch, David Roundy, Tevian Dray, and Corinne Manogue. An expert path through a thermo maze. In AIP Conference Proceedings, volume 1513, page 234, 2013. [ .pdf ]
[15] D. Roundy and M. Rogers. Exploring the thermodynamics of a rubber band. American Journal of Physics, 81:20, 2013. [ .pdf ]
[16] Jessica Hughes, Eric J Krebs, and David Roundy. A classical density-functional theory for describing water interfaces. The Journal of chemical physics, 138(2):024509--024509, 2013. [ .pdf ]
[17] David Roundy, , Ayush Gupta, Joseph F. Wagner, Tevian Dray, Mary Bridget Kustusch, Emily van Zee, and Corinne A. Manogue. From fear to fun in thermodynamics. In 2013 PERC Proceedings, pages 42--45, 2013. [ .pdf ]
[18] Corinne A. Manogue, Elizabeth Gire, and David Roundy. Tangible metaphors. In 2013 PERC Proceedings, pages 27--30, 2013. [ http ]
[19] Grant Sherer, Mary Bridget Kustusch, Corinne A. Manogue, and David Roundy. The partial derivative machine. In 2013 PERC Proceedings, pages 341--344, 2013. [ .pdf ]
[20] Jeff B. Schulte, Patrick A. Kreitzberg, Chris V. Haglund, and David Roundy. Using fundamental measure theory to treat the correlation function of the inhomogeneous hard-sphere fluid. Phys. Rev. E, 86:061201, 2012. [ DOI | .pdf ]
[21] J.R. Thompson, C.A. Manogue, D.J. Roundy, D.B. Mountcastle, N.S. Rebello, P.V. Engelhardt, and C. Singh. Representations of partial derivatives in thermodynamics. In AIP Conference Proceedings-American Institute of Physics, volume 1413, page 85, 2012.
[22] L. Prisbrey, D. Roundy, K. Blank, L.S. Fifield, and E.D. Minot. Electrical characteristics of carbon nanotube devices prepared with single oxidative point defects. The Journal of Physical Chemistry C, 2012. [ .pdf ]
[23] Ardavan F. Oskooi, David Roundy, Mihai Ibanescu, Peter Bermel, J.D. Joannopoulos, and Steven G. Johnson. Meep: A flexible free-software package for electromagnetic simulations by the fdtd method. Computer Physics Communications, 181(3):687 -- 702, 2010. [ DOI ]
[24] Daniel A. Freedman, D. Roundy, and T. A. Arias. Elastic effects of vacancies in strontium titanate: Short- and long-range strain fields, elastic dipole tensors, and chemical strain. Phys. Rev. B, 80(6):064108, 2009. [ DOI ]
[25] S. A. Petrosyan, Jean-Francois Briere, David Roundy, and T. A. Arias. Joint density-functional theory for electronic structure of solvated systems. Phys. Rev. B, 75(20):205105, 2007. [ http ]
[26] A. Farjadpour, D. Roundy, Alejandro Rodriguez, M. Ibanescu, Peter Bermel, J. D. Joannopoulos, Steven G. Johnson, and G. W. Burr. Improving accuracy by subpixel smoothing in the finite-difference time domain. Optics Letters, 31(20):2972--2974, 2006. [ DOI ]
[27] D. Roundy. Darcs: distributed version management in haskell. In Proceedings of the 2005 ACM SIGPLAN workshop on Haskell, pages 1--4. ACM, 2005.
[28] M. Ibanescu, S. G. Johnson, D. Roundy, Y. Fink, and J. D. Joannopoulos. Microcavity confinement based on an anomalous zero group-velocity waveguide mode. Optics Letters, 30(5):552--554, 2005.
[29] H. Üstünel, D. Roundy, and T. A. Arias. Ab initio mechanical response: internal friction and structure of divacancies in silicon. Phys. Rev. Lett., 94:025503, 2005.
[30] H. Üstünel, D. Roundy, and T. A. Arias. Modelling a suspended nanotube oscillator. Nano Letters, 5(3):523--526, 2005.
[31] Seung-Hoon Jhi, D. Roundy, S. G. Louie, and M. L. Cohen. Formation and electronic properties of double-walled boron nitride nanotubes. Solid State Commun., 134:397--402, 2005.
[32] M. Ibanescu, S. G. Johnson, D. Roundy, C. Luo, Y. Fink, and J. D. Joannopoulos. Anomalous dispersion relations by symmetry breaking in axially uniform waveguides. Phys. Rev. Lett., 92(6):063903, 2004.
[33] R. E. Kraig, D. Roundy, and M. L. Cohen. A study of the mechanical and structural properties of polonium. Solid State Commun., 129(6):411--413, 2004.
[34] Hong Sun, F. J. Ribeiro, Je-Luen Li, D. Roundy, M. L. Cohen, and S. G. Louie. Ab initio pseudopotential studies of equilibrium lattice structures and phonon modes of bulk bc3. Phys. Rev. B, 69:024110, 2004.
[35] D. Roundy, E. Lidoriki, and J. D. Joannopoulos. Polarization-selective waveguide bends in a photonic crystal with layered square symmetry. J. Appl. Phys., 96(12):7750--7752, 2004.
[36] V. Sazonova, Y. Yaish, H. Üstünel, D. Roundy, P. L. McEuen, and T. A. Arias. A tunable carbon nanotube electromechanical oscillator. Nature, 431:284--287, 2004.
[37] H. J. Choi, D. Roundy, H. Sun, M. L. Cohen, and S. G. Louie. Reply to “comment on `first-principles calculation of the superconducting transition in mgb2 within the anisotropic eliashberg formalism' ”. Phys. Rev. B, 69(5):056502, 2004.
[38] D. Roundy and John Joannopoulos. Photonic crystal structure with square symmetry within each layer and a three-dimensional band gap. App. Phys. Lett., 82(22):3835, 2003.
[39] H. J. Choi, D. Roundy, H. Sun, M. L. Cohen, and S. G. Louie. The origin of the anomalous superconducting properties of mgb2. Nature, 418:758--760, August 2002.
[40] C. R. Krenn, D. Roundy, M. L. Cohen, D. C. Chrzan, and J. W. Morris, Jr. Connecting atomistic and experimental estimates of ideal strength. Phys. Rev. B, 65:134111, 2002.
[41] H. J. Choi, D. Roundy, H. Sun, M. L. Cohen, and S. G. Louie. First-principles calculation of the superconducting transition in mgb2 within the anisotropic eliashberg formalism. Phys. Rev. B, 66:020513, 2002.
[42] F. J Ribeiro, D. Roundy, and M. L. Cohen. Electronic properties of mose nanowires. Phys. Rev. B, 65:153401, 2002.
[43] W. Luo, D. Roundy, M. L. Cohen, and J. W. Morris, Jr. Ideal strength of bcc molybdenum and niobium. Phys. Rev. B, 66:094110, 2002.
[44] D. Roundy, C. R. Krenn, M. L. Cohen, and J. W. Morris, Jr. The ideal strength of tungsten. Phil. Mag. A, 81(7):1725, 2001.
[45] C. R. Krenn, D. Roundy, J. W. Morris, Jr., and M. L. Cohen. The nonlinear elastic behavior and ideal shear strength of al and cu. Mat. Sci. Eng. A, 317:44--48, 2001.
[46] C. R. Krenn, D. Roundy, J. W. Morris, Jr., and M. L. Cohen. The ideal strengths of bcc metals. Mat. Sci. Eng. A, 319:111--114, 2001.
[47] J. W. Morris, Jr., C. R. Krenn, D. Roundy, and M L Cohen. Deformation at the limit of elastic stability. Mat. Sci. Eng. A, 309:121--124, 2001.
[48] H. Sun, S. H. Jhi, D. Roundy, M. L. Cohen, and S. G. Louie. Structural forms of cubic bc2n. Phys. Rev. B, 64(9):094108, 2001.
[49] M. A. Khakoo, D. Roundy, C. Hicks, N. Margolis, E. Yeung, A. W. Ross, and T. J. Gay. Monte carlo studies of mott scattering asymmetries from gold foils. Phys. Rev. A, 64(5):052713, 2001.
[50] D. Roundy and M. L. Cohen. Ideal strength of diamond, si and ge. Phys. Rev. B, 64:212103, 2001.
[51] J. W. Morris, Jr., C. R. Krenn, D. Roundy, and M L Cohen. Elastic stability and the limits of strength. In P. E. Turchi and A. Gonis, editors, Phase Transformations and Evolution in Materials, page 187, Warrendale, Pa, 2000. TMS.
[52] F. Rugamas, D. Roundy, G. Mikaelian, G. Vitug, M. Rudner, J. Shih, D. Smith, J. Segura, and M. A. Khakoo. Angular profiles of molecular beams from effusive tube sources: I. experiment. Measurement Science and Technology, 11(12):1750--1765, 2000.
[53] D. Roundy, C. R. Krenn, M. L. Cohen, and J. W. Morris, Jr. Ideal shear strengths of aluminum and copper. Phys. Rev. Lett., 82(13):2713, 1999.
[54] M. A. Khakoo, D. Roundy, and F. Rugamas. Electron-impact excitation of the 11s->31p and 11s->431p transition in helium. Phys. Rev. A, 54(5):4004--4014, 1996.
[55] M. A. Khakoo, D. Roundy, and F. Rugamas. Electron-impact excitation of the 11s->31p transition in helium. Phys. Rev. Lett., 75(1):41--44, 1995.


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