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Peer-reviewed Papers

122. D. T.-X. Dang, D.-N. Le, and L. M. Woods, Dissecting van der Waals interactions with Density Functional Theory - Wannier-basis approach, submitted (2024) 

121. D. Zhou, Y. T. H. Pham, D. T-X. Diem, D. Sanchez, A. Oberoi, K. Wang, A. Fest, A. Sredenschek, M. Liu, H. Terrones, S. Das, D.-N. Le, L. M. Woods, M.-H. Phan, and M. Terrones, Vanadium-doped Molybdenum Disulfide monolayers with tunable electronic and magnetic properties: do dopant-vacancy pairs matter?, submitted (2024)

120. O. P. Ojo, L. Ma, D. C. B. Gunatilleke, A. J. Biacchi, H. Wang, L. M. Woods, and G. S. Nolas, A synergistic theoretical and experimental study elucidating the electronic and thermal properties in spinel CuInSnS4, Mater. Res. Bulletin 178, 112888 (2024)

119. P. Rodriguez-Lopez, D.-N. Le, I. V. Bondarev, M. Antezza, and L. M. Woods, Giant anisotropy and Casimir phenomena: the case of carbon nanotube metasurfaces, Phys. Rev. B 104, 035422 (2024)

118 D.-N. Le, P. Rodriguez-Lopez, and L. M. Woods, Nonlinear effects in many-body van der Waals interactions, Phys. Rev. Research 6, 013289 (2024)

117. R. K. Barik and L. M. Woods, Statistical modeling of frictional properties of two dimensional materials enabled by machine learning, submitted (2023)

116. R. K. Barik and L. M. Woods (2023). Machine Learning Modeling of Frictional Properties of 2D Materials. figshare. Software. https://doi.org/10.6084/m9.figshare.23739633.v1  

115. K. Huang, X. Cao, Y. Lu, M. Xiu, K. Cui, B. Zhang, W. Shi, X. Li, J. Xia, L. M. Woods, S. Zhu, Z. Wang, Z. Liu, J. Wu, and Y. Huang, Scalable lattice-disorder electrodes engineered by thermal dezincification for highly efficient hydrolysis, submitted (2023)

114. I. V. Bondarev, M. D. Pugh, P. Rodriguez-Lopez, L. M. Woods, and M. Antezza, Confinement-induced nonlocality and Casimir force in transdimensional systems, PCCP 25, 29257 (2023)

113. L. Ma, W. Shi, and L. M. Woods, Cation substitution varieties of I-II2-III-VI4 semiconductors and their effects on electronic and phononic properties, J. Alloys and Comp. 969, 172399 (2023)

112. O. P. Ojo, L. Ma, W. D. C. Gunatilleke, A. F. May, L. M. Woods, and G. S. Nolas, Electronic and thermal properties of the cation-substitution-derived quaternary chalcogenide CuInSnSe4, Inorg. Chemistry 62, 16114 (2023)

111. R. K. Barik and L. M. Woods, High throughput calculations of bilayer materials, Scientific Data 10, 232 (2023)

110. R. K. Barik and L. M. Woods (2022), BMDB - Bilayer materials database, https://doi.org/10.6084/m9.figshare.21799475.v2 

109. C.-M. Hung, D. T.-X. Dang, A. Chanda, D. Detellem, N. Alzahrani, N. Karupuge, Y. T. H. Pham, M. Liu, D. Zhou, H. Gutierrez, D. Arena, M. Terrones, S. Witanachchi, L. M. Woods, H. Srikanth, and M.-H. Phan, Enhanced magnetism and anomalous Hall transport through two-dimensional tungsten disulfide interfaces, Nanomaterials 13, 771 (2023)

108. K. Huang, X. Cao, M. Xiu, K. Cui, B. Zhang, W. Shi, X. Li, J. Xia, L. M. Woods, S. Zhu, Z. Wang, and J. Wu, Self-reconstructed spinel surface structure enabling the long-term stable HER/OER efficiency of FeCoNiRu high-entropy alloyed electrocatalyst, Adv. Science, 2300094 (2023)

107. P. Rodriguez-Lopez, D.-N. Le, M. J. Calderon, E. Bascones, and L. M. Woods, Twisted bilayered graphenes at magic angles and Casimir interactions: correlation-driven effects, 2D Materials 10, 014006 (2022) (Focus Issue on Twistronics in 2D Materials)

106. D. T.-X. Dang, R. K. Kumar, M.-H. Phan, and L. M. Woods, Enhanced Magnetism in Heterostructures with Transition Metal Dichalcogenide Monolayers, The J. Phys. Chem. Lett. 13, 8879 (2022)

105. L. Ma, W. Shi, and L. M. Woods, Structural diversity of CuZn2InSe4 quaternary chalcogenide: electronic and phonon properties from first principles, RSC Advances 22, 26648 (2022)

104. D.-N. Le, P. Rodriguez-Lopez, and L. M. Woods, Dispersive interactions between standard and Dirac materials and the role of dimensionality, J. Phys. Materials 5, 034001 (2022)

103.  W. Shi and L. M. Woods, Thermoelectric Efficiency for Anisotropic Materials, J. Phys.: Energy 4, 014001 (2022)

102.  M.-H. Phan, M. T. Trinh, T. Eggers, V. Kalappattil, L. M. Woods, and M. Terrones, A perspective on two-dimensional van de Waals opto-spin-caloritronics, Appl. Phys. Lett. 119, 250501 (2021)

101.   W. Shi, T. Pandey, L. Lindsay, and L. M. Woods, Vibrational properties and transport in quaternary chalcogenides: the case of Te-based compositions, Phys. Rev. Materials 5, 045401 (2021)

100.  N. Alzarani, H. Poddig, H. Wang, J. Martin, W. Shi, L. M. Woods, and G. S. Nolas, Off-stoichiometric semiconductors Cu1.33+xZn1.33-xIn1.33Se4 (x = 0, 0.1, 0.2 and 0.3): Synthesis, structure, and thermal and electrical properties, J. Solid St. Chemistry 297, 122058 (2021)

99.  L. M. Woods, M. Kruger, and V. V. Dodonov, Perspective on some recent and future developments in Casimir interactions, Appl. Sciences 11, 293 (2021)

98.  D. T. Nga, A. D. Phan, V. D. Lam, L. M. Woods, and K. Wakabayashi, Enhanced solar photothermal effect of PANI fabrics with plasmonic nanostructures, RSC Advances 10, 28447 (2020)

97.  T. Stedman and L. M. Woods, Transport theory within the Boltzmann equation for multiband wave packets, Phys. Rev. Research 2, 033086 (2020)

96.  W. Shi, T. Stedman, and L. M. Woods, Thermoelectric transport control with metamaterial composites, J. Appl. Phys. 128, 025104 (2020) (featured in AIP Scilights)

95.  W. Shi, A. Khabibullin, and L. M. Woods, Exploring phase stability and properties of I-II2-III-VI4 quaternary chalcogenides, Adv. Theory Simul. 3, 2000041 (2020)

94.  P. Rodriguez-Lopez, A. Popescu, I. Fialkovsky, N. Khusnutdinov, and L. M. Woods, Signatures of Complex Optical Response in Casimir Interactions of Type I and II Weyl Semimetals, Commun. Materials (Nature) 1, 14 (2020)

93.  V. Kalappattil, R. Geng, R. Das, H. Luong, M. Pham, T. Nguyen, A. Popescu, L. M. Woods, M. Klaui, H. Srikanth, and M. H. Phan, Giant spin Seebeck effect through an interface organic semiconductor, Mater. Horiz. 7, 1413 (2020)

92.  G. L. Klimchitskaya, V. M. Mostepanenko, K. Yu, and L. M. Woods, The Casimir force, causality, and the Gurzhi model, Phys. Rev. B 101, 075418 (2020)

91.  D. Hobbis, W. Shi, A. Popescu, K. Wei, R. E. Baumbach, H. Wang, L. M. Woods, and G. S. Nolas, Synthesis, transport properties and electronic structure of p–type CuMn2InTe4, Dalton Trans. 49, 2273 (2020)

90.  G. Nolas, L. M. Woods, and R. Funahashi, Advanced Thermoelectric (editorial to the focused issue on Advanced Thermoelectrics), J. Appl. Phys. 127, 060401 (2020)

89. A. Popescu, A. Pertsova, A. V. Balatsky, and L. M. Woods, Optical Response of MoTe2 and WTe2 Weyl Semimetals: Distinguishing Between Bulk and Surface Contributions, Adv. Theory Simul. 3, 1900247 (2020)

88.  T. Stedman, C. Timm, and L. M. Woods, Multiband effects in equations of motion of observables beyond the semiclassical approach, New J. Phys. 21, 103007 (2019)

87.  A. D. Phan, N. B. Le, N. T. H. Lien, L. M. Woods, S. Ishi, and K. Wakabayashi, Confinement effect on the solar thermal heating process of TiN nanoparticle solutions, Phys. Chem. Chem. Phys. 21, 19915 (2019)

86.  N. Khusnutdinov and L. M. Woods, Casimir effects in 2D Dirac materials, JETP Lett. 110, 183 (2019)

85.  A. Popescu, P. Rodriguez-Lopez, and L. M. Woods, Composition and stacking dependent topology in bilayers from the graphene family, Phys. Rev. Materials 3, 064002 (2019)

84.  W. Shi, A. Khabibullin, D. Hobbis, G. S. Nolas, and L. M. Woods, Electronic structure properties of CuZn2InTe4 and AgZn2InTe4 quaternary chalcogenides, J. Appl. Phys. 125, 155101 (2019) (chosen as an Editor’s Pick)

83.  W. Shi, T. Stedman, and L. M. Woods, Transformation optics for thermoelectricity, J. Phys.:  Energy 1, 025002 (2019)

82.  A. R. Khabibullin, K. Wei, T. D. Huan, G. S. Nolas, and L. M. Woods, Compositional effects and electron lone-pair distortions in doped bournonites,  ChemPhysChem 19, 2635 (2018) (selected for the cover of Issue 20, ChemPhysChem)

81.  K. Wei, A. R. Khabibullin, D. Hobbis, W. Wong-Ng, T. Chang, S.-Y. G. Wang, I. Levin, Y.-S. Chen, L. M. Woods, and G. S. Nolas, Synthesis, structure, and electrical properties of the single crystal Ba8Cu16As30, Inorg. Chem. 57, 9327 (2018)

80.  A.R. Khabibullin, A. Karolak, M.M. Budzevich, M.L. McLaughlin, L.M. Woods, and D.L. Morse, Structure and properties of DOTA-chelated radiopharmaceuticals within the 225Ac decay pathway, Med. Chem. Comm. 9, 1155 (2018)

79.  N. Khusnutdinov, R. Kashparov, and L.M. Woods, Thermal Casimir and Casimir-Polder interactions in N parallel 2D Dirac materials, 2D Mater. 5, 035032 (2018)

78.  A. Popescu, P. Rodriguez-Lopez, P. M. Haney, and L.M. Woods, Thermally driven anomalous Hall effect transitions in FeRh, Phys. Rev B 97, 140407 (R) (2018)

77.  P. Rodriguez-Lopez, W.J.M. Kort-Kamp, D.A.R. Dalvit, and L.M. Woods, Nonlocal optical response in topological phase transitions in the graphene family, Phys. Rev. Materials 2, 014003 (2018)

76.  K. Wei, A.R. Khabibullin, T. Stedman, L.M. Woods, and G.S. Nolas, Polaronic transport in Ag-based quaternary chalcogenides, J. Appl. Phys. 122, 105109 (2017)

75.  T. Stedman and L.M. Woods, Cloaking of thermoelectric transport, Sci. Rep. 7, 6988 (2017)

74.  A.R. Khabibullin, T.D. Huan, G.S. Nolas, and L.M. Woods, Cage disorder and gas encapsulation as routes to tailor properties of inorganic clathrates, Acta Mater. 131, 475  (2017)

73.  P. Rodriguez-Lopez, W.J.M. Kort-Kamp, D.A.R. Dalvit, and L.M. Woods, Casimir force phase transitions in the graphene family, Nat. Comm. 8, 14699 (2017)

72.  L.M. Woods, D.A.R. Dalvit, A. Tkatchenko, P. Rodriguez-Lopez, A.W. Rodriguez, and R. Podgornik, A Materials Perspective of Casimir and van der Waals Interactions, Rev. Mod. Phys. 88, 045003 (2016)

71.  K. Wei, X. Zeng, T.M. Tritt, A.R. Khabibullin, L.M. Woods, and G.S. Nolas, Structure and transport properties of dense polycrystalline clathrate-II (K,Ba)16(Ga,Sn)136 synthesized by a new approach, Materials 9, 732 (2016) (Special Issue on Inorganic Clathrates)

70.  N. Khusnutdinov, R. Kashparov, and L. M. Woods, The Casimir-Polder effect for a stack of conductive planes, Phys. Rev. A 94, 012513 (2016)

69.  N.B. Le and L.M. Woods, Graphene nanoribbons anchored to SiC substrates, J. Phys.: Cond. Matter 28, 364001 (2016) (Special issue on “Interfaces and heterostructures of van der Waals materials”, by invitation)

68.  T.D. Huan, V.N. Tuoc, N.B. Le, N.V. Minh, and L.M. Woods, High-pressure phases of magnesium silicide Mg2Si, Phys. Rev. B 93, 094109 (2016)

67.  N. B. Le, T. D. Huan, and L. M. Woods, Interlayer Interactions in van der Waals Heterostructures: Electron and Phonon Properties, ACS Appl. Mater. Interfaces 8, 6286 (2016)

66.  R. Kashparov, N. Khusnutdinov, and L. M. Woods, The Casimir effect for planar layered system, Int. J. Mod. Phys. A 31, 1641028 (2016)

65.  D. Drosdoff, I.V. Bondarev, A. Widom, R. Podgornik, and L.M. Woods, Charge induced fluctuation forces in graphitic nanostructures, Phys. Rev. X 6, 011004 (2016)

64.  K. Wei, T. Stedman, Z.H. Ge, L.M. Woods, and G.S. Nolas, A synthetic approach for enhanced thermoelectric properties of PEDOT:PSS bulk composites, Appl. Phys. Lett. 107, 153301 (2015)

63.  T. Stedman, K. Wei, G.S. Nolas, and L.M. Woods, Thermoelectric transport in polymer composites: thermally induced fluctuations and tunneling, Phys. Chem. Chem. Phys. 17, 27883 (2015)

62.  N. Khusnutdinov, R. Kashparov, and L.M. Woods, Casimir effect for a stack of conductive planes, Phys. Rev. D 92, 045002 (2015)

61.  Y. Dong. A. Khabibullin, K. Wei, J. Salvador, G.S. Nolas, and L.M. Woods, Bournonite PbCuSbS3: Stereochemically active lone-pair electrons inducing low thermal conductivity, ChemPhysChem 26, 3264 (2015)

60.  D. Drosdoff, A.D. Phan, and L.M. Woods, Transverse electric mode for near-field radiative heat transfer in graphene-metamaterial systems, Adv. Opt. Mater. 2, 1038 (2014)

59.  Y. Dong, K. Wei, Z.H. Ge, A.R. Khabibullin, J. Martin, J.R. Salvador, L.M. Woods, and G.S. Nolas, Synthesis, transport properties, and electronic structure of Cu2CdSnTe4, Appl. Phys. Lett. 104, 252107 (2014)

58.  A. Khabibullin and L.M. Woods, Ab Initio Investigation of Bi rich Bi1-xSbx Alloys, J. of Electr. Mater. 43, 3110 (2014)

57.  N.B. Le, H. Tran, and L.M. Woods, Spin-dependent structure-property correlations in zigzag silicene nanoribbons, Phys. Rev. Applied 1, 054002 (2014)

56.  N. Khusnutdinov, D. Drosdoff, and L.M. Woods, Casimir energy for surfaces with constant conductivity, Phys. Rev. D 89, 085033 (2014)

55.  D. Drosdoff and L.M. Woods, Quantum and thermal dispersion forces: Application to graphene nanoribbons, Phys. Rev. Lett. 112, 025501 (2014)

54.  T. Stedman, D. Drosdoff, and L.M. Woods, Van der Waals interactions between nanostructures: some results from series expansions, Phys. Rev. A 89, 012509 (2014)

53.  A.D. Phan, T.L. Phan, and L.M. Woods, Near-field transfer between gold nanoparticle arrays, J. Appl. Phys. 114, 214306 (2013)

52.  A.D. Phan, Sheng Shen, and L.M. Woods, Radiative Exchange between graphitic nanostructures: a microscopic perspective, J. Phys. Chem. Lett. 4, 4196 (2013)

51.  A.D. Phan, T.X. Hoang, T.L. Phan, and L.M. Woods, Repulsive interaction of cell membrane with graphene on composite materials, J. Chem. Phys. 139, 184703 (2013)

50.   A.D. Phan, T.X. Hoang, T.H. Nghiem, and L.M. Woods, Surface plasmon resonances of protein-conjugated gold nanoparticles on graphitic substrates, Appl. Phys. Lett. 103, 163702 (2013)

49.  T.D. Huan, M. Amsler, R. Sabatini, V.N. Tuoc, N.B. Le, L.M. Woods, N. Marzari, and S. Goedecker, Thermodynamic stability of alkali metal/zinc double cation borohydrides at low temperatures, Phys. Rev. B 88, 024108 (2013)

48.  A.D. Phan, L.M. Woods, and T.L. Phan, Van der Waals interactions between graphitic nanowiggles, J. Appl. Phys. 114, 044308 (2013)

47.  N.B. Le and L.M. Woods, Zigzag graphene nanoribbons with curved edges, RSC Advances 3, 10014 (2013)

46.  L.M. Woods, A. Popescu, D. Drosdoff, and I.V. Bondarev, Dispersion interactions in graphitic nanostructures, Chem. Phys. 413, 116 (2013) (Special Issue on Photophysics of Carbon Nanotubes and Nanotube Composites)

45.  A.D. Phan, L.M. Woods, and N.A. Viet, Temperature phase transition model for DNA-CNT-based nanotweezers, J. of Math. Chem. 51, 278 (2013)

44.  A.D. Phan, N.A. Viet, N.A. Poklonskii, and L.M. Woods, Interaction of a graphene sheet with a ferromagnetic metal plate, Phys. Rev. B 86, 155419 (2012)

43.  D. Drosdoff, A.D. Phan, L.M. Woods, I.V. Bondarev, and J.F. Dobson, Effects of spatial dispersion on the Casimir force between two graphene sheets, Eur. Phys. J. B 85, 365 (2012)

42.  A. Popescu and L.M. Woods, Valleytronics, carrier filtering, and thermoelectricity in bismuth: magnetic field polarization effects, Adv. Funct. Mat. 22, 3945 (2012) (featured in Advances in Engineering, a premier venue for academic and industrial R&D personnel)

41.  A.D. Phan, L.M. Woods, D. Drosdoff, I.V. Bondarev, and V.A. Viet, Temperature dependent graphene suspension due to the thermal Casimir interaction, Appl. Phys. Lett. 101, 113118 (2012)

40.  A. Popescu, L.M. Woods, and G.S. Nolas, Magnetic field and nanostructuring effects on the thermoelectric performance of bismuth, Phys. Rev. B 85, 115202 (2012)

39.  N.B. Le and L.M. Woods, Folded graphene nanoribbons with single and double closed edges, Phys. Rev. B 85, 035403 (2012)

38.  D. Drosdoff and L.M. Woods, Casimir interactions between graphene and metamaterials, Phys. Rev. A 84, 062501 (2011)

37.  I.V. Bondarev, L.M. Woods, and A. Popescu, On the role of interband surface plasmons in carbon nanotubes, Optics and Spec. 111, 770 (2011)

36.  A. Popescu, A. Datta, G.S. Nolas, and L.M. Woods, Thermoelectric properties of Bi-doped PbTe composites, J. Appl. Phys. 109, 103709 (2011)

35.  A. Popescu, L.M. Woods, and I.V. Bondarev, Chirality dependent carbon nanotube interactions, Phys. Rev. B 83, 081406 (R) (2011)

34.  D. Drosdoff and L.M. Woods, Casimir forces and graphene sheets, Phys. Rev. B 82, 155459 (2010)

33.  A. Popescu and L.M. Woods, Enhanced Thermoelectricity in Composites by Electronic Structure Modifications and Nanostructuring, Appl. Phys. Lett. 97, 052102 (2010)

32.  Y. V. Shtogun and L.M. Woods, Many-Body van der Waals Interactions between Graphitic Nanostructures, J. Phys. Chem. Lett. 1, 1356 (2010)

31.  I. V. Bondarev, K. Tatur, and L.M. Woods, Surface Exciton-Plasmons and Optical Response of Small-Diameter Carbon Nanotubes, Optics and Spec. 108, 376 (2010)

30.  Y.V. Shtogun and L.M. Woods, Mechanical Properties of Defective Single Wall Carbon Nanotubes, J. of App. Phys. 107, 061803 (2010)

29.  A. Popescu and L.M. Woods, Telescopic Hot Double Wall Carbon Nanotube for Nanolithography, Appl. Phys. Lett. 95, 203507 (2009)

28.  L.M. Woods, A. Popescu, J, Martin, and G.S. Nolas, Transport Properties of Thermoelectric Nanocomposites, MRS Symposium Proceedings Vol. 1166-N05-08 (2009)

27.  K. Tatur and L.M. Woods, Electromagnetic interactions between parallel dialectric-diamagnetic cylinders, Phys. Rev. A 80, 050101 (R) (2009)

26.  Y.V. Shtogun and L.M. Woods, Electronic and Magnetic Properties of Deformed and Defective Single Wall Carbon Nanotubes, Carbon 47, 3252 (2009)

25.  I.V. Bondarev, L.M. Woods, and K. Tatur, Strong Exciton-Plasmon Coupling in Semiconducting Carbon Nanotubes, Phys. Rev. B 80, 085407 (2009)

24.  A. Popescu, L.M. Woods, J. Martin, and G.S. Nolas, Model of Transport Properties of Thermoelectric Nanocomposite Materials, Phys. Rev. B 79, 205302 (2009)

23.  Y. Shtogun and L.M. Woods, Electronic Structure Modulations of Radially Deformed Single Wall Carbon Nanotubes under Transverse External Electric Fields, J. of Phys. Chem. C 113, 4793 (2009)

22.  J. Pritz and L.M. Woods, Radiative Electromagnetic Modes in Concentric Cylindrical Layers, Physica B 404, 1585 (2009)

21.  I.V. Bondarev, K. Tatur, and L.M. Woods, Optical Response of Small-Diameter Semiconducting Carbon Nanotubes under Exciton-Surface-Plasmon Coupling, Optics Comm. 282, 661 (2009)

20.  G. Dovbeshko, L.M. Woods, Y. Shtogun, and O. Fesenko, Modeling of DNA Base Interactions with Carbon Nanotubes: ab initio Calculations and SEIRA Data, AIP Conf. Proc. 1148, 416 (2009)

19. K. Tatur, L.M. Woods, and I.V. Bondarev, Zero-point Energy of a Cylindrical Layer of Finite Thickness, Phys. Rev. A 78, 012110 (2008)

18.  A. Popescu, L.M. Woods, and I.V. Bondarev, A Carbon Nanotube Oscillator as a Surface Profiling Device, Nanotechnology 19, 435702 (2008)

17.  K. Tatur and L.M. Woods, Zero-point Energy of N Perfectly Conducting Concentric Cylindrical Shells, Physical Letters A 372, 6705 (2008)

16.  J. Pritz and L.M. Woods, Surface Plasmon Polaritons in Concentric Cylindrical Structures, S. St. Comm. 146, 345 (2008)

15.  A. Popescu, L.M. Woods, and I.V. Bondarev, Simple Model of van der Waals Interactions between two Radially Deformed Single-Wall Carbon Nanotubes, Phys. Rev. B 77, 115443 (2008)

14.  L.M. Woods, T.L. Reinecke, and A.K. Rajagopal, Electron Spin Dynamics due to Hyperfine Coupling in Quantum Dots, Phys. Rev. B 77, 07331 (2008)

13.  Y. V. Shtogun, L.M. Woods, and G.I Dovbeshko, Adsorption of Adenine and Thymine and their Radicals on Single Wall Carbon Nanotubes, J. of Phys. Chem. C 111, 18174 (2007)

12.  L.M. Woods, S.C. Badescu, and T.L. Reinecke, Adsorption of Simple Benzene Derivatives on Carbon Nanotubes, Phys. Rev. B 75, 155415 (2007)

11.  L.M. Woods and T.L. Reinecke, Electron-spin Decoherence due to Hyperfine Coupling in Quantum Dots, AIP Conf. Proceedings 772, 1343 (2005)

10.  L. M. Woods, T. L. Reinecke, and R. Kotlyar, Hole Spin Relaxation in Quantum Dots, Phys. Rev. B 69, 125330 (2004)

9.  L.M. Woods and T.L. Reinecke, Nonlinear Polaritonic Effects in Photonic Wires, Phys. Rev. B 67, 115336 (2003)

8.  L. M. Woods and T. L. Reinecke, Spin Relaxation in Quantum Dots, Phys. Rev. B 66, (R) 161318 (2002)

7.  L.M. Woods, Magnon-phonon Effects in Ferromagnetic Manganites, Phys. Rev. B 65, 014409 (2002)

6.  D. Mandrus, J.R. Thompson, R. Gaal, L. Forro, J.C. Bryan, B.C. Chakoumakos, L.M. Woods, B.C. Sales, R.S. Fishman, and V. Keppens, Continuous Metal-insulator Transition in Pyrochlore Cd2Os2O7, Phys. Rev. B 63, 195104 (2001)

5.  L.M. Woods, Electronic Structure of Ca2RuO4: a Comparison with the Electronic Structures of Other Ruthenates, Phys. Rev. B 62, 7833 (2000)

4.  L. M. Woods and G. D. Mahan, Electron-Phonon effects in Graphene and Armchair (10,10) Single-Wall Carbon Nanotubes, Phys. Rev. B 61, 10 651 (2000); Also published in “Selected Papers on Nanotechnology – Theory and Modeling” edited by F. Wang and A. Lakhtakia, 2006

3.  G.D. Mahan and L.M. Woods, Phonon Modulated Electron-Electron Interactions, Phys. Rev. B 60, 5276 (1999)

2.  G. D. Mahan and L. M. Woods, Multilayer Thermionic Refrigeration, Phys. Rev. Lett. 80, 4016 (1998)

1.  L.M. Woods and G.D. Mahan, Nonlinear Electron-Phonon Heat Exchange, Phys. Rev. B 57, 7679 (1998)

Books

  • "The Bottom-Up Approach to Bulk Thermoelectric Materials with Nano-scale Domains", A. Datta, A. Popescu, L.M. Woods, and G.S. Nolas (2011 CRC Handbook, Taylor&Francis Group)

  • "Exciton-Plasmon Interactions in Individual Carbon Nanotubes", I.V. Bondarev, L.M. Woods, and A. Popescu (Chapter 7 in "Plasmons: Theory and Applications", Nova Publishers, 2010)

  • "Properties of Carbon Nanotubes under External Factors", Y.V. Shtogun and L.M. Woods (Chapter 1 in "Carbon Nanotubes", Intech, 2010)

  • "Nucleic Acid Interaction and Interfaces with Single-Walled Carbon Nanotubes", G. Dovbeshko, O. M. Fesenko, O. Gnatyk, Y. Shtogun, L.M. Woods, S. Bertarione, A. Damin, D. Scarano, and Z. Adriano (Chapter 34 in "Carbon Nanotubes", Intech, 2010)

Patents

  • US Patent 10895421; “Thermoelectric flow cloaking via metamaterials” T. Stedman and L.M. Woods

  • US Patent 8,920,700; “Telescopic nanotube device for hot nanolithography”, A. Popescu and L.M. Woods

  • US Patent 8,060,943; “Carbon nanotube oscillator surface profiling device and method of use”, A. Popescu, L.M. Woods, and I.V. Bondarev

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