PhD: University of Calcutta, 1985
Foundations of Quantum Mechanics and Quantum Information
Department of Physics
93/1, A. P. C. Road
Kolkata - 700 009, India
(a) An ingenious idea was formulated by invoking Quantum indistinguishability leading to an arbitrarily efficient resource for producing entanglement, applicable for spin-like variables of any two identical bosons/fermions (Phys. Rev. Lett. 88, 050401 (2002)). Entanglement being at the core of QI, this work stimulated applications of Quantum Statistics in QI processing, apart from being used in studies on free electron Quantum Computation.
(b) A hitherto unexplored use of intraparticle path-spin entanglement (Physics Letters A 279, 281(2001) was conceived for empirically verifying Quantum Contextuality (subsequently tested, Nature 425, 45 (2003)), followed recently by suggesting its information-theoretic applications (Euro Physics Letters 89, 10005 (2010)).
(c) The widely cited analysis of the Quantum Zeno effect (Annals of Physics 258, 237 (1997)), preceded by the formulation of a unified framework for such effects (Physics Letters A 173, 327 (1993)).
(d) Proposed a novel experiment to demonstrate simultaneous wave and particle – like behaviour in the same setup using optical tunneling of single photon states (Physics Letters A 153, 403 (1991)), subsequently implemented (Physics Letters A 168, 1 (1992)).
(e) Conceived an innovative biomolecular example to probe the Quantum Measurement Problem (Physical Review Letters 76, 2836 (1996)).
Quantum mechanical violation of macrorealism for large spin and its robustness against coarse-grained measurements; S. Mal, D. Das and D. Home, Physical Review A 94, 062117 (2016).
Manifestation of pointer-state correlations in complex weak values of quantum observables; S. Kanjilal, G. Muralidhara and D. Home, Physical Review A 94, 052110 (2016).
Sharing of Nonlocality of a Single Member of an Entangled Pair of Qubits Is Not Possible by More than Two Unbiased Observers on the Other Wing; S. Mal, A. S. Majumdar and D. Home; Special Issue “Mathematics of Quantum Uncertainty”- Mathematics 4, 48 (2016).
Duality in Entanglement tested with Bell Measurements; I. P. Degiovanni, E. Moreva, M. Gramegna, M. Genovese, S. Bose, D. Home, and G. Brida; in Conference on Lasers and Electro-Optics, OSA Technical Digest (Optical Society of America,) JTu5A.27 ( 2016).
Facets of the Leggett-Garg inequality: some recent studies; D. Home, Current Science 109, 1980 (2015).
Effect of quantum statistics on the gravitational weak equivalence principle; S. V. Mousavi, A. S. Majumdar and D. Home, Classical and Quantum Gravity 32, 215014 (2015).
Bell measurements as a witness of a dualism in entanglement; E. Moreva, G. Brida, M. Gramegna, S. Bose, D. Home and M. Genovese, Physical Review A 91, 062117 (2015).
Toward secure communication using intra-particle entanglement; S. Adhikari, D. Home, A. S. Majumdar, A. K. Pan, A. Shenoy H. and R. Srikanth, Quantum Information Processing 14, 1451 (2015).
Wigner’s form of the Leggett-Garg inequality, No-Signaling-in-time condition, and unsharp measurement; D. Saha, S. Mal, P. K. Panigrahi and D. Home, Physical Review A 91, 032117 (2015).
Multipartite Bell-type Inequality by Generalizing Wigner’s Argument; D. Home, D. Saha and S. Das, Physical Review A 91, 012102 (2015).
Unification of Bell, Leggett-Garg and Kochen-Specker inequalities: Hybrid spatio-temporal inequalities; S. Das, S. Arvinda, R. Srikanth and D. Home, Europhysics Letters 104, 60006 (2013).
Duality in Entanglement Enabling a Test of Quantum Indistinguishability Unaffected by Interactions; S. Bose and D. Home, Physical Review Letters 110, 140404 (2013).
Probing the Leggett-Garg inequality for oscillating neutral kaons and neutrinos; D. Gangopadhyay, D. Home and A. Sinha Roy, Physical Review A 88, 022115 (2013).
Reexamining Larmor precession in a spin-rotator: Testable correction and its ramifications; D. Home, A. K. Pan and A. Banerjee, The European Physical Journal D 67, 72 (2013).
Reply to Comment on ‘Quantitative probing of the quantum-classical transition for the arrival time distribution’; D Home, A. K. Pan and A. Banerjee, Journal of Physics A: Mathematical and Theoretical 46, 208002 (2013).
A testable prediction of the no-signalling condition using a variant of the EPR-Bohm example; D. Home, A. Rai and A. S. Majumdar, Physics Letters A 337, 540 (2013).
Effect of a transient barrier on wavepacket traversal; D. Home, A. S. Majumdar and A. Matzkin, Journal of Physics A: Mathematical and Theoretical 45, 295301 (2012).
Strong quantum violation of the gravitational weak equivalence principle by a non-Gaussian wave-packet; P. Chowdhury, D. Home, A. S. Majumdar, S. V. Mousavi, M. R. Mozaffari and S. Sinha, Classical and Quantum Gravity 29, 025010 (2012).
Quantum violation of noncontextuality for separable states using fewer measurement settings; A. K. Pan and D. Home, The European Physical Journal D 66, 62 (2012).
Quantum teleportation using non-orthogonal entangled channels; S. Adhikari, A. S. Majumdar, D. Home, A. K. Pan and P. Joshi, Physica Scripta 85, 045001 (2012).
Testing non-locality of single photons using cavities; T. Pramanik, S. Adhikari, A. S. Majumdar and D. Home, Physics Letters A 376, 344 (2012).
On Empirical Scrutiny of the Bohmian Model Using a Spin Rotator and the Arrival/Transit Time Distribution; A. K. Pan and D. Home, International Journal of Theoretical Physics 51, 374 (2012).
Leggett-type nonlocal realist inequalities without any constraint on the geometrical alignment of measurement settings; A. Rai, D. Home and A. S. Majumdar, Physical Review A 84, 052115 (2011).
An interplay between nonlocality and quantum violation of path-spin noncontextuality; D. Home and A. K. Pan, International Journal of Quantum Information 9, 1279 (2011).
On the Possibility of Empirically Probing the Bohmian Model in Terms of the Testability of Quantum Arrival/Transit Time Distribution; D. Home and A. K. Pan, in “Quantum Trajectories”; edited by P. Chattaraj (CRC Press, Taylor & Francis, 2011).
Quantum mechanical effect of path-polarization contextuality for a single photon; A. K. Pan and D. Home, International Journal of Theoretical Physics 49, 1920 (2010).
Reply to the “Comments on ‘Contextuality within quantum mechanics manifested in subensemble mean values’”; D. Home and A. K. Pan, Physics Letters A 374, 2195 (2010).
Information transfer using a single particle path-spin hybrid entangled state; T. Pramanik, S. Adhikari, A. S. Majumdar, D. Home, and A. K. Pan, Physics Letters A 374, 1121 (2010).
Swapping path-spin intraparticle entanglement onto spin-spin interparticle entanglement; S. Adhikari, A. S. Majumdar, D. Home, and A. K. Pan, Europhysics Letters 89, 10005 (2010).
Contextuality within quantum mechanics manifested in subensemble mean values; D. Home and A. K. Pan, Physics Letters A 373, 3430 (2009).
Dark energy from quantum wave function collapse of dark matter; A. S. Majumdar, D. Home, and S. Sinha, Physics Letters B 679, 167 (2009).
Quantitative probing of the quantum–classical transition for the arrival time distribution; D. Home, A. K. Pan and A. Banerjee, Journal of Physics A: Math. Theor. 42, 165302 (2009).
Using the no-signaling condition for constraining the nonidealness of a Stern-Gerlach set-up; D. Home and A. K. Pan, Journal of Physics A: Math. Theor. 42, 085301 (2009).
Quantum transit time distribution, its testability and foundational implications; D. Home and A. K. Pan, in “Quantum Optics – Coherence, Entanglement and Nonlinear Dynamics”; edited by J. Banerji, P. K. Panigrahi, and R. P. Singh (Macmillan India, 2008).
Reply to “Comment on ‘Quantum time-of-flight distribution for cold trapped atoms’”; M. Ali, D. Home, A. S. Majumdar and A. K. Pan, Physical Review A 77, 026101 (2008).
Aspects of nonideal Stern – Gerlach experiment and testable ramifications; D. Home, A. K. Pan, M. Ali and A. S. Majumdar, Journal of Physics A: Mathematical and Theoretical 40, 13975 (2007).
Quantum time of flight distribution for cold trapped atoms; M. Ali, D. Home, A. S. Majumdar and A. K. Pan, Physical Review A 75, 042110 (2007).
On the quantum analogue of Galileo’s leaning tower experiment; M. Ali, A. S. Majumdar, D. Home, and A. K. Pan, Classical and Quantum Gravity 23, 6493 – 6502 (2006).
Quantum Superarrivals: Bohr's Wave-Particle Duality Revisited; M. Ali, A. S. Majumdar, and D. Home, Foundations of Physics Letters 19, 179 (2006).
Observability of the arrival time distribution using spin-rotator as quantum clock; A. K. Pan, M. Ali and D. Home, Physics Letters A 352, 296 (2006).
Testing Quantum Statistics with Particles in Distinguishable States; S. Bose and D. Home, International Journal of Quantum Information 3, 117 (2005)
Information Transfer and Non-locality for a Tripartite Entanglement using Dynamics; D. Home and J. Corbett, Physics Letters A 333, 382 (2004).
Spin-dependent observable effect for Free Particles using the Arrival Time Distribution; M. Ali, A. S. Majumdar, D. Home and S. Sengupta, Physical Review A 68, 042105 (2003).
Information Flow and Quantum Cryptography using Statistical Fluctuations; D. Home and M. A. B. Whitaker, Physical Review A 67, 022306 (2003).
Generic entangling through quantum indistinguishability; S. Bose and D. Home, Pramana – Journal of Physics 59, 229 (2002).
Violation of Bell’s inequality in neutral kaons system; M. K. Samal and D. Home, Pramana – Journal of Physics 59, 289 (2002).
Understanding Quantum Superarrivals using the Bohmian Model; M. Ali, A. S. Majumdar and D. Home, Physics Letters A 304, 61 (2002).
Quantum Information Transfer without An External Chanel; D. Home and J. Corbett, in Proc. 7th Int. Symp. on Foundations of Quantum Mechanics in the Light of New Technology ISQM – Tokyo’01; World Scientific (2002).
Quantum Information Transfer Using A Time-Dependent Boundary Condition; D. Home and A. S. Majumdar; in Proc. 7th Int. Symp. on Foundations of Quantum Mechanics in the Light of New Technology ISQM – Tokyo’01; World Scientific (2002).
Generic Entanglement Generation, Quantum Statistics, and Complementarity; S. Bose and D. Home, Physical Review Letters 88, 050401 (2002).
Quantum-Mechanical Effects in a Time-varying Reflection Barrier; S. Bandyopadhyay, A. S. Majumdar and D. Home, Physical Review A 65, 052718 (2002).
Interpreting the Measurement of the Time of Decay: Phenomenological Significance of the Bohm Model; A. S. Majumdar and D. Home, Physics Letters A 296, 176 (2002).
Quantum superarrivals and information transfer through a time varying boundary; D. Home and A. S. Majumdar, Pramana – Journal of Physics 59, 321 (2002).
Bell's inequality for a single spin-1/2 particle and Quantum Contextuality; S. Basu, S. Bandyopadhyay, G. Kar and D. Home, Physics Letters A 279, 281 (2001).
Facets of Tripartite Entanglement, in Foundations of Quantum Theory and Quantum Optics; D. Home, Pramana – Journal of Physics 56, 179 (2001).
Quantum Effects involving Interplay between Unitary Dynamics and Kinematic Entanglement; D. Home and J. Corbett, Physical Review A 62, 062103 (2000).
On the Importance of the Bohmian Approach for Interpreting CP Violation Experiments; D. Home and A. S. Majumdar, Foundations of Physics 29, 721 (1999).
Quantum Zeno Effect: Relevance for Local Realism, Macroscopic Realism, and Non-invasive Measurability at the Macroscopic Level; D. Home and M.A.B. Whitaker, Physics Letters A 239, 6 (1998).
Response to “Comment on DNA Molecular Cousin of Schrödinger’s Cat: A Curious Example of Quantum Measurement”; D. Home and R. Chattopadhyaya, Physical Review Letters 80, 1349 (1998).
Comment on Why Quantum Mechanics Cannot be formulated as a Markov Process; L. Hardy, D. Home, E. J. Squires and M. A. B. Whitaker, Physical Review A 56, 3301 (1997).
A Conceptual Analysis of Quantum Zeno; Paradox, Measurement and Experiment; D. Home and M. A. B. Whitaker, Annals of Physics 258, 237 (1997).
Collapse-Induced Quantum Nonlocal Effect; D. Home and G. Kar, Foundations of Physics 27, 1765 (1997).
Testing a Dynamical Model of Wavefunction Collapse in the Cosmological Scenario; D. Home and A.S. Majumdar, in Quantum Coherence and Decoherence; edited by K. Fujikawa and Y. A. Ono (Elsevier, 1996).
Is Spontaneous Localization Compatible with the Energy density of the Universe?; A. S. Majumdar and D. Home, Physics Letters A 220, 17 (1996).
The Two-Prism Experiment and Wave Particle Duality of Light; P. Ghose and D. Home, Invited Contribution to the Special Issue of Foundations of Physics in honour of Max Jammer 26, 943 (1996).
Standard Quantum Mechanics with Environment-Induced Decoherence and Wavefunction Collapse: Possibility of an Empirical Discrimination Using Neutron Interferometry; D. Home and S. Bose, Physics Letters A 217, 209 (1996).
DNA Molecular Cousin of Schrödinger’s Cat: A Curious Example of Quantum Measurement; D. Home and R. Chattopadhyaya, Physical Review Letters 76, 2836 (1996).
The inadequacy of Effective Incoherence Interpretations of Quantum Theory, as demonstrated by analysis of EPR Measurements; D. Home and M. A. B. Whitaker, Physics Letters A 211, 5 (1996).
Incompatibility between Quantum Mechanics and Classical Realism in the Strong Macroscopic Limit; D. Home and A. S. Majumdar, Physical Review A 52, 4959 (1995).
Quantum Nonlocality of Single Photon States; D. Home and G. S. Agarwal, Physics Letters A 209, 1 (1995).
An Analysis of the Aharonov-Anandan-Vaidman Model; P. Ghose and D. Home, Foundations of Physics 25, 1105 (1995).
Quantum Mechanical Interference and Indistinguishability in Nuclear Orbiting Reactions; A. Ray and D. Home, Physics Letters A 204, 87 (1995).
On Boson Trajectories in the Bohm Model; P. Ghose and D. Home, Physics Letters A 191, 362 (1994).
Position and Contextuality in Bohm’s Causal Completion of Quantum Mechanics; D. Home, Physics Letters A 190, 353 (1994).
Wave Function Collapse as a Nonlocal Quantum Effect; D. Home and R. Nair, Physics Letters A 187, 224 (1994).
Parameter Dependence in the EPR-Bohm Type Experiment; D. Home and M. A. B. Whitaker, Physics Letters A 187, 227 (1994).
Simultaneously Sharp Wave and Particle-Like Property of Single Photon States in a Two-Prism Experiment; P. Ghose and D. Home in: Recent Developments in Quantum Optics, edited by R. Inguva (Springer, 1993) 43 – 46.
Non-Classical Interference and Which Path Information in a Gamma Angular Correlation Experiment Using a Heavy-Ion Orbiting Reaction; A. Ray and D. Home, Physics Letters A 178, 33 (1993).
Relativistic quantum mechanics of bosons; P. Ghose, D. Home and M. N. Sinha Roy, Physics Letters A 183, 267 (1993).
Comment on Computational Approach to the Quantum Zeno Effect; D. Home and M. A. B. Whitaker, Physical Review A 48, 2502 (1993).
A New Theorem on Quantum Nonlocality, D. Home, Vistas in Astronomy 37, 269-272 (1993).
Interrupted Fluorescence Experiments and Hidden Variables; D. Home and M. A. B. Whitaker, Physics Letters A 181, 114 (1993).
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