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Deepak Dhar
Deepak Dhar
Deepak Dhar
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Deepak Dhar (born 30 October 1951) is an Indian theoretical physicist known for his research on statistical physics and stochastic processes. In 2022, he became the first Indian to be awarded the Boltzmann Medal, the highest recognition in statistical physics awarded once every three years by IUPAP, for exceptional contributions to the subject.

Key Information

Dhar has been awarded the Padma Bhushan in 2023. Dhar is a winner of the TWAS prize and also an elected fellow of The World Academy of Sciences. The Council of Scientific and Industrial Research, the apex agency of the Government of India for scientific research, awarded Dhar the Shanti Swarup Bhatnagar Prize for Science and Technology, one of the highest Indian science awards, for his contributions to physical sciences in 1991.[1][note 1]. He is an elected fellow of all three major Indian science academies – Indian Academy of Sciences, Indian National Science Academy and National Academy of Sciences, India. Currently, he is INSA Distinguished Professor at the International Centre for Theoretical Sciences (ICTS-TIFR), Bengaluru.[2]

Biography

[edit]
University of Allahabad

Deepak was born on 30 October 1951 at Pratapgarh, in the north Indian state of Uttar Pradesh to Murli Dhar and Rama Gupta. Dhar graduated in science from the University of Allahabad in 1970 before earning a master's degree in physics from the Indian Institute of Technology, Kanpur in 1972.[3] Moving to the US, he enrolled for his doctoral studies under the guidance of Jon Mathews at California Institute of Technology, and after securing a PhD in 1978,[4] returned to India to start his career as a research fellow at Tata Institute of Fundamental Research (TIFR) the same year.[5] After two years of research, Dhar became a full-time fellow in 1980 and served in that position until 1986 when he was promoted as a reader. Before his superannuation from regular service, Dhar held various positions at TIFR, such as that of an associate professor (1991) and professor grades from G to J (1995–2008). In between, he had a one-year sabbatical at the University of Paris as a visiting scientist during 1984–85) and a month-long stint at Isaac Newton Institute in May 2006 as a Rothschild Professor. Post-retirement, Dhar served as a distinguished professor at the Indian Institute of Science Education and Research, Pune.[6] He is currently serving as a faculty at the International Centre for Theoretical Sciences (ICTS-TIFR), Bengaluru.[2]

Dhar is married to Manju and the couple has two children "NASI fellows". National Academy of Sciences, India. 2017. Archived from the original on 17 July 2015.

Legacy

[edit]
A computer-simulated realization of a Wiener or Brownian motion process (a continuous-time stochastic process) on the surface of a sphere

Focusing his studies on statistical physics and stochastic processes, Dhar has worked on the statistical mechanics and kinetics of random lattices and his work is reported to have widened our understanding of the disciplines.[7] He is credited with the introduction of spectral dimension concept in the studies of fractals and contributed to developing a methodology for determining their critical phenomena using real-space renormalization group techniques which was the first time the mathematical apparatus was used for calculations on nontrivial critical exponents on fractals.[5] Dhar worked with Ramakrishna Ramaswamy to solve the Abelian sandpile model of self-organized criticality[8] and developed a new model[9] which came to be known as Dhar-Ramaswamy model.[10] Working on directed-site animals-enumeration problem[11] using Bethe ansatz method, he proposed the evolution operator which has since been subjected to studies by other researchers as Dhar directed-site animals-enumeration problem.[12][13] Dhar also demonstrated the predominance of slow flipping of isolated unfrustrated clusters in auto-correlation functions and proposed models of metastable glassy states in stochastic evolution.[5] His studies have been documented by way of a number of articles[14][15][note 2] and the online article repository of Indian Academy of Sciences has listed 113 of them.[16]

Dhar is an associate editor of Journal of Statistical Physics, a Springer publication since 2005 where he sat in the editorial board on two previous terms (1993–96 and 1999–2002).[17] He is an editorial board member of the Indian Journal of Pure and Applied Physics (IJPAP) of the National Institute of Science Communication and Information Resources (NISCAIR),[18] a former editorial adviser to Physica A, an Elsevier science journal, and has been associated with journals such as Journal of Statistical Mechanics: Theory and Experiment, Physical Review E and Pramana as an editorial board member. He was a member of the Commission on Statistical Physics of the International Union of Pure and Applied Physics from 1992 to 1995[3] and is a member of the program committee of the International Centre for Theoretical Sciences.[19] Dhar has also delivered invited speeches and the special lecture on The Curious Relationship Between Physics and Mathematics at the University of Mumbai on 19 October 2016 was one among them.[20]

Awards and honors

[edit]

During his doctoral days at Caltech, Dhar held two institutional fellowships; E. P. Anthony fellowship (1972–73) and R. P. Feynman fellowship (1974–76).[3] He received the Young Scientist Medal of the Indian National Science Academy in 1983.[21] The Council of Scientific and Industrial Research awarded him the Shanti Swarup Bhatnagar Prize, one of the highest Indian science awards in 1991.[22] Two year's later, International Centre for Theoretical Physics selected him for the 1993 J. Robert Schrieffer Prize.[8] INSA honored Dhar again in 2001 with the Satyendranath Bose Medal[23] and he received the TWAS Prize of The World Academy of Sciences in 2002.[24]

Dhar was elected as a fellow by the Indian Academy of Sciences in 1990 where he is a sitting council member.[25] He became an elected fellow of the Indian National Science Academy on 1995[26] and the National Academy of Sciences, India elected him as a fellow in 1999.[27] Dhar received the elected fellowship of the World Academy of Sciences in 2006[28] and was selected for the J. C. Bose National fellowship of the Science and Engineering Research Board in 2007, with the tenure running until 2017.[3]

Dhar has been chosen for the prestigious Boltzmann Medal award for the year 2022 and becomes the first Indian to receive the honor.[29] It is bestowed upon a scientist with exceptional contributions in the field of statistical physics, every three year. Dhar shares his prize with John Hopfield.[29] He received the 2023 Padma Bhushan, the third highest civilian award by Government of India.[30]

Selected bibliography

[edit]

See also

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Notes

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References

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[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Deepak Dhar

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from Grokipedia
Deepak Dhar (born 30 October 1951) is an Indian theoretical renowned for his foundational contributions to statistical physics and stochastic processes. Born in , he earned a B.Sc. from the in 1970, an M.Sc. in physics from in 1972, and a Ph.D. from the in 1978. His career spans over four decades, primarily at the (TIFR) in , where he joined as a in 1978 and served as faculty until his retirement in 2016, contributing to the development of the TIFR school of statistical physics alongside colleagues like Mustansir Barma. Post-retirement, he holds positions as a at the International Centre for Theoretical Sciences (ICTS-TIFR) in Bengaluru and as Distinguished Emeritus Professor at the Indian Institute of Science Education and Research (IISER) . Dhar's research has profoundly influenced the understanding of complex systems through exact solutions and theoretical models, emphasizing the of intricate behaviors from simple rules. Key areas include studies of on fractals, enumeration of directed branched polymers and animals (with applications to molecular structures), the of (which models phenomena like earthquakes and financial crashes), slow relaxation in disordered magnets, and dynamics of and super-cooled liquids. His work on the sandpile model, solved in 1990, provided an exact framework for , while contributions to have informed clinical applications in cancer . Dhar's approach, blending theoretical rigor with interdisciplinary applications, underscores his belief in curiosity-driven , as reflected in his editorial roles, including Associate Editor of the Journal of Statistical Physics since 2005. His achievements have earned widespread recognition, including the Prize in Physical Sciences in 1991, the TWAS Prize in Physics in 2002, the in 2022 (as the first Indian recipient), and the , India's third-highest civilian honor, in 2023. Dhar is an elected of the , Indian National Science Academy, , India, and (TWAS), and he served on the International Union of Pure and Applied Physics (IUPAP) Commission on Statistical Physics from 1992 to 1995.

Early Life and Education

Birth and Family Background

Deepak Dhar was born on October 30, 1951, in , , to Murli Dhar, an officer in the government judicial service, and Rama Gupta. His father later served as a judge at the and as president of the Bar Association. Dhar grew up in a middle-class family that was not particularly privileged but faced no major hardships, with a strong emphasis on as a pathway to stability. His father's career in the judicial service necessitated frequent transfers, leading the family to relocate across several small towns in , including , , , and Gonda, after their initial time in Pratapgarh. This nomadic lifestyle meant adapting to new schools every two to three years, fostering resilience and a broad exposure to diverse local environments in the region. Dhar's early interest in science was nurtured through family influences, particularly his father's habit of bringing home popular science magazines such as Understanding Science, which sparked his curiosity despite initial challenges as a Hindi-medium student encountering English-language content. These readings, combined with discussions in the household, introduced him to scientific concepts and encouraged a questioning mindset. In school, he consistently ranked at the top of his class, and a formative experience came during a summer program at , where hands-on encounters with computer punch cards and interactions with like-minded peers further ignited his passion for physics. This early grounding in Uttar Pradesh's educational landscape paved the way for his transition to higher studies at the .

Academic Training

Deepak Dhar earned his degree from the in 1970. He subsequently pursued a in Physics at the Indian Institute of Technology Kanpur, completing the degree in 1972. Dhar then traveled to the for doctoral studies, obtaining his PhD in Physics from the in 1978; his thesis examined topics in , with a focus on techniques applied to . At Caltech, Dhar worked under the supervision of Professor Jon Mathews, who encouraged his exploration of problems. He also benefited from interactions with leading figures in the field, including serving as a teaching assistant to Nobel laureate and receiving the R. P. Feynman Fellowship from 1974 to 1976. During his graduate years, Dhar engaged in early research projects on lattice models and in statistical systems, laying the groundwork for his later contributions. Hailing from , Dhar's academic path was shaped by a family background that prioritized scientific .

Professional Career

Early Positions at TIFR

Upon completing his PhD at the in 1978, Deepak Dhar returned to and joined the (TIFR) in as a Visiting Fellow in the Department of . This initial research fellowship marked the beginning of his long tenure at TIFR, where he focused on theoretical work in statistical physics. In 1980, Dhar transitioned to a full-time position, which he held until , allowing him to establish his research program. During this early phase, he initiated studies in on random lattices, exemplified by his seminal paper on self-avoiding random walks on exactly soluble lattices, published in the Journal of Mathematical Physics in 1978. He progressed through the academic ranks at TIFR, becoming Reader from to 1991, Associate from 1991 to 1995, and Professor starting in 1995. Dhar took a one-year sabbatical as a visiting at the from 1984 to 1985, an experience that facilitated international collaborations and enriched his approach to processes in disordered systems. As part of his faculty responsibilities at TIFR during this period, he supervised graduate students and contributed to teaching advanced courses in , fostering the next generation of researchers in the field.

Later Roles and Affiliations

After nearly four decades at the Tata Institute of Fundamental Research (TIFR) in Mumbai, where he served from 1978 to 2016, Deepak Dhar retired from his regular faculty position in 2016. Following his retirement from TIFR, Dhar joined the Indian Institute of Science Education and Research (IISER) Pune in November 2016 as a Distinguished Visiting Professor in the Department of Physics. He continued at IISER Pune as a Distinguished Visiting Professor until 2024 and was later appointed Distinguished Professor Emeritus (as of 2023), alongside holding the position of NASI Senior Scientist. Currently, Dhar serves as INSA Distinguished Professor in the Statistical Physics group at the International Centre for Theoretical Sciences (ICTS-TIFR), Bengaluru, maintaining his ongoing association with TIFR through this role. In addition to his academic positions, Dhar has served as Associate Editor for the Journal of Statistical Physics since 2005 and is a member of the editorial board of the Journal of Statistical Mechanics: Theory and Experiment, contributing to the peer review process in statistical physics.

Research Contributions

Fractals and Spectral Dimension

In the early 1980s, Deepak Dhar made significant contributions to the application of geometry in physics, particularly in understanding the structural and dynamic properties of disordered systems at the (TIFR). His work focused on how fractal structures emerge in physical contexts such as and growth processes, providing tools to characterize their scaling behaviors beyond traditional Euclidean dimensions. Fractals in physics describe irregular, self-similar structures that appear in phenomena like clusters and , where standard fails due to . Dhar's investigations during this period highlighted the need for multiple dimensional descriptors to capture both geometric and dynamic aspects of these systems. The spectral dimension dsd_s serves as a measure of processes on fractals, quantifying how the probability of a random walker returning to the origin scales with time, P(t)tds/2P(t) \sim t^{-d_s/2}. Unlike the dfd_f, which describes the scaling of mass with size (MrdfM \sim r^{d_f}), the spectral dimension probes the efficiency of and vibration modes on the fractal substrate. Dhar derived this concept by analyzing the for vibrational excitations, or equivalently, the return probabilities in random walks, showing that dsd_s remains invariant under embedding dimensions for a given fractal topology. This distinction is crucial for fractals where geometric and diffusive scalings decouple, leading to non-classical behaviors. A pivotal contribution came in Dhar's 1985 paper on classical diffusion on Eden trees, where he applied spectral dimension to tree-like fractal structures relevant to growth models and clusters. Using simulations on square and cubic lattices, he computed dsd_s for Eden trees, finding values of approximately 1.22 in two dimensions and 1.30 in three dimensions. This work supported the broader application of spectral dimension to characterize in such systems, with relevance to the Alexander-Orbach predicting ds4/3d_s \approx 4/3 for clusters. Dhar extended these ideas to random lattices, such as percolation networks and Eden growth models, which mimic the backbone of infinite clusters near criticality. In these systems, the spectral dimension governs the long-time decay of correlations in diffusion, implying slower spreading than in Euclidean spaces. For instance, on percolation clusters, the implications include subdiffusive transport where the mean squared displacement scales as r2(t)t2/dw\langle r^2(t) \rangle \sim t^{2/d_w} with dw>2d_w > 2, leading to enhanced trapping and reduced conductivity compared to bulk materials. These findings have broad applications in modeling porous media and disordered conductors. The mathematical framework for spectral dimension relates it to the fractal dimension dfd_f and the walk dimension dwd_w through the formula ds=2dfdwd_s = \frac{2 d_f}{d_w}, where dwd_w captures the anomalous scaling of diffusion paths (r2t2/dw\langle r^2 \rangle \sim t^{2/d_w}). This relation arises from the scaling of the resistance or diffusion kernel on the fractal graph. For the deterministic Sierpinski gasket, a canonical fractal with df=ln3ln21.585d_f = \frac{\ln 3}{\ln 2} \approx 1.585, Dhar calculated dw=ln5ln22.322d_w = \frac{\ln 5}{\ln 2} \approx 2.322 using spectral decimation techniques, yielding ds1.365d_s \approx 1.365. This example illustrates how ds<2d_s < 2 implies recurrent random walks and logarithmic divergences in return probabilities, distinguishing fractal dynamics from regular lattices.

Sandpile Models and Criticality

Deepak Dhar, in collaboration with Ramakrishna Ramaswamy, introduced a directed variant of the in 1989 as a cellular automaton designed to study avalanche dynamics in driven dissipative systems. The model simulates sand grains added randomly to sites on a lattice, where each site holds up to a critical height; exceeding this threshold causes a toppling event, redistributing grains to neighboring sites and potentially triggering further topplings in a cascade or avalanche. This setup captures the essence of self-organized systems evolving toward a critical state without external parameter tuning. A pivotal breakthrough was Dhar's proof of the model's Abelian property, demonstrating that the order of toppling events is commutative, meaning the final stable configuration after an avalanche is independent of the sequence in which unstable sites topple. This commutativity arises because toppling operators at different sites commute under the model's rules, forming an Abelian group structure that renders the dynamics invertible and allows exact enumeration of stable states. Consequently, the model becomes analytically tractable, enabling precise calculations of probabilities and correlations that were previously inaccessible in similar nonequilibrium systems. Dhar's work established strong connections between the Abelian sandpile and the concept of self-organized criticality (SOC), originally proposed by Per Bak, Chao Tang, and Kurt Wiesenfeld in 1987. Unlike the isotropic BTW sandpile, Dhar and Ramaswamy's directed variant exhibits SOC with power-law avalanche statistics and long-range correlations, mirroring natural phenomena like earthquakes or neuronal firing. The model's recurrent configurations form a uniform measure over stable states, naturally driving the system to criticality through slow driving and fast dissipation. The Dhar-Ramaswamy model extends the framework to driven diffusive systems, incorporating directed transport and stochastic elements to model realistic nonequilibrium processes such as particle flow in biased fields. Key results include the emergence of fractal patterns in the stable configurations, where the boundaries of piled regions exhibit self-similar structures akin to . Avalanche sizes and durations follow power-law distributions, with exponents calculable exactly in low dimensions; for instance, in two dimensions, the survival probability of avalanches decays as P(t>t0)t01P(t > t_0) \sim t_0^{-1}. Further analytical advances by Dhar provided explicit expressions for toppling probabilities and height correlations. The probability that a site topples during relaxation from a given initial configuration is given by the normalized form G0(X;Y)=T(X)!iXi!G_0(\mathbf{X}; \mathbf{Y}) = \frac{T(\mathbf{X})!}{\prod_i X_i!}, where T(X)T(\mathbf{X}) is the total number of topplings, valid for non-negative integer vectors and zero otherwise. Height-height correlations in the scale logarithmically in three dimensions and as a in two dimensions, F(r)r1αF(r) \sim r^{1-\alpha} with α=1\alpha = 1, underscoring the critical nature of the configurations. These findings highlight the model's utility in probing universal aspects of SOC across dimensions.

Stochastic Processes and Kinetics

Deepak Dhar made significant contributions to the study of stochastic processes on random lattices, particularly focusing on the dynamics of random walks in heterogeneous environments. In collaboration with Mustansir Barma, he investigated biased diffusion on one-dimensional percolation models, where particles experience trapping due to site disorder, leading to anomalous drift velocities and distributions that deviate from Gaussian behavior. This work highlighted how quenched randomness in transition rates alters the long-time transport properties, with the effective velocity scaling as v(ppc)μv \sim (p - p_c)^\mu near the pcp_c, where μ\mu depends on the bias strength. A key aspect of Dhar's research involved trapping models, where random walkers encounter sites with varying trapping times, modeling kinetics in disordered media such as porous materials. In these models, the survival probability of a walker decays non-exponentially, often following a power-law tail S(t)tθS(t) \sim t^{-\theta}, with the exponent θ\theta determined by the distribution of trap depths. Dhar extended these ideas to low-dimensional systems, developing numerical methods like exact enumeration of paths to solve for mean first-passage times on finite lattices, providing benchmarks for anomalous diffusion exponents in heterogeneous settings. Dhar's work on kinetics emphasized the framework adapted for random lattices and , accounting for spatial heterogeneity in transition rates. The of the probability Pi(t)P_i(t) at site ii is governed by dPidt=j(WjiPjWijPi),\frac{dP_i}{dt} = \sum_j \left( W_{ji} P_j - W_{ij} P_i \right), where WijW_{ij} are site- and bond-dependent rates, introducing non-uniformity that leads to subdiffusive behavior on fractal supports. In the and , he applied this to reaction kinetics, such as deposition-evaporation processes on random networks, revealing conserved quantities and phase transitions driven by disorder. In the realm of phase transitions in disordered systems, Dhar explored how stochastic dynamics lead to multiple universality classes, particularly in interface growth models with quenched noise. His analyses showed that dynamic phase transitions occur via absorbing states, with varying across disorder strengths, as seen in one-dimensional kinetic Ising models under oscillating fields. Dhar also advanced understanding of probabilities in random media through studies of stationary stochastic processes. In a 2001 paper with Satya N. Majumdar, he derived exact persistence exponents for moving-average processes in heterogeneous noise, where the probability that a signal remains positive up to time tt scales as tθt^{-\theta}, with θ\theta depending on the correlation structure of the medium. These results provided insights into non-Markovian dynamics relevant to in disordered environments. As an example of broader stochastic dynamics, Dhar's sandpile models illustrate criticality in such systems, though his primary focus remained on general kinetic theories.

Branched Polymers and Animals

Dhar contributed to the enumeration of directed branched polymers and lattice animals, providing exact solutions and scaling relations with applications to molecular structures and . His work on fractals extended to these objects, analyzing their connectivity and growth on various lattices.

Disordered Magnets and Relaxation

Dhar studied slow relaxation dynamics in disordered magnets, exploring glassy behavior and aging phenomena through theoretical models of spin glasses and systems. These investigations revealed universal features in non-equilibrium relaxation, connecting to broader themes in complex systems.

Protein Folding and Super-Cooled Liquids

In later work, Dhar applied processes to the dynamics of and super-cooled liquids, modeling kinetic pathways and glass transitions using techniques and numerical simulations. This interdisciplinary approach highlighted emergent behaviors in biophysical and systems.

Electroporation

Dhar's contributions to models have informed understanding of permeabilization, with implications for clinical applications in targeted cancer by enhancing cellular uptake mechanisms.

Awards and Honors

National Recognitions

In 1983, Deepak Dhar received the INSA Young Scientist Medal from the Indian National Science Academy for his early contributions to . Deepak Dhar received the Prize for Science and Technology in 1991, awarded by the Council of Scientific and Industrial Research (CSIR) for his pioneering contributions to , particularly in areas like fractals and . This prestigious national award, often regarded as India's highest honor for young scientists under 45, recognizes exceptional research impact and has propelled recipients to leadership roles in the country's scientific community. In 2001, Dhar was awarded the Satyendranath Bose Medal by the Indian National Science Academy for his outstanding research in physical sciences. In 2023, Dhar was conferred the , one of India's highest civilian honors, by the in the field of science and engineering, acknowledging his lifelong dedication to and its applications. The award highlights his role in elevating Indian statistical physics on the global stage, reflecting the government's recognition of scientists who bridge fundamental research with national innovation priorities. Dhar has been elected as a of the Indian National Science Academy (INSA) in 1995, the in 1990, and the National Academy of Sciences, India (NASI) in 1999, underscoring his sustained influence within India's premier scientific bodies. These fellowships, which honor outstanding contributions to science, have enabled him to mentor generations of researchers and shape policy through academy initiatives. Additionally, in 2022, Dhar was honored with the Distinguished Alumnus Award for his exemplary achievements in physics, celebrating his journey from an alumnus of the institute to a globally respected theorist. This recognition emphasizes the role of premier engineering institutions in nurturing India's scientific talent and their contributions to national progress.

International Accolades

Deepak Dhar received the in 2022 from the International Union of Pure and (IUPAP), shared with John J. Hopfield, recognizing his lifetime contributions to statistical physics, including foundational work on fractals, , and exactly solved models. This marked the first time an Indian physicist was awarded this prestigious honor, often regarded as the highest accolade in the field, highlighting Dhar's global influence beyond national boundaries. In 2002, Dhar was awarded the TWAS Prize in Physics by (TWAS) for his pioneering research on exactly solvable models in and applications to fractals and disordered systems. He was elected a Fellow of TWAS in 2006, further affirming his stature among developing world scientists for advancing . Earlier, in 1993, Dhar earned the ICTP Prize in honor of J. Robert Schrieffer from the (ICTP) for outstanding contributions to understanding complex physical problems involving geometry, numerical methods, dynamics, and . Dhar has also held significant editorial roles in international journals, serving as an associate editor of the Journal of Statistical Physics (Springer) since 2005 and as a member of the editorial board of the Journal of Statistical Mechanics: Theory and Experiment (). These positions underscore his role in shaping global discourse in statistical physics.

Legacy and Personal Life

Influence on Physics Community

Deepak Dhar has significantly influenced the physics community through his mentorship of numerous PhD students and postdocs during his tenure at the (TIFR) and as a distinguished visiting professor at the Indian Institute of Science Education and Research (IISER) . He supervised theses such as those of Tridib , who explored non-equilibrium statistical physics and later contributed to processes research, and Rahul Dandekar, whose work focused on related models in . These alumni, along with others, have gone on to hold leading positions in academia and research, extending Dhar's ideas in statistical physics and inspiring a generation of Indian physicists to pursue theoretical work in complex systems. Dhar's foundational contributions to (SOC), particularly through his development of the , have had lasting impact, with his seminal papers cited extensively in modern applications. For instance, his 1990 paper on the self-organized critical state of sandpile automaton models has garnered over 1,300 citations and influenced studies modeling earthquakes as SOC phenomena, where avalanches mimic seismic events. Similarly, extensions of his work appear in , analyzing criticality in interconnected systems like social or biological networks, demonstrating the model's versatility beyond original contexts. His 2006 review on theoretical studies of SOC, with 411 citations, continues to serve as a pedagogical for researchers exploring these dynamics. Throughout his career, Dhar authored 114 peer-reviewed articles, achieving an of 47 and over 9,125 total citations, metrics that underscore his high-impact scholarship in statistical physics. These figures reflect the broad adoption of his methods in , fractals, and stochastic kinetics, with his work frequently referenced in interdisciplinary fields. As an elected fellow of the Indian National Science Academy (INSA) and through roles like NASI Senior Scientist, Dhar contributed to Indian by mentoring young researchers and participating in academic programs at IISER , fostering a rigorous approach to theoretical inquiry. Dhar's receipt of the 2022 Boltzmann Medal marked him as the first Indian recipient of this prestigious award, the highest honor in statistical physics, serving as profound inspiration for young scientists in and beyond. This milestone highlighted the global recognition of Indian contributions to the field and encouraged aspiring physicists to tackle challenging problems in complex systems, amplifying his legacy as a pioneer who bridged theoretical innovation with educational outreach.

Family and Personal Details

Deepak Dhar is married to Manju Dhar, with whom he has shared a supportive partnership throughout his professional journey. The couple has two daughters, and Dhar has publicly acknowledged the emotional backing from his family, which has been instrumental in sustaining his dedication to research. In interviews, Dhar has highlighted the intrinsic rewards of scientific inquiry, stating that "science is a very exciting journey" where the joy derives from the process of discovery rather than immediate applications. His personal interests reflect a appreciation for , including views and leisurely drives with friends, which he enjoyed during his time in and continues to value as a northerner by origin. Dhar maintains residences connected to his later academic roles, primarily in as at the Indian Institute of Science Education and Research (IISER), while also holding an affiliation with the International Centre for Theoretical Sciences in Bengaluru. As of November 2025, at age 74, he remains active and in good standing within the physics community.

References

  1. https://www.springernature.com/gp/deepak-dhar/23289950
  2. https://iitk.ac.in/dora/profile/Prof-Deepak-Dhar
  3. https://theprint.in/science/how-a-theoretical-physicists-passionate-approach-to-simple-math-got-him-the-padma-bhushan/1341209/
  4. https://www.icts.res.in/people/deepak-dhar
  5. https://www.iiserpune.ac.in/storage/media-library/c1451a86-fecd-40e7-9056-eb15f8cd472d.pdf
  6. https://www.hindustantimes.com/cities/lucknow-news/au-alumnus-selected-for-boltzmann-medal-101646847820196.html
  7. https://prabook.com/web/deepak.dhar/521306
  8. https://www.globalindian.com/story/cover-story/meet-dr-deepak-dhar-the-first-indian-physicist-to-win-a-boltzmann-medal/
  9. https://iitk.ac.in/dora/blog/prof-deepak-dhar
  10. https://www.tifr.res.in/docs/detailed_information.pdf
  11. https://thesis.library.caltech.edu/view/author/Dhar-Deepak.html
  12. https://www.iiserpune.ac.in/news/post/felicitation-of-padma-awardees/565
  13. https://www.yumpu.com/en/document/view/38323074/curriculum-vitae-of-deepak-dhar-theoretical-physics-tifr-tata-
  14. https://www.dailyexcelsior.com/padma-awardees-in-science-engineering/
  15. https://www.tifr.res.in/~ipa1970/news/V53-3/Vol53-3.pdf
  16. https://indianexpress.com/article/cities/bangalore/professor-deepak-dhar-iiser-tifr-republic-day-840495/
  17. https://www.iiserpune.ac.in/news/post/prof-deepak-dhar-to-be-conferred-boltzmann-medal/272
  18. https://www.icts.res.in/people/faculty
  19. https://iopscience.iop.org/journal/1742-5468/page/editorial_board
  20. https://theory.tifr.res.in/Research/AnnRep/publs_subj.pdf
  21. https://www.researchgate.net/publication/285315267_Fractals
  22. https://link.aps.org/doi/10.1103/PhysRevLett.54.1346
  23. https://link.aps.org/doi/10.1103/PhysRevLett.50.135
  24. https://iopscience.iop.org/article/10.1088/0305-4470/21/9/007
  25. https://doi.org/10.1103/PhysRevLett.63.1659
  26. https://iopscience.iop.org/article/10.1088/0022-3719/16/8/013
  27. https://arxiv.org/abs/cond-mat/9704026
  28. http://repository.ias.ac.in/9388/1/389.pdf
  29. https://doi.org/10.1103/PhysRevE.64.046123
  30. https://ssbprize.gov.in/content/Detail.aspx?AID=182
  31. https://www.pib.gov.in/PressReleaseIframePage.aspx?PRID=1914038
  32. https://insajournal.in/intranetinsa/fellow_detail.php?id=N95-1172
  33. https://fellows.ias.ac.in/profile/v/FL1990006
  34. https://nasi.org.in/fellows/dhar-deepak/
  35. https://iitk.ac.in/dora/da-award
  36. https://iitkalumni.org/daa
  37. https://statphys28.org/boltzmannmedal.html
  38. https://www.tifr.res.in/docs/Deepak.pdf
  39. https://twas.org/recipients-twas-awards-and-prizes
  40. https://twas.org/directory/dhar-deepak
  41. https://www.ictp.it/home/ictp-prize-winner-1993
  42. https://link.springer.com/journal/10955/updates/20270270
  43. https://theory.tifr.res.in/Research/Thesis/Tridib_thesis.pdf
  44. https://theory.tifr.res.in/Research/Thesis/Dandekar_Rahul1.pdf
  45. https://scholar.google.com/citations?user=dl1wQfwAAAAJ&hl=en
  46. https://link.aps.org/doi/10.1103/PhysRevLett.64.1613
  47. https://iopscience.iop.org/article/10.1088/1742-6596/1298/1/012007/pdf
  48. https://www.psa.gov.in/article/india-focus-prof-deepak-dhar-honoured-boltzmann-medal/4219
  49. https://www.thehindu.com/sci-tech/science/deepak-dhar-and-john-j-hopfield-chosen-for-the-boltzmann-medal/article65192794.ece
  50. https://www.iiserpune.ac.in/
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