Physical Review Letters
Physical Review Letters (PRL) is the flagship peer-reviewed scientific journal of the American Physical Society (APS), dedicated to the rapid publication of short, high-quality reports on significant advances in all areas of physics, including fundamental, applied, and interdisciplinary research.[1] Launched in 1958, PRL serves as the world's premier physics letters journal, emphasizing transformative ideas and influential developments that advance the understanding of physical phenomena across subfields such as quantum information, cosmology, condensed matter, and beyond.[1] The journal publishes articles electronically on a rolling basis, with a traditional weekly issuance schedule established since 1964, ensuring timely dissemination of cutting-edge research to the global physics community.[2] With a 2024 Journal Impact Factor of 9.0 and a CiteScore of 15.6, PRL maintains exceptional visibility and influence, as evidenced by its h5-index of 201 and total citations exceeding 518,000.[1] Over its history, the journal has featured numerous groundbreaking papers that contributed to Nobel Prizes, including the 1962 discovery of the muon neutrino, the 1982 invention of the scanning tunneling microscope, and the 1995 observation of Bose-Einstein condensation, underscoring its role in shaping modern physics.[3]Overview
Publication Details
Physical Review Letters (PRL) was founded in 1958 by the American Physical Society (APS), a non-profit membership organization dedicated to advancing and sharing physics knowledge worldwide.[4][1] As the flagship journal of APS, PRL is published weekly, issuing 52 issues per year, and is available in both print and digital formats through the APS website.[5][6] It operates as a peer-reviewed publication emphasizing concise reporting, with a strict limit of four journal pages per article to ensure broad accessibility and focus on significant advancements.[7] PRL receives approximately 14,000 manuscript submissions each year and maintains a selective acceptance rate of around 25%, reflecting its rigorous standards for influential physics research.[1] The journal's identifiers include ISSN 0031-9007 for the print edition and 1079-7114 for the online edition.[6]Editorial Process
The editorial process for Physical Review Letters (PRL) employs a single-anonymous peer review model, in which reviewers are aware of the authors' identities but remain anonymous to them, ensuring rigorous evaluation while maintaining confidentiality.[8] Manuscripts deemed potentially suitable by editors are sent for external review, typically involving two or more referees selected for their expertise; the process emphasizes rapid assessment, with an average turnaround of 6-8 weeks from submission to initial decision.[9][10] This expedited timeline supports PRL's goal of disseminating timely, high-impact physics results, and editors may accelerate reviews for particularly groundbreaking submissions.[1] The editorial board comprises active researchers from diverse physics subfields, serving as Divisional Associate Editors appointed for three-year terms by the Lead Editor to oversee specific areas and advise on manuscript handling.[1] As of 2025, the Lead Editor is Rafael Fernandes, who provides strategic direction alongside a rotating leadership structure that includes senior editors to maintain impartiality and expertise across disciplines.[11] Acceptance hinges on criteria such as novelty, broad interest to the physics community, clarity of presentation, and potential impact, with rejections frequently stemming from insufficient significance or broad appeal rather than technical errors.[1][8] PRL enforces strict submission policies to promote conciseness, including a maximum length of four journal pages for the core content (approximately 3,750 words), with up to two additional pages permitted for end matter such as appendices targeted at specialists.[9] Submissions must use the REVTeX 4.2 LaTeX system to ensure consistent formatting, and no supplemental materials beyond the specified end matter are allowed in the main article to uphold the journal's focus on brevity.[7] For controversial topics that challenge established paradigms, editors apply additional scrutiny, including careful referee selection and requirements for detailed methodological descriptions to facilitate reproducibility, aligning with the American Physical Society's overarching standards for scientific integrity.[12][8]History
Establishment and Development
Physical Review Letters (PRL) emerged as a dedicated outlet for rapid publication within the American Physical Society's (APS) portfolio, building on the foundation of The Physical Review, which was established in 1893 by Edward L. Nichols at Cornell University to foster the dissemination of physics knowledge in the United States.[4] By the mid-1950s, The Physical Review was overwhelmed by a surge in submissions, particularly short reports on urgent developments that demanded quick turnaround times, a trend amplified by the post-World War II expansion of physics research funded by government initiatives.[13] In response, APS launched PRL in July 1958 under the editorship of Samuel A. Goudsmit, the then-editor of The Physical Review, with the explicit motivation to separate concise "letters" from longer articles, thereby allowing The Physical Review to focus on comprehensive papers while PRL prioritized high-impact, brief communications limited to about 600 words.[14][15] Goudsmit's vision positioned PRL as an "experiment" in physics publishing, initially concentrating on nuclear and particle physics amid the postwar boom driven by accelerator developments and atomic energy programs.[2] George L. Trigg joined as assistant editor in 1958 and succeeded Goudsmit as editor from 1969 to 1988, overseeing the journal's operational maturation during its formative years.[15] Under their leadership, PRL became a weekly publication by 1964 to meet rising demand, reflecting the Cold War-era acceleration in fundamental research supported by institutions like Brookhaven National Laboratory, where the editorial office was based.[2] During the 1960s and 1970s, PRL broadened its scope beyond nuclear and particle physics to encompass condensed matter physics and astrophysics, accommodating the diversification of the field as solid-state research gained prominence through semiconductor advancements and early space observations. This expansion paralleled substantial growth in readership, underscoring PRL's role as a central hub for global physics discourse.[2] Institutionally, PRL was sustained primarily through APS membership dues and journal subscriptions, enabling it to effectively distribute critical advances in physics amid the geopolitical and scientific imperatives of the Cold War period without reliance on external grants for core operations.[4] Subsequent editors, including Gene D. Sprouse (1988–2010) and Michael Thoennessen (2010–present), continued to guide PRL's evolution.Key Milestones
In 2008, Physical Review Letters marked its 50th anniversary with a comprehensive retrospective organized by the American Physical Society (APS), which highlighted 50 influential articles from the journal's history, spanning breakthroughs in particle physics, condensed matter, and beyond. This celebration underscored PRL's role in advancing rapid dissemination of significant research and coincided with the launch of enhanced digital archives, making the full corpus of past issues freely accessible online to facilitate historical analysis and education.[3][2] The late 1990s brought transformative changes in publishing workflows, as APS pioneered electronic dissemination for PRL, with the first online publication appearing on July 1, 1995, and the introduction of online submission systems that streamlined the process and diminished reliance on physical manuscripts and print production. Building on this digital foundation, open access initiatives emerged in the mid-2000s; APS implemented a hybrid model allowing authors to opt for immediate open access by paying an article processing charge, expanding to PRL and other journals by 2006. Further, since 2014, high-energy physics articles in PRL have been published under a full open access model through the SCOAP³ consortium, sponsored by international funding agencies to cover costs and ensure free global access without author fees.[2][16] Adapting to the digital era, PRL incorporated multimedia supplements in the 2010s, enabling authors to include videos, animations, and interactive datasets alongside traditional text to better convey complex phenomena, such as quantum simulations or fluid dynamics. In the 2020s, responding to broader scientific concerns over reproducibility, APS mandated data availability statements for all PRL submissions, promoting transparent sharing of underlying datasets via repositories to verify results and foster collaboration. As of 2025, there is a heightened emphasis on interdisciplinary research, exemplified by expanded coverage of quantum computing applications across physics subfields.[17][8]Scope and Content
Covered Topics
Physical Review Letters (PRL) encompasses the full spectrum of physics research, serving as the flagship journal for all branches of the discipline. Its core areas include general physics, such as statistical and quantum mechanics, classical mechanics, and mathematical physics; atomic, molecular, and optical physics; condensed matter physics; nuclear physics; particles and fields; gravitation, cosmology, and astrophysics; and nonlinear dynamics and complex systems.[18] This broad coverage ensures that PRL addresses fundamental questions across theoretical and experimental domains, drawing from the comprehensive scope of the Physical Review journals portfolio.[19] The journal emphasizes results with broad impact and significance, prioritizing papers that advance new ideas or methods, report findings with immediate relevance to fundamental principles, or represent significant progress in key research areas.[20] It excludes routine applications, incremental advancements, and work focused primarily on applied engineering rather than fundamental physics. Additionally, PRL does not publish pure mathematics, biology, or chemistry unless these are inextricably linked to central physics questions, and it avoids conference proceedings or non-original content.[21] Since the 1990s, PRL has expanded its interdisciplinary overlap, increasingly incorporating topics at the interfaces of physics with other fields, such as biophysics, quantum information science, and materials science. These areas reflect growing synergies, where physical principles drive innovations in biological systems, quantum technologies, and advanced materials.[22] For instance, quantum information contributions now highlight transformative ideas in computation and communication, while biophysics papers explore physical mechanisms in living systems. Historically, PRL's topical focus has evolved in line with broader trends in physics. In the 1960s, publications were dominated by elementary particle physics, reflecting the era's excitement around high-energy discoveries. By the 1980s and onward, there was a notable shift toward condensed matter physics, which has since become a leading category, underscoring the journal's responsiveness to the field's dynamic priorities.[23] This evolution maintains PRL's role in disseminating vital, current research to a wide physics audience.[20]Article Formats and Policies
Physical Review Letters (PRL) imposes strict length limits to ensure concise communication of significant research, with Letters limited to a maximum of 3750 words, equivalent to approximately four journal pages for the core content between the abstract and acknowledgments.[9] This structure typically includes a self-contained abstract of no more than 600 characters (roughly 100 words), the main text, end matter such as figure captions, tables, and references (generally up to 25 to fit within the word count), and no more than two pages of optional end matter like appendices.[9] [24] Figures and tables are incorporated into the word count, with each figure counting as 170 words, effectively limiting their total space to avoid exceeding half the article's allocation while maintaining focus on textual explanation.[25] PRL adheres to the American Physical Society's (APS) comprehensive ethics guidelines, which emphasize integrity, transparency, and fairness in scientific publishing.[26] Authors must disclose any potential conflicts of interest, such as financial or personal relationships that could influence the work, at the time of submission.[8] Since 2017, PRL has required a data availability statement in every article, explaining how underlying data can be accessed, shared, or reproduced; this policy was refreshed in 2024 to further strengthen commitments to transparent research, with phased implementation starting September 2024.[27] Figure policies prioritize clarity and quality, mandating high-resolution submissions at 600 dpi or higher to ensure accurate reproduction in both print and digital formats.[28] Supplementary materials are permitted exclusively for online publication and must contain only non-essential information, such as extended datasets, multimedia files, or additional analyses that do not alter the main article's conclusions; they cannot be used to circumvent length limits.[17] Authorship in PRL follows APS criteria, requiring that all listed authors have made substantial intellectual contributions to the conception, design, analysis, or interpretation of the research, and have approved the final manuscript.[8] The corresponding author bears primary responsibility for ensuring the accuracy of the submission, handling communications with the journal, and verifying compliance with all policies, including post-publication corrections if needed. To enhance reproducibility, PRL's policies encourage deposition of code, data, and materials in public repositories such as Zenodo, with stronger requirements for computational or data-intensive work following the 2024 data availability policy refresh.[8] These guidelines align submissions with PRL's scope in physics, promoting rapid dissemination while upholding rigorous standards.[1]Impact and Recognition
Citation Metrics
Physical Review Letters (PRL) maintains a strong position in citation metrics, reflecting its influence in the physics community. The journal's 2024 Journal Impact Factor, as reported in the Journal Citation Reports by Clarivate Analytics, is 9.0, an increase from 8.1 in 2023, following a peak of 9.185 in 2021 and 8.6 in 2022.[1][29][30] This trend underscores PRL's sustained high impact amid evolving publication volumes and citation patterns in physics. Additional metrics further highlight PRL's prestige. Its h5-index, calculated by Google Scholar for articles published between 2020 and 2024, is 201, indicating that 201 papers from this period each received at least 201 citations.[31] The CiteScore, from Scopus data, is 15.6, measuring average citations over a four-year window.[1] The SCImago Journal Rank (SJR) for 2024 is 2.856, positioning PRL in the Q1 quartile for physics and astronomy (miscellaneous) and multidisciplinary physics categories.[18] In global rankings, PRL holds the 785th position overall according to SCImago's 2024 data, while topping multidisciplinary physics subfields.[32] The journal has amassed over 518,000 total citations across its publications, with older articles averaging approximately 200 citations each, demonstrating long-term relevance.[1][33] Comparatively, PRL consistently ranks among the top five physics journals worldwide, often leading in breadth of coverage compared to more specialized outlets like Nature Physics.[34][31] This broad influence is evident in its h5-index supremacy in physics and mathematics categories per Google Scholar metrics.[31]| Metric | Value | Source (Year) |
|---|---|---|
| Impact Factor | 9.0 | Clarivate JCR (2024) |
| h5-index | 201 | Google Scholar (2024) |
| CiteScore | 15.6 | Scopus (2024) |
| SJR | 2.856 | SCImago (2024) |
| Overall Rank | 785 | SCImago (2024) |
| Total Citations | 518,699 | APS (2024) |