ACS Applied Materials & Interfaces
ACS Applied Materials & Interfaces is a peer-reviewed, interdisciplinary scientific journal published weekly by the American Chemical Society (ACS), dedicated to the development and application of advanced materials and interfacial processes for practical uses across fields such as biology, medicine, energy, environment, catalysis, and electronics.[1] It serves chemists, engineers, physicists, and biologists by emphasizing research that integrates materials science with real-world applications, including nanostructured materials, polymers, composites, coatings, and surfaces/interfaces, while complementing ACS's more fundamental journals like Chemistry of Materials and Langmuir.[1] Launched in 2009, the journal has experienced rapid growth, becoming one of ACS's largest publications with a significant global reach; by 2023, the majority of its articles originated from outside the United States, and it achieved over 305 million downloads that year.[1] Its content includes original research articles, reviews, perspectives, spotlights on applications, forum articles, and comments, with some types available only by invitation, and it supports open access options under Creative Commons licenses (CC BY or CC BY-NC-ND).[1] As of 2024, ACS Applied Materials & Interfaces holds a 2-year impact factor of 8.2, a CiteScore of 14.5, and has accumulated 386,890 total citations, reflecting its influence in materials science and related disciplines.[2] The journal is overseen by an expert editorial team of active researchers, including Editor-in-Chief Xing Yi Ling from Nanyang Technological University, Singapore, and executive editors such as Rizia Bardhan from Iowa State University and Omar Farha from Northwestern University.[3][4]History
Establishment
ACS Applied Materials & Interfaces was established in 2009 by the American Chemical Society (ACS) as a peer-reviewed scientific journal dedicated to advancing research in applied materials science.[5] The journal was created to meet the increasing demand for a dedicated outlet in the ACS portfolio that emphasizes application-oriented studies in materials and interfaces, bridging the gap between fundamental chemistry journals and practical engineering applications.[5][6] Kirk S. Schanze, a professor of chemistry at the University of Florida at the time, served as the founding Editor-in-Chief, leading the journal from its inception through 2023 and shaping its interdisciplinary emphasis on materials interfaces and their real-world applications.[5][7] Under his guidance, the journal launched its inaugural issue as Volume 1 in January 2009, with an initial monthly publication frequency to ensure timely dissemination of research.[8][5] The creation of the journal was driven by the recognition of a need for a platform that integrates materials science, engineering, and related fields to highlight novel applications of advanced materials, distinct from ACS's existing publications focused on core chemical principles.[5] This foundational vision positioned ACS Applied Materials & Interfaces as a key resource for researchers seeking to explore the synergy between fundamental science and practical innovations at material interfaces.[6] Schanze's tenure concluded with a transition to subsequent editors, including Xing Yi Ling as the current Editor-in-Chief starting in 2024.[3]Development and Milestones
Following its establishment in 2009, ACS Applied Materials & Interfaces experienced significant operational growth to meet rising submission rates and expanding interest in applied materials research.[1] Initially published monthly, the journal transitioned to biweekly publication starting with Volume 5 in 2013 to handle the increasing volume of high-quality manuscripts. This shift was followed by a move to weekly issues in 2015 with Volume 7, enabling more timely dissemination of research amid accelerating publication demands.[9] The journal's article output grew rapidly, reflecting its broadening appeal; early volumes in 2009 featured approximately 400 articles, expanding to over 5,500 annually by 2023 as interdisciplinary contributions surged from global authors.[10][11] This expansion positioned it as a key outlet within the American Chemical Society's publications, with over 49,000 articles published as of 2024.[11] A notable editorial transition occurred in late 2023, when founding Editor-in-Chief Kirk S. Schanze stepped down after leading the journal for over a decade; Professor Xing Yi Ling of Nanyang Technological University was appointed as the new Editor-in-Chief effective January 1, 2024, emphasizing enhanced global collaboration and applications in emerging technologies.[2] Under this leadership, the journal integrated more deeply into ACS's applied materials portfolio, aligning with sister titles to foster cohesive advancements in the field.[12] Key milestones include the 10-year anniversary celebration in March 2019, marked by a curated collection highlighting seminal contributions in materials and interfaces.[13] By 2025, the journal had amassed over 386,000 total citations, underscoring its enduring influence on applied science.[2]Scope and Focus
Core Research Areas
ACS Applied Materials & Interfaces emphasizes applied research at the nexus of materials science and interfacial phenomena, with core research areas spanning several interconnected domains that address practical challenges in technology and medicine. These areas include biological and medical applications of materials and interfaces, energy, environmental, and catalysis applications, functional inorganic materials and devices, organic electronic devices, functional nanostructured materials (including low-dimensional carbon), applications of polymer, composite, and coating materials, and surfaces, interfaces, and applications.[1] The journal prioritizes studies that link material synthesis, structure, and properties to specific device or process performance, fostering advancements across chemistry, physics, engineering, and biology.[1] In biological and medical applications, the journal highlights biomaterials and bio-interfaces designed for therapeutic uses, such as controlled drug delivery systems and scaffolds for tissue engineering. Research in this area often explores how surface chemistry and topography influence cellular interactions and biocompatibility, enabling targeted therapies with minimal side effects. For instance, a review on material and design toolkits for drug delivery discusses stimuli-responsive polymers and nanoparticles that achieve precise release profiles, improving efficacy in cancer treatment and wound healing.[14] These studies underscore the role of interfacial properties in enhancing bioavailability and reducing toxicity in vivo. Energy, environmental, and catalysis applications form another cornerstone, focusing on materials that improve efficiency in energy storage, conversion, and pollutant remediation. Contributions here examine hybrid systems for batteries, solar cells, and catalysts, emphasizing scalable fabrication and long-term stability under operational conditions. A representative example is a review of ordered pores in nanomaterials, which details their use in lithium-ion batteries and electrocatalysis, where pore architecture enhances ion transport and reaction rates compared to bulk counterparts.[15] Such work highlights applied catalysis processes that prioritize practical metrics like turnover frequency over purely theoretical mechanisms.[16] Functional inorganic and organic electronic devices represent key domains for advanced active and passive electronic/optical materials, including nanomaterials integrated into sensors, transistors, and displays. These areas stress device-level performance, such as charge mobility and optical tunability, derived from interfacial engineering. For organic electronics, a seminal review on boron subphthalocyanines explores their electron-accepting properties in photovoltaic cells, achieving power conversion efficiencies up to 4.2% through optimized film morphologies.[17] Similarly, inorganic nanomaterials like perovskites are investigated for optoelectronic applications, where defect passivation at interfaces enhances stability and quantum efficiency.[1] The journal also covers functional nanostructured materials, particularly low-dimensional carbon forms like graphene and carbon nanotubes, applied in flexible electronics and sensors. These studies link nanoscale structure to macroscopic functionality, such as enhanced conductivity or mechanical strength. In polymer, hybrid, and composite materials, emphasis is placed on energy and environmental uses, including membranes for water purification and composites for lightweight energy storage. Coatings, colloids, and surfaces/interfaces receive attention for phenomena like friction reduction and self-assembly, with applications in anti-fouling surfaces and lubricants.[1] Overall, these areas integrate to drive innovations in sustainable technologies and healthcare.[1]Interdisciplinary Applications
ACS Applied Materials & Interfaces bridges multiple scientific disciplines by emphasizing the development of materials and interfacial processes that enable practical applications across fields such as chemistry, physics, engineering, and biology. The journal's content integrates concepts from core areas like polymers and colloids to address real-world challenges, fostering collaborations that translate fundamental research into functional devices and systems.[1] In energy and environmental fields, the journal highlights interfacial materials for solar cells, batteries, and pollutant remediation. For instance, multifunctional dye molecules have been explored as interfacial layers in perovskite solar cells to enhance efficiency and stability through improved charge extraction at interfaces.[18] Similarly, studies on interfacial ion transfer kinetics in lithium-ion batteries reveal mechanisms to optimize electrode-electrolyte interactions, reducing resistance and improving cycle life.[19] For pollutant remediation, electrochemical methods using nanostructured interfaces enable efficient removal of organic and inorganic contaminants from water, leveraging surface properties for selective adsorption and degradation.[1] Biological and medical applications focus on sensors, implants, and biocompatible coatings that interface with living systems for diagnostics and therapeutics. Biocompatible hybrid graphenic thin coatings on flexible substrates demonstrate low cytotoxicity and strong adhesion, suitable for implantable devices that require long-term stability in physiological environments. These materials often incorporate interfacial designs to minimize immune responses while enabling functions like drug release or tissue integration.[20][1] In engineering contexts, the journal covers device fabrication involving flexible electronics and smart materials for wearables. Flexible electronic reflection smart windows utilize interfacial layers to achieve tunable optical properties, integrating materials science with electrical engineering for energy-efficient building applications.[21] Smart gloves with WiFi-powered sensors exemplify wearable integration, where interfacial optimizations ensure reliable signal transmission and mechanical durability during motion.[22] Catalysis and device integration emphasize hybrid systems combining organic and inorganic components for efficient chemical processes. Hybrid photo- and thermal catalyst systems facilitate continuous CO2 reduction by optimizing interfacial charge transfer between light-absorbing and catalytic layers, enhancing selectivity and yield in sustainable fuel production. These approaches draw from interdisciplinary insights to create robust, multifunctional platforms.[23][1] The journal underscores translational research, where lab-scale discoveries evolve into prototypes, such as plasmonic nanostructures for sensing. Metal-insulator-metal plasmonic nanostructures provide accessible sites for biosensing, enabling high-sensitivity detection of biomolecules through localized surface plasmon resonance at interfaces, paving the way from fundamental studies to practical diagnostic tools.[24]Editorial Structure
Editor-in-Chief
The Editor-in-Chief of ACS Applied Materials & Interfaces oversees the journal's editorial direction, establishes its strategic vision, and makes high-level decisions regarding manuscript suitability and publication.[25] This role ensures the journal maintains its focus on high-impact, application-oriented research at the interfaces of materials science, chemistry, and engineering.[5] Kirk S. Schanze served as the founding Editor-in-Chief from 2009 to 2023, affiliated with the University of Florida.[2] Under his leadership, the journal expanded from a niche publication to a high-impact venue, publishing nearly 20,000 articles and accumulating over 300,000 citations by 2018, with a 2016 impact factor of 7.50.[26] Schanze emphasized the journal's commitment to interdisciplinary applications, such as electronic materials, coatings, and energy storage, distinguishing it from more fundamental-oriented ACS titles; he authored editorials marking the 2009 launch and the 2018 tenth anniversary, highlighting growth in submissions and global editorial expansion to 32 editors across 14 countries.[5][26] Xing Yi Ling, a professor at Nanyang Technological University in Singapore, assumed the role of Editor-in-Chief in January 2024.[2] Her expertise lies in nanophotonics and plasmonics, particularly self-assembling noble metal nanoparticles for surface-enhanced Raman scattering (SERS) applications in environmental sensing, healthcare, and catalysis.[27] Ling's vision for the journal includes advancing research on sustainable and environmentally friendly materials, promoting innovations in nanomaterials, energy materials, and smart materials, while fostering global diversity in submissions and collaborations through outreach events.[27] Editors-in-Chief are appointed by ACS Publications through a confidential process involving a diverse search committee that identifies candidates based on their research leadership, editorial experience, and alignment with the journal's goals.[28][25]Editorial Board and Review Process
The editorial board of ACS Applied Materials & Interfaces comprises approximately 118 members (as of 2025) across various roles, including associate, advisory, executive, and early career members, all of whom are active researchers in materials science and related fields such as chemistry, physics, and biochemistry.[3] These members are selected based on their expertise in key areas, including energy materials, biomaterials, electronic materials, and interfacial science, ensuring comprehensive coverage of the journal's interdisciplinary scope.[3] The board exhibits strong international representation, with members from over 20 countries; while the United States accounts for about 34 members, the majority—84—are affiliated with institutions outside the U.S., including significant numbers from China (29 members), South Korea (10), and various European and Asian nations.[3] Supporting the Editor-in-Chief, the board includes specialized roles such as one Deputy Editor, 12 Executive Editors, and 38 Associate Editors, who handle manuscript assignments and oversee the review workflow.[3] For instance, Deputy Editor Peter Müller-Buschbaum, appointed in 2024 from Technische Universität München, Germany, provides technical oversight in functional materials and supports strategic decisions on submissions.[29] Additionally, a 47-member Editorial Advisory Board offers guidance on emerging trends, while a 20-member Early Career Board incorporates fresh perspectives from rising researchers.[3] A single Managing Editor at the American Chemical Society coordinates administrative operations.[3] The journal employs a single-anonymized peer review process, in which reviewers are aware of the authors' identities but remain anonymous to them, with an optional transparent peer review where reviewer comments and author responses are published as supporting information.[30] Submissions undergo initial screening by editors or associate editors to assess fit with the journal's scope, emphasizing the interplay between material synthesis, structure, properties, and practical applications.[30] The median time to first decision following peer review is 34.6 days (as of 2025), reflecting an efficient workflow that prioritizes rigorous evaluation of scientific merit, novelty, and potential impact.[31] Reviewers are encouraged to assess reproducibility through detailed methodological descriptions and data availability, aligning with the journal's focus on reliable, application-oriented research.[2] Ethical handling and appeals are governed by the ACS Ethical Guidelines to Publication of Chemical Research, which address issues like authorship, conflicts of interest, and data integrity. As a member of the Committee on Publication Ethics (COPE), the journal follows COPE guidelines for investigating misconduct, including plagiarism detected via tools like iThenticate.[32] Authors may appeal editorial decisions through a formal process outlined in ACS policies, with final approvals often involving the Editor-in-Chief.Publication Details
Format and Frequency
ACS Applied Materials & Interfaces has been published weekly since 2015, resulting in approximately 52 issues per year. Each issue typically contains 100-120 articles, reflecting the journal's high submission volume and rapid growth (as of 2024).[33] Originally issued monthly upon its launch in 2009, the publication schedule evolved to biweekly in 2013 before shifting to weekly to better support the influx of interdisciplinary research.[34] The journal operates in a hybrid print and digital format, prioritizing online accessibility for timely distribution. Accepted articles appear online first via the As Soon As Publishable (ASAP) program, which posts them shortly after final corrections, often weeks before their formal issue assignment. Full-text content is delivered in both HTML and PDF versions to facilitate reading and archiving.[2][35] Key identifiers for the journal include the print ISSN 1944-8244 and web ISSN 1944-8252, along with the CODEN AAMICK and OCLC number 238703087.[36][35][8] Research articles in the journal are expected to be concise, typically spanning 4-8 pages, though no strict length limit is enforced to allow flexibility in presenting complex materials science findings. Supporting information, which may include detailed experimental data, spectra, or supplementary figures, is unlimited in length and provided as separate files for comprehensive reader access.[35]Access and Licensing
ACS Applied Materials & Interfaces operates under a hybrid access model, providing subscription-based access for institutions while offering pay-per-view options for individual users; abstracts are freely accessible to all readers.[30] Authors have the option to publish their articles as gold open access through the ACS AuthorChoice program, selecting either a Creative Commons Attribution (CC BY) license or a CC BY-NonCommercial-NoDerivatives (CC BY-NC-ND) license, which makes the content immediately free to read and share under the specified terms.[30] The article processing charge (APC) for immediate open access under the CC BY license in this hybrid journal is $4,500 USD as of 2025, with a reduced fee of $4,000 USD for the CC BY-NC-ND license.[37] The journal participates in read-and-publish agreements through the ACS Read + Publish program, which enables institutions to bundle subscription access to ACS journals with covered open access publishing for affiliated authors, eliminating APCs for eligible corresponding authors at partner organizations worldwide.[38] For long-term preservation, all content from ACS Applied Materials & Interfaces is archived in both Portico and CLOCKSS, ensuring availability in the event of disruptions to the publisher's services.[39]Impact and Metrics
Citation Metrics
ACS Applied Materials & Interfaces has established itself as a highly influential journal in the field of materials science, as evidenced by its robust citation metrics. The journal's 2024 Impact Factor, according to the Journal Citation Reports released by Clarivate, stands at 8.2, reflecting a slight decline from previous years but maintaining a strong position in the nanoscience and nanotechnology category, where it ranks in the first quartile (Q1).[2][40][41] This metric is calculated based on the average number of citations received in 2024 to articles published in 2022 and 2023. Historically, the Impact Factor peaked at 10.4 in 2021, followed by 9.5 in 2022, 8.3 in 2023, and 8.2 in 2024, indicating a decline after the peak despite competitive pressures in the discipline.[40] The journal's H-index, a measure of productivity and citation impact, reached 334 as of 2025, meaning that 334 of its papers have each received at least 334 citations.[33][42] This high H-index underscores the enduring influence of its publications since the journal's launch in 2009, with cumulative growth in citations reflecting its role in advancing applied materials research.[1] Additional metrics further highlight the journal's prestige. Its 2024 CiteScore, provided by Scopus, is 14.5, evaluating citations from 2021 to 2024 relative to citable items in that period.[2] The SCImago Journal Rank (SJR) for 2024 is 1.921, placing it in Q1 for materials science (miscellaneous), which accounts for the prestige and citation normalization across disciplines.[33] Overall, the journal has amassed approximately 387,000 total citations as of 2024, demonstrating broad scholarly engagement.[2] In terms of rankings, ACS Applied Materials & Interfaces positions in the top 10% of journals within multidisciplinary materials science based on CiteScore percentiles and achieves an 82nd percentile in nanoscience and nanotechnology according to Journal Citation Reports.[41][43] These standings affirm its leadership in fostering high-impact research at the interfaces of materials and applications.[44]| Metric | Value (2024 unless noted) | Source |
|---|---|---|
| Impact Factor | 8.2 | Journal Citation Reports[2] |
| Historical Impact Factors | 2021: 10.4; 2022: 9.5; 2023: 8.3 | BioxBio[40] |
| H-Index | 334 (as of 2025) | SCImago[33] |
| CiteScore | 14.5 | Scopus via ACS[2] |
| SJR | 1.921 (Q1) | SCImago[33] |
| Total Citations | ~387,000 | ACS Publications[2] |
| Nanoscience Percentile | 82% | Journal Citation Reports[41] |