Molecular deposition on solid surfaces forms crystalline or amorphous/glassy thin solid films. Intermolecular interactions govern the packing and dynamics of these films. The connection between molecular structure and intermolecular interactions is based on understanding electrostatic forces, dispersion forces and hydrogen bonding. Recently, an entire class of dipolar molecular species have demonstrated counterintuitive self-organization such that the dipole moments of individual molecules are oriented in thin films. This leads to the spontaneous generation of polarized molecular films manifesting a polarization charge equivalent to tens to hundreds of volts in strength at the film-vacuum interface, relative to the film-substrate interface. These voltages, and the corresponding electric fields present in such films, result from a collective and spontaneous orientation of molecular dipoles throughout the film during film growth and represent a metastable state of polarized material. The existence of these materials should encourage reconsideration of the importance of solid-state intermolecular electrostatic interactions.

Bimetallic catalysts hold promise in tailoring the catalytic activity and selectivity of transition metals for important chemical processes due to the synergistic coupling between the constituent elements that can connect catalytical active sites. However, it remains a challenge to construct an ideal bimetallic catalyst to study the respective or cooperative effects of the two transition metals within the bimetallic catalyst on the overall catalytic performance because multiple factors are always convoluted, such as the size dispersity of particles, the inhomogeneous structure, and the unknown exact location of the two metal elements in any particle. Therefore, almost all of the current studies give rise to the statistics of the overall catalytic performance from all of the particles in a bimetallic catalyst or at least the observed performance reflects an ensemble average of all metal atoms in a particle. Atomically precise metal nanoclusters have attracted catalysis scientists since their total structures (core plus surface) were solved by single-crystal X-ray crystallography, thereby providing unparalleled opportunities to build a precise correlation of catalyst structures with catalytic properties at an atomic level. Within this field, we are interested in identifying catalytically active sites and further constructing the active sites by an atom-by-atom manipulation, which are typically challenging for conventional particle-based heterogeneous catalysts and organometallics-based complex catalysts.

In the mid 2010s, high-pressure diffraction and spectroscopic tools opened a window into the molecular-scale behavior of fluids under the conditions of many CO2 sequestration and shale/tight gas reservoirs, conditions where CO2 and CH4 are present as variably wet supercritical fluids. Integrating high-pressure spectroscopy and diffraction with molecular modeling has revealed much about the ways that supercritical CO2 and CH4 behave in reservoir components, particularly in the slit-shaped micro- and mesopores of layered silicates (phyllosilicates) abundant in caprocks and shales. This Account summarizes how supercritical CO2 and CH4 behave in the slit pores of swelling phyllosilicates as functions of the H2O activity, framework structural features, and charge-balancing cation properties at 90 bar and 323 K, conditions similar to a reservoir at ∼1 km depth. Slit pores containing cations with large radii, low hydration energy, and large polarizability readily interact with CO2, allowing CO2 and H2O to adsorb and coexist in these interlayer pores over a wide range of fluid humidities. In contrast, cations with small radii, high hydration energy, and low polarizability weakly interact with CO2, leading to reduced CO2 uptake and a tendency to exclude CO2 from interlayers when H2O is abundant. The reorientation dynamics of confined CO2 depends on the interlayer pore height, which is strongly influenced by the cation properties, framework properties, and fluid humidity. The silicate structural framework also influences CO2 uptake and behavior; for example, smectites with increasing F-for-OH substitution in the framework take up greater quantities of CO2. Reactions that trap CO2 in carbonate phases have been observed in thin H2O films near smectite surfaces, including a dissolution–reprecipitation mechanism when the edge surface area is large and an ion exchange–precipitation mechanism when the interlayer cation can form a highly insoluble carbonate. In contrast, supercritical CH4 does not readily associate with cations, does not react with smectites, and is only incorporated into interlayer slit mesopores when (i) the pore has a z-dimension large enough to accommodate CH4, (ii) the smectite has low charge, and (iii) the H2O activity is low. The adsorption and displacement of CH4 by CO2 and vice versa have been studied on the molecular scale in one shale, but opportunities remain to examine behavioral details in this more complicated, slit-pore inclusive system.

Nanostructured copper-based materials have emerged as a new generation of robust architectures for realizing high-performing and reliable interconnection in modern electronic packaging. As opposed to traditional interconnects, nanostructured materials offer better compliance during the packaging assembly process. Due to the high surface area-to-volume ratio of nanomaterials, they also enable joint formation by sintering through thermal compression at much lower temperatures compared to bulk counterparts. Nanoporous Cu (np-Cu) films have been employed in electronic packaging as materials that facilitate a chip-to-substrate interconnection, realized by a Cu-on-Cu bonding after sintering.

With unparalleled programmability, DNA has evolved as a powerful scaffold for engineering intricate and dynamic systems that can perform diverse tasks. By allowing serial detection of molecular targets in complex cellular milieus, increasingly sophisticated DNA sensors have not only promoted significant advances in unveiling the fundamental mechanisms of various pathophysiological processes but also provided a useful toolkit for disease diagnostics based on molecular signatures. Despite much progress, an inherent limitation of DNA-based sensors is that they often lack spatial control and cell-type selectivity for the sensing activity because of their “always active” design mechanism. Since most molecular targets of interests are not exclusive to disease cells, they are also shared by normal cells, the application of such biosensors for disease-specific imaging is limited by inadequate signal-to-background ratios due to indistinguishable signal response in both disease and normal cells. Therefore, imparting biosensors with spatial controllability remains a key issue to achieve molecular imaging with high sensitivity and cell specificity.

The high energy barriers associated with the reaction chemistry of inert substrates can be overcome by employing redox-active photocatalysts. Research in this area has grown exponentially over the past decade, as transition metal photosensitizers have been shown to mediate challenging organic transformations. Critical for the advancement of photoredox catalysis is the discovery, development, and study of complexes based on earth-abundant metals that can replace and/or complement established noble-metal-based photosensitizers.

Theranostic nanoparticles’ potential in tumor treatment has been widely acknowledged thanks to their capability of integrating multifaceted functionalities into a single nanosystem. Theranostic nanoparticles are typically equipped with an inorganic core with exploitable physical properties for imaging and therapeutic functions, bioinert coatings for improved biocompatibility and immunological stealth, controlled drug-loading–release modules, and the ability to recognize specific cell type for uptake. Integrating multiple functionalities in a single nanosized construct require sophisticated molecular design and precise execution of assembly procedures. Underlying the multifunctionality of theranostic nanoparticles, ligand chemistry plays a decisive role in translating theoretical designs into fully functionalized theranostic nanoparticles. The ligand hierarchy in theranostic nanoparticles is usually threefold. As they serve to passivate the nanoparticle’s surface, capping ligands form the first layer directly interfacing with the crystalline lattice of the inorganic core. The size and shape of nanoparticles are largely determined by the molecular property of capping ligands so that they have profound influences on the nanoparticles’ surface chemistry and physical properties. Capping ligands are mostly chemically inert, which necessitates the presence of additional ligands for drug loading and tumor targeting. The second layer is commonly utilized for drug loading. Therapeutic drugs can either be covalently conjugated onto the capping layer or noncovalently loaded onto nanoparticles via drug-loading ligands. Drug-loading ligands need to be equally versatile in properties to accommodate the diversity of drugs. Biodegradable moieties are often incorporated into drug-loading ligands to enable smart drug release. With the aid of targeting ligands which usually stand the tallest on the nanoparticle surface to seek and bind to their corresponding receptors on the target, theranostic nanoparticles can preferentially accumulate at the tumor site to attain a higher precision and quantity for drug delivery. In this Account, the properties and utilities of representative capping ligands, drug-loading ligands, and targeting ligands are reviewed. Since these types of ligands are often assembled in close vicinity to each other, it is essential for them to be chemically compatible and able to function in tandem with each other. Relevant conjugation strategies and critical factors with a significant impact on ligands’ performance on nanoparticles are discussed. Representative theranostic nanoparticles are presented to showcase how different types of ligands function synergistically from a single nanosystem. Finally, the technological outlook of evolving ligand chemistry on theranostic nanoparticles is provided.

Fluorescent molecular sensors, often referred to as “turn-on” or “turn-off” fluorescent probes, are synthetic agents that change their fluorescence signal in response to analyte binding. Although these sensors have become powerful analytical tools in a wide range of research fields, they are generally limited to detecting only one or a few analytes. Pattern-generating fluorescent probes, which can generate unique identification (ID) fingerprints for different analytes, have recently emerged as a new class of luminescent sensors that can address this limitation. A unique characteristic of these probes, termed ID-probes, is that they integrate the qualities of conventional small-molecule-based fluorescent sensors and cross-reactive sensor arrays (often referred to as chemical, optical, or electronic noses/tongues). On the one hand, ID-probes can discriminate between various analytes and their combinations, akin to array-based analytical devices. On the other hand, their minute size enables them to analyze small-volume samples, track dynamic changes in a single solution, and operate in the microscopic world, which the macroscopic arrays cannot access.

Native mass spectrometry is nowadays widely used for determining the mass of intact proteins and their noncovalent biomolecular assemblies. While this technology performs well in the mass determination of monodisperse protein assemblies, more real-life heterogeneous protein complexes can pose a significant challenge. Factors such as co-occurring stoichiometries, subcomplexes, and/or post-translational modifications, may especially hamper mass analysis by obfuscating the charge state inferencing that is fundamental to the technique. Moreover, these mass analyses typically require measurement of several million molecules to generate an analyzable mass spectrum, limiting its sensitivity. In 2012, we introduced an Orbitrap-based mass analyzer with extended mass range (EMR) and demonstrated that it could be used to obtain not only high-resolution mass spectra of large protein macromolecular assemblies, but we also showed that single ions generated from these assemblies provided sufficient image current to induce a measurable charge-related signal. Based on these observations, we and others further optimized the experimental conditions necessary for single ion measurements, which led in 2020 to the introduction of single-molecule Orbitrap-based charge detection mass spectrometry (Orbitrap-based CDMS). The introduction of these single molecule approaches has led to the fruition of various innovative lines of research. For example, tracking the behavior of individual macromolecular ions inside the Orbitrap mass analyzer provides unique, fundamental insights into mechanisms of ion dephasing and demonstrated the (astonishingly high) stability of high mass ions. Such fundamental information will help to further optimize the Orbitrap mass analyzer. As another example, the circumvention of traditional charge state inferencing enables Orbitrap-based CDMS to extract mass information from even extremely heterogeneous proteins and protein assemblies (e.g., glycoprotein assemblies, cargo-containing nanoparticles) via single molecule detection, reaching beyond the capabilities of earlier approaches. We so far demonstrated the power of Orbitrap-based CDMS applied to a variety of fascinating systems, assessing for instance the cargo load of recombinant AAV-based gene delivery vectors, the buildup of immune-complexes involved in complement activation, and quite accurate masses of highly glycosylated proteins, such as the SARS-CoV-2 spike trimer proteins. With such widespread applications, the next objective is to make Orbitrap-based CDMS more mainstream, whereby we still will seek to further advance the boundaries in sensitivity and mass resolving power.

Characterized by the reverse intersystem crossing (RISC) process from the triplet state (T1) to the singlet state (S1), thermally activated delayed fluorescence (TADF) emitters, which produce light by harvesting both triplet and singlet excitons without noble metals, are considered to be third-generation organic electroluminescent materials. Rapid advances in molecular design criteria, understanding the photophysics underlying TADF, and applications of TADF materials as emitters in organic light-emitting diodes (OLEDs) have been achieved. Theoretically, enhanced spin–orbit coupling (SOC) between singlet and triplet states can result in a fast RISC process and thus a high light-emitting efficiency according to Fermi’s golden rule. Therefore, regulating the nature of triplet excited states by elaborate molecular design to improve SOC is an effective approach to high-efficiency TADF-based OLEDs. Generally, on one hand, the increased local excited (LE) populations of the excited triplet state can significantly improve the nature flips between S1 and T1. On other hand, the reduced energy gap between S1 and the lowest triplet with a charge transfer (CT) characteristic can also enhance their vibronic coupling. Consequently, it is vital to determine how to regulate the nature of triplet excited states by molecular design to guide the material synthesis, especially for polymeric emitters.

The past 50 years of discovery in organic electronics have been driven in large part by the donor–acceptor design principle, wherein electron-rich and electron-poor units are assembled in conjugation with each other to produce small band gap materials. While the utility of this design strategy is undoubtable, it has been largely exhausted as a frontier of new avenues to produce and tune novel functional materials to meet the needs of the ever-increasing world of organic electronics applications. Its sister strategy of joining quinoidal and aromatic groups in conjugation has, by comparison, received much less attention, to a great extent due to the categorically poor stability of quinoidal conjugated motifs.

Development of multifunctional nanoparticles (NPs) with desired properties is a significant topic in the field of nanotechnology and has been anticipated to revolutionize cancer diagnosis and treatment modalities. The surface character is one of the most important parameters of NPs that can directly affect their in vivo fate, bioavailability, and final theranostic outcomes and thus should be carefully tuned to maximize the diagnosis and treatment effects while minimizing unwanted side effects. Surface engineered NPs have utilized various surface functionality types and approaches to meet the requirements of cancer therapy and imaging. Despite the various strategies, these surface modifications generally serve similar purposes, namely, introducing therapeutic/imaging modules, improving stability and circulation, enhancing targeting ability, and achieving controlled functions. These surface engineered NPs hence could be applied in various cancer diagnosis and treatment scenarios and continuously contribute to the clinical translation of the next-generation NP-based platforms toward cancer theranostics.

Understanding the structural architecture of nanoparticles is essential for investigating their fundamental properties because these materials have become more desirable in modern nanoscience research. Designing a proper synthetic strategy to control their growth with atomic precision is crucial. The polydispersed nature of the nanoparticles makes determining their precise structural information challenging. Metal nanoclusters (NCs) have emerged as a promising solution to this problem as they bridge the gap between metal nanoparticles and discrete molecular complexes. Well-ordered molecular structures provide opportunities to look at structure–property correlations and find quantum confinement effects at the atomic level that reveal their similarity to molecular-like properties. While most M(0)/(I)-based NCs exhibit exceptional photoluminescence (PL) emission at room temperature, M(I)-based NCs are less likely to exhibit PL emissions due to their electronic environment. Developments in the field of metal nanoparticles have made it intriguing to achieve room-temperature PL emission in M(I) NCs. Efforts have focused on developing efficient methods for preparing luminescent M(I) NCs to better comprehend fundamental aspects of their PL emission properties. We provide an overview of various synthetic strategies for preparing NCs and their selective functionalization for generating room-temperature PL emissions. Our focus has been creating an Ag(I) NC with a core–shell architecture, as this unique structural design complements the charge transition phenomenon. The molecular structure obtained from single-crystal X-ray diffraction (SCXRD) and associated theoretical calculation revealed that our effort results in a unique hexagonal closed pack core and Keplerate shell containing [S@Ag50S12(StBu)20]4+ NC where the charge transition between the core and the metal–ligand shell facilitates emission properties. We also explored the approach of host–guest supramolecular adduct formations to engineer the surface of ligands that reduce nonradiative relaxation rates by restricting surface molecular vibrations and controlling the generation of PL emission. To do this, we capped precisely structured [Cl@Ag16S(S-Adm)8(CF3COO)5(DMF)3(H2O)2]·DMF with β-cyclodextrin via adamantane moieties. We also describe the effects of bimetallic cluster formation on increasing surface rigidity and modulating the frontier molecular orbital arrangement, which helps to attain synergy to generate room-temperature PL emission. We focused on the structural integrity of Ag(I) NCs, allowing us to incorporate heterometal atoms at peripheral positions that lead to the formation of [CO2@Ag20Cu2S2(StBu)10(CF3COO)8(DMA)4]·(DMA). We also explored the impact of introducing extra ligands into the Ag(I) cluster node on the generation of PL emission at room-temperature. These strategies are not limited to Ag NCs. We discussed the possibility of combining core–shell architecture and surface modifications to enhance PL emission in [Cu18H3(S-Adm)12(PPh3)4Cl2] NC at room temperature. SCXRD studies revealed its distinct core–shell architecture that ensures electronic transitions and that transition is controlled by the imposed surface rigidity that yields a higher PL emission. We believe that this innovative structural engineering holds potential for the advancement of NC research, and this Account will inspire the scientific community to synthesize functional M(I) NCs.

Gold nanoparticles (AuNPs) exhibit unique size- and shape-dependent properties not obtainable at the macroscale. Gold nanorods (AuNRs), with their morphology-dependent optical properties, ability to convert light to heat, and high surface-to-volume ratios, are of great interest for biosensing, medicine, and catalysis. While the gold core provides many fascinating properties, this Account focuses on AuNP soft surface coatings, which govern the interactions of nanoparticles with the local environments. Postmodification of AuNP surface chemistry can greatly alter NP colloidal stability, nano-bio interactions, and functionality. Polyelectrolyte coatings provide controllable surface-coating thickness and charge, which impact the composition of the acquired corona in biological settings. Covalent modification, in which covalently bound ligands replace the original capping layer, is often performed with thiols and disulfides due to their ability to replace native coatings. N-heterocyclic carbenes and looped peptides expand the possible functionalities of the ligand layer.

Peptides are essential components of living systems and contribute to critical biological processes, such as cell proliferation, immune defense, tumor formation, and differentiation. Therefore, peptides have attracted considerable attention as targets for the development of therapeutic products. The incorporation of unnatural amino acid residues into peptides can considerably impact peptide immunogenicity, toxicity, side effects, water solubility, action duration, and distribution and enhance the peptides’ druggability. Typically, the direct modification of natural amino acids is a practical and effective approach for promptly obtaining unnatural amino acids. However, selective functionalization of multiple C(sp3)–H bonds with comparable chemical reactivities in the peptide side chains remains a formidable challenge. Furthermore, chemical modifications aimed at highly reactive (nucleophilic and aromatic) groups on peptide side chains can interfere with the biological activity of peptides.

This Account describes the results of the electrodeposition of film-like Si, Ti, and W by utilizing molten salts selected based on a new concept. The proposed molten salt systems, KF–KCl and CsF–CsCl, have high fluoride ion concentrations, relatively low operating temperatures, and high solubility in water.

This article is part of the Research at HBCUs special issue. Guest Editorial for the Accounts of Chemical Research special issue “Research at HBCUs”. Since the founding of Cheyney State University in 1837, Historically Black Colleges and Universities (HBCUs) have continued to build on the nation’s scientific and technological dominance through the production of exceptional talent and cutting-edge research. Black history is brimming with the names of inventive geniuses who fueled America’s scientific prowess and prosperity─like Drs. William and Lawrence Knox who worked on the Manhattan Project to improve the isolation of uranium isotopes needed for the atomic bomb; (1) Dr. Henry McBay whose research on acetyl peroxide led to the synthesis of a hormone used in the treatment of prostate cancer; (2) and Dr. Charles Magee who recently received a patent for a portable osmotic food production (3) system and has received more patents than George Washington Carver. (4) Today, HBCUs continue to contribute to the body of research in anticancer and antimalarial agents and cell biology, new types of polymerization-based biosensing and bioimaging techniques for early screening and diagnosis of human disease, and the creation of a wide range of alternative energy sources. Moreover, their groundbreaking research in the fields of therapeutic biomaterials, environmental and water remediation, and sustainable and energy-efficient materials has inspired students to explore careers in chemistry and related sciences. Striking a balance between history and hope for a better future, the core values of “inclusion, innovation, and investment,” are deeply embedded in the mission of HBCUs. These universities share the same vision and similar missions─creating opportunity, adding value to society, and defining scholarship in ways that illuminate the underpinnings of historic discrimination. Given their stellar record of success in research, HBCUs are uniquely positioned to play a more prominent role in complementing the American Chemistry Society’s (ACS) mission to serve as “Champions of Chemistry.” The extraordinary influence of HBCUs on African Americans’ education and professional development in chemistry, engineering, and related disciplines has no precedent. HBCUs prepare and empower students to persist in STEM and embody who they desire to be through an inclusive and supportive environment unique to their culture. They produce 24% of all Black undergraduates with STEM degrees and 30% of all Black doctorates in science and engineering. Unfortunately, despite the fact that greater diversity in the workforce drives innovation and contributes to America’s economic muscle, a meager 7.7% of Chemists in the U.S. are Black. The U.S. is the top chemical producer in the world, accounting for nearly one-fifth of world production. The Chemistry sector represents a multitrillion-dollar market with nearly 800,000 people working around the world and contributing to the creation of 4.4 million jobs. HBCU professionals are contributing to the growth of Merck, Intel, and Centers for Disease Control and Prevention and are engaged in global research laboratories and centers charged with the mission of improving the health and well-being of people and the planet. Improving the quality of life demands greater support of government and private sector stakeholders in maintaining America’s preeminence in the sciences. As noted in a report issued by the World Bank, “...higher education, is the pathway to the empowerment of people and the development of nations...The modern university is the ideal space for the ecosystem of scholars to search for new ideas.” (5) The nation’s failure to engage HBCUs in the search for new ideas in the field of Chemistry and beyond could hold unfortunate consequences for sustainable growth in the marketplace. America has always been a nation of vast human potential, of creators and catalysts of change. The challenge of today is to find new and innovative ways to mine and invest in the human potential of the nation’s 101 Historically Black Colleges and Universities. Justice Marshall reminds us that “We must dissent from the poverty of vision and the absence of moral leadership. We must dissent because America can do better, because America has no choice but to do better.” (6) This special issue of Accounts of Chemical Research highlights exciting new research from leading HBCU laboratories and addresses fundamental questions surrounding the contributions of HBCUs in maintaining the nation’s prominence in science and technology. Further, to continue to give voice to the HBCU community to promote their research and innovations, a half-day inaugural American Chemical Society (ACS) Presidential Event Research at HBCUs Symposium was convened at the ACS 2023 Crossroads of Chemistry Conference on Sunday, March 26th. The symposium showcased research occurring at HBCU institutions that are foundational to the nation’s efforts to build a diverse STEM workforce and to stimulate increased engagement among HBCUs and the chemical enterprise. In addition, this symposium featured HBCU presentations, keynote addresses, and panel sessions covering topics ranging from the science of hair to the challenges of research at HBCUs and addressed the best practices of mentoring underrepresented minorities and broadening participation. This meeting was cosponsored by the ACS Committee on Minority Affairs and supported by ACS, ACR, ORAU, academia, and the chemical industry. The authors extend their sincerest gratitude to the Thurgood Marshall College Fund staff and Dr. Michael Schwartz, Managing Director at the NSF-funded Center for Sustainable Nanotechnology, for their review of the Guest Editorial for this special issue. This article references 6 other publications. This article has not yet been cited by other publications. This article references 6 other publications.

Stereochemical control of excited-state asymmetric photoreactions has been one of the most challenging topics of modern photochemistry. The short-lived character of electronically excited photosubstrates and their low activation energy barriers to form both enantiomers are the major obstacles to achieving significant enantioselectivity in excited-state asymmetric photochemistry. Recent research demonstrated that the supramolecular strategy is promising to control the stereochemical outcome of asymmetric photoreaction through relatively strong and long-lasting noncovalent interaction at both ground and excited states. In this methodology, chiral hosts/assemblies provide the chiral environment for photochemically transferring chirality to the complexed photosubstrate in both the ground and the excited states by virtue of relatively strong supramolecular interactions, such as hydrogen bonding, van der Waals, π–π, electrostatic, and hydrophobic interactions. The orientation and conformation of the photosubstrate can be critically manipulated by the supramolecular complexation to ensure the subsequent effective stereoselective photochemical conversion.

Ultrafast spectroscopy and imaging have become tools utilized by a broad range of scientists involved in materials, energy, biological, and chemical sciences. Commercialization of ultrafast spectrometers including transient absorption spectrometers, vibrational sum frequency generation spectrometers, and even multidimensional spectrometers have put these advanced spectroscopy measurements into the hands of practitioners originally outside the field of ultrafast spectroscopy. There is now a technology shift occurring in ultrafast spectroscopy, made possible by new Yb-based lasers, that is opening exciting new experiments in the chemical and physical sciences. Amplified Yb-based lasers are not only more compact and efficient than their predecessors but also, most importantly, operate at many times the repetition rate with improved noise characteristics in comparison to the previous generation of Ti:sapphire amplifier technologies. Taken together, these attributes are enabling new experiments, generating improvements to long-standing techniques, and affording the transformation of spectroscopies to microscopies. This Account aims to show that the shift to 100 kHz lasers is a transformative step in nonlinear spectroscopy and imaging, much like the dramatic expansion that occurred with the commercialization of Ti:sapphire laser systems in the 1990s. The impact of this technology will be felt across a great swath of scientific communities. We first describe the technology landscape of amplified Yb-based laser systems used in conjunction with 100 kHz spectrometers operating with shot-to-shot pulse shaping and detection. We also identify the range of different parametric conversion and supercontinuum techniques which now provide a path to making pulses of light optimal for ultrafast spectroscopy. Second, we describe specific instances from our laboratories of how the amplified Yb-based light sources and spectrometers are transformative. For multiple probe time-resolved infrared and transient 2D IR spectroscopy, the gain in temporal span and signal-to-noise enables dynamical spectroscopy measurements from femtoseconds to seconds. These gains widen the applicability of time-resolved infrared techniques across a range of topics in photochemistry, photocatalysis, and photobiology as well as lower the technical barriers to implementation in a laboratory. For 2D visible spectroscopy and microscopy with white light, as well as 2D IR imaging, the high repetition rates of these new Yb-based light sources allow one to spatially map 2D spectra while maintaining high signal-to-noise in the data. To illustrate the gains, we provide examples of imaging applications in the study of photovoltaic materials and spectroelectrochemistry.

Electrochemistry has a central role in addressing the societal issues of our time, including the United Nations’ Sustainable Development Goals (SDGs) and beyond. At a more basic level, however, elucidating the nature of electrode–electrolyte interfaces is an ongoing challenge due to many reasons, but one obvious reason is the fact that the electrode–electrolyte interface is buried by a thick liquid electrolyte layer. This fact would seem to preclude, by default, the use of many traditional characterization techniques in ultrahigh vacuum surface science due to their incompatibility with liquids. However, combined UHV-EC (ultrahigh vacuum-electrochemistry) approaches are an active area of research and provide a means of bridging the liquid environment of electrochemistry to UHV-based techniques. In short, UHV-EC approaches are able to remove the bulk electrolyte layer by performing electrochemistry in the liquid environment of electrochemistry followed by sample removal (referred to as emersion), evacuation, and then transfer into vacuum for analysis.