Your search keyword '"van der Stam W"' showing total 103 results

1. Prospects of nano-lithographic tools for the fabrication of surface-enhanced Raman spectroscopy (SERS) substrates

Author

Srivastava, K., Le-The, H., Lozeman, J.J.A., van den Berg, A., van der Stam, W., and Odijk, M.

Published

2024

2. In situ spatiotemporal characterization and analysis of chemical reactions using an ATR-integrated microfluidic reactor

Author

Sub Inorganic Chemistry and Catalysis, Inorganic Chemistry and Catalysis, Srivastava, K., Boyle, N. D., Flaman, G. T., Ramaswami, B., van den Berg, A., van der Stam, W., Burgess, I. J., Odijk, M., Sub Inorganic Chemistry and Catalysis, Inorganic Chemistry and Catalysis, Srivastava, K., Boyle, N. D., Flaman, G. T., Ramaswami, B., van den Berg, A., van der Stam, W., Burgess, I. J., and Odijk, M.

Published

2023

3. In situ spatiotemporal characterization and analysis of chemical reactions using an ATR-integrated microfluidic reactor.

Author

Srivastava, K., Boyle, N. D., Flaman, G. T., Ramaswami, B., van den Berg, A., van der Stam, W., Burgess, I. J., and Odijk, M.

Subjects

ANALYTICAL chemistry, CHEMICAL reactions, BENZYL bromide, CHEMICAL processes, SYNCHROTRON radiation

Abstract

Determining kinetic reaction parameters with great detail has been of utmost importance in the field of chemical reaction engineering. However, commonly used experimental and computational methods however are unable to provide sufficiently resolved spatiotemporal information that can aid in the process of understanding these chemical reactions. With our work, we demonstrate the use of a custom designed single-bounce ATR-integrated microfluidic reactor to obtain spatiotemporal resolution for in situ monitoring of chemical reactions. Having a single-bounce ATR accessory allows us to individually address different sensing areas, thereby providing the ability to obtain spatially and temporally resolved information. To further enhance the spatial resolution, we utilize the benefits of synchrotron IR radiation with the smallest beam spot-size ∼150 μm. An on-flow modular microreactor additionally allows us to monitor the chemical reaction in situ, where the temporal characterization can be controlled with the operational flowrate. With a unique combination of experimental measurements and numerical simulations, we characterize and analyse a model SN2 reaction. For a chemical reaction between benzyl bromide (BB) and sodium azide (SA) to produce benzyl azide (BA), we successfully show the capability of our device to determine the diffusion coefficients of BB and SA as 0.367 ± 0.115 10−9 m2 s−1 and 1.17 ± 0.723 10−9 m2 s−1, respectively. Finally, with the above characteristics of our device, we also calculate a reaction rate of k = 0.0005 (m3s−1mol−1) for the given chemical reaction. [ABSTRACT FROM AUTHOR]

Published

2023

4. ATR microreactor

Author

Srivastava, K., Boyle, N. D., Jorissen, K. F.A., Burgess, I. J., Van Der Stam, W., Van Den Berg, A., Odijk, M., Biomedical and Environmental Sensorsystems, and MESA+ Institute

Subjects

insitu reaction monitoring, mixers, 2023 OA procedure, nanofabrication, microreactor

Abstract

We report the fabrication of a microreactor with embedded internal reflection element (IRE) and herringbone (HB) micromixer. The microreactor can be used as a powerful tool for monitoring in-situ chemical reactions when combined with attenuated total internal reflection (ATR) infrared (IR) spectroscopy. In this work, a H2O/D2O model reaction was monitored as a proof of concept and the HOD product formation was spatially tracked. In addition to this, a mixing efficiency of 99% at 25 cycles was also calculated for the microreactor.

Published

2022

5. Fabrication of Si-Au nanocone-nanoparticle array for homogeneous enhancement factor in Raman scattering

Author

Srivastava, K., Jonker, D., Lafuente, M., Susarrey-Arce, A., van den Berg, A., Gardeniers, Han J.G.E., van der Stam, W., Odijk, M., Tsai, Din Ping, Tanaka, Takuo, Lu, Yu-Jung, Biomedical and Environmental Sensorsystems, MESA+ Institute, and Mesoscale Chemical Systems

Subjects

surface enhanced Raman scattering, glancing angle deposition, silicon nanocones, gold nanoparticle, plasmonics

Abstract

Gold nanoparticles (AuNPs) were the basis for the earliest research in the field of surface enhanced Raman scattering (SERS). Coupling of their surface plasmon resonances creates hot-spots of high electromagnetic intensities found to be very useful for sensing applications. However, chemically synthesized AuNPs in suspension are usually polydisperse and when arranged on a SERS substrate, lack periodic spatial organization. This leads to large variations in the enhancement factor (EF) which is detrimental to the sensing capabilities of the SERS substrate. Here, we showcase reproducible fabrication of an array of spherical AuNPs at the apices of shell isolated silicon nanocones with a homogeneous EF for SERS. The AuNPs are produced through discrete rotation glancing angle deposition of Au on shell isolated silicon nanocones (SI-SiNC) with square lattice periodicity and 250 nm pitch. By tuning the substrate tilt angle, substrate rotation angle and deposition thickness, the location and the size of the AuNPs formed can be controlled. Using this method, we successfully fabricated 60 nm AuNPs positioned at the apices of the nanocone array. Finite-Difference Time-Domain (FDTD) simulations were performed to visualize the electric field enhancement and verify conditions such as tip radius and oxide shell thickness to optimize the same. The EF was then experimentally calculated by performing SERS measurements on benzenethiol (BT) functionalized AuNPs at 400 unique points over the SI-SiNC substrate and compared to measurements of pure BT solution. A homogeneous substrate EF of (2.05 ± 0.05) ∙107 (99% confidence interval) at par with literature was calculated for the C-S in-plane deformation mode, δCS, of the BT molecule excited at 1077 cm-1. Our work highlights the advantages of nanofabrication for homogeneous SERS EF substrates.

Published

2022

6. ATR microreactor: A tool for in-situ and spatial reaction monitoring

Author

Srivastava, K., primary, Boyle, N. D., additional, Jorissen, K.F.A, additional, Burgess, I. J., additional, Van Der Stam, W., additional, Van Den Berg, A., additional, and Odijk, M., additional

Published

2022

7. Trapping and Detrapping in Colloidal Perovskite Nanoplatelets: Elucidation and Prevention of Nonradiative Processes through Chemical Treatment

Author

Vonk, S.J.W., Fridriksson, M.B., Hinterding, S.O.M., Mangnus, M.J.J., van Swieten, T.P., Grozema, F.C., Rabouw, F.T., van der Stam, W., Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, and Soft Condensed Matter and Biophysics

Abstract

Metal-halide perovskite nanocrystals show promise as the future active material in photovoltaics, lighting, and other optoelectronic applications. The appeal of these materials is largely due to the robustness of the optoelectronic properties to structural defects. The photoluminescence quantum yield (PLQY) of most types of perovskite nanocrystals is nevertheless below unity, evidencing the existence of nonradiative charge-carrier decay channels. In this work, we experimentally elucidate the nonradiative pathways in CsPbBr3 nanoplatelets, before and after chemical treatment with PbBr2 that improves the PLQY. A combination of picosecond streak camera and nanosecond time-correlated single-photon counting measurements is used to probe the excited-state dynamics over 6 orders of magnitude in time. We find that up to 40% of the nanoplatelets from a synthesis batch are entirely nonfluorescent and cannot be turned fluorescent through chemical treatment. The other nanoplatelets show fluorescence, but charge-carrier trapping leads to losses that are prevented by chemical treatment. Interestingly, even without chemical treatment, some losses due to trapping are mitigated because trapped carriers spontaneously detrap on nanosecond-to-microsecond timescales. Our analysis shows that multiple nonradiative pathways are active in perovskite nanoplatelets, which are affected differently by chemical treatment with PbBr2. More generally, our work highlights that in-depth studies using a combination of techniques are necessary to understand nonradiative pathways in fluorescent nanocrystals. Such understanding is essential to optimize synthesis and treatment procedures.

Published

2020

8. Quantitative Electrochemical Control over Optical Gain in Quantum-Dot Solids

Author

Geuchies, J.J. (author), Brynjarsson, Baldur (author), Grimaldi, G. (author), Gudjónsdóttir, S. (author), van der Stam, W. (author), Evers, W.H. (author), Houtepen, A.J. (author), Geuchies, J.J. (author), Brynjarsson, Baldur (author), Grimaldi, G. (author), Gudjónsdóttir, S. (author), van der Stam, W. (author), Evers, W.H. (author), and Houtepen, A.J. (author)

Abstract

Solution-processed quantum dot (QD) lasers are one of the holy grails of nanoscience. They are not yet commercialized because the lasing threshold is too high: one needs >1 exciton per QD, which is difficult to achieve because of fast nonradiative Auger recombination. The threshold can, however, be reduced by electronic doping of the QDs, which decreases the absorption near the band-edge, such that the stimulated emission (SE) can easily outcompete absorption. Here, we show that by electrochemically doping films of CdSe/CdS/ZnS QDs, we achieve quantitative control over the gain threshold. We obtain stable and reversible doping of more than two electrons per QD. We quantify the gain threshold and the charge carrier dynamics using ultrafast spectroelectrochemistry and achieve quantitative agreement between experiments and theory, including a vanishingly low gain threshold for doubly doped QDs. Over a range of wavelengths with appreciable gain coefficients, the gain thresholds reach record-low values of ∼1 × 10-5 excitons per QD. These results demonstrate a high level of control over the gain threshold in doped QD solids, opening a new route for the creation of cheap, solution-processable, low-threshold QD lasers., ChemE/Opto-electronic Materials, BN/Technici en Analisten

Published

2020

9. Trapping and Detrapping in Colloidal Perovskite Nanoplatelets: Elucidation and Prevention of Nonradiative Processes through Chemical Treatment

Author

Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Soft Condensed Matter and Biophysics, Vonk, S.J.W., Fridriksson, M.B., Hinterding, S.O.M., Mangnus, M.J.J., van Swieten, T.P., Grozema, F.C., Rabouw, F.T., van der Stam, W., Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Sub Soft Condensed Matter, Sub Condensed Matter and Interfaces, Soft Condensed Matter and Biophysics, Vonk, S.J.W., Fridriksson, M.B., Hinterding, S.O.M., Mangnus, M.J.J., van Swieten, T.P., Grozema, F.C., Rabouw, F.T., and van der Stam, W.

Published

2020

10. Overcoming the exciton binding energy in two-dimensional perovskite nanoplatelets by attachment of conjugated organic chromophores

Author

Gelvez Rueda, M.C. (author), Fridriksson, M.B. (author), Dubey, R. (author), Jager, W.F. (author), van der Stam, W. (author), Grozema, F.C. (author), Gelvez Rueda, M.C. (author), Fridriksson, M.B. (author), Dubey, R. (author), Jager, W.F. (author), van der Stam, W. (author), and Grozema, F.C. (author)

Abstract

In this work we demonstrate a novel approach to achieve efficient charge separation in dimensionally and dielectrically confined two-dimensional perovskite materials. Two-dimensional perovskites generally exhibit large exciton binding energies that limit their application in optoelectronic devices that require charge separation such as solar cells, photo-detectors and in photo-catalysis. Here, we show that by incorporating a strongly electron accepting moiety, perylene diimide organic chromophores, on the surface of the two-dimensional perovskite nanoplatelets it is possible to achieve efficient formation of mobile free charge carriers. These free charge carriers are generated with ten times higher yield and lifetimes of tens of microseconds, which is two orders of magnitude longer than without the peryline diimide acceptor. This opens a novel synergistic approach, where the inorganic perovskite layers are combined with functional organic chromophores in the same material to tune the properties for specific applications., ChemE/Opto-electronic Materials, ChemE/Advanced Soft Matter

Published

2020

11. Trapping and Detrapping in Colloidal Perovskite Nanoplatelets: Elucidation and Prevention of Nonradiative Processes through Chemical Treatment

Author

Vonk, Sander J.W. (author), Fridriksson, M.B. (author), Hinterding, Stijn O.M. (author), Mangnus, Mark J.J. (author), Van Swieten, Thomas P. (author), Grozema, F.C. (author), Rabouw, Freddy T. (author), van der Stam, W. (author), Vonk, Sander J.W. (author), Fridriksson, M.B. (author), Hinterding, Stijn O.M. (author), Mangnus, Mark J.J. (author), Van Swieten, Thomas P. (author), Grozema, F.C. (author), Rabouw, Freddy T. (author), and van der Stam, W. (author)

Abstract

Metal-halide perovskite nanocrystals show promise as the future active material in photovoltaics, lighting, and other optoelectronic applications. The appeal of these materials is largely due to the robustness of the optoelectronic properties to structural defects. The photoluminescence quantum yield (PLQY) of most types of perovskite nanocrystals is nevertheless below unity, evidencing the existence of nonradiative charge-carrier decay channels. In this work, we experimentally elucidate the nonradiative pathways in CsPbBr3 nanoplatelets, before and after chemical treatment with PbBr2 that improves the PLQY. A combination of picosecond streak camera and nanosecond time-correlated single-photon counting measurements is used to probe the excited-state dynamics over 6 orders of magnitude in time. We find that up to 40% of the nanoplatelets from a synthesis batch are entirely nonfluorescent and cannot be turned fluorescent through chemical treatment. The other nanoplatelets show fluorescence, but charge-carrier trapping leads to losses that are prevented by chemical treatment. Interestingly, even without chemical treatment, some losses due to trapping are mitigated because trapped carriers spontaneously detrap on nanosecond-to-microsecond timescales. Our analysis shows that multiple nonradiative pathways are active in perovskite nanoplatelets, which are affected differently by chemical treatment with PbBr2. More generally, our work highlights that in-depth studies using a combination of techniques are necessary to understand nonradiative pathways in fluorescent nanocrystals. Such understanding is essential to optimize synthesis and treatment procedures., ChemE/Opto-electronic Materials

Published

2020

12. Interplay between surface chemistry, precursor reactivity, and temperature determines outcome of ZnS shelling reactions on CuInS2 nanocrystals

Author

Berends, A.C., van der Stam, W., Hofmann, Jan Philipp, Bladt, Eva, Meeldijk, J.D., Bals, Sara, de Mello-Donega, C., Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, and Inorganic Materials & Catalysis

Subjects

Photoluminescence, Absorption spectroscopy, Chemistry, Physics, General Chemical Engineering, Alloy, 02 engineering and technology, General Chemistry, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Article, 0104 chemical sciences, Colloid, Nanocrystal, Chemical engineering, Etching, Materials Chemistry, engineering, Reactivity (chemistry), Absorption (chemistry), 0210 nano-technology

Abstract

ZnS shelling of I-III-VI2 nanocrystals (NCs) invariably leads to blue-shifts in both the absorption and photoluminescence spectra. These observations imply that the outcome of ZnS shelling reactions on I-III-VI2 colloidal NCs results from a complex interplay between several processes taking place in solution, at the surface of, and within the seed NC. However, a fundamental understanding of the factors determining the balance between these different processes is still lacking. In this work, we address this need by investigating the impact of precursor reactivity, reaction temperature, and surface chemistry (due to the washing procedure) on the outcome of ZnS shelling reactions on CuInS2 NCs using a seeded growth approach. We demonstrate that low reaction temperatures (150 °C) favor etching, cation exchange, and alloying regardless of the precursors used. Heteroepitaxial shell overgrowth becomes the dominant process only if reactive S- and Zn-precursors (S-ODE/OLAM and ZnI2) and high reaction temperatures (210 °C) are used, although a certain degree of heterointerfacial alloying still occurs. Remarkably, the presence of residual acetate at the surface of CIS seed NCs washed with ethanol is shown to facilitate heteroepitaxial shell overgrowth, yielding for the first time CIS/ZnS core/shell NCs displaying red-shifted absorption spectra, in agreement with the spectral shifts expected for a type-I band alignment. The insights provided by this work pave the way toward the design of improved synthesis strategies to CIS/ZnS core/shell and alloy NCs with tailored elemental distribution profiles, allowing precise tuning of the optoelectronic properties of the resulting materials.

Published

2018

13. Fabrication of Si-Au nanocone-nanoparticle array for homogeneous enhancement factor in Raman scattering

Author

Tsai, Din Ping, Tanaka, Takuo, Lu, Yu-Jung, Srivastava, K., Jonker, D., Lafuente, M., Susarrey-Arce, A., van den Berg, A., Gardeniers, Han J. G. E., van der Stam, W., and Odijk, M.

Published

2022

14. On the Stability of Permanent Electrochemical Doping of Quantum Dot, Fullerene, and Conductive Polymer Films in Frozen Electrolytes for Use in Semiconductor Devices

Author

Gudjónsdóttir, S. (author), van der Stam, W. (author), Koopman, Christel (author), Kwakkenbos, Bob (author), Evers, W.H. (author), Houtepen, A.J. (author), Gudjónsdóttir, S. (author), van der Stam, W. (author), Koopman, Christel (author), Kwakkenbos, Bob (author), Evers, W.H. (author), and Houtepen, A.J. (author)

Abstract

Semiconductor films that allow facile ion transport can be electronically doped via electrochemistry, where the amount of injected charge can be controlled by the potential applied. To apply electrochemical doping to the design of semiconductor devices, the injected charge has to be stabilized to avoid unintentional relaxation back to the intrinsic state. Here, we investigate methods to increase the stability of electrochemically injected charges in thin films of a wide variety of semiconductor materials, namely inorganic semiconductors (ZnO NCs, CdSe NCs, and CdSe/CdS core/shell NCs) and organic semiconductors (P3DT, PCBM, and C60). We show that by charging the semiconductors at elevated temperatures in solvents with melting points above room temperature, the charge stability at room temperature increases greatly, from seconds to days. At reduced temperature (-75 °C when using succinonitrile as electrolyte solvent) the injected charge becomes entirely stable on the time scale of our experiments (up to several days). Other high melting point solvents such as dimethyl sulfone, ethylene carbonate, and poly(ethylene glycol) (PEG) also offer increased charge stability at room temperature. Especially the use of PEG increases the room temperature charge stability by several orders of magnitude compared to using acetonitrile. We discuss how this improvement of the charge stability is related to the immobilization of electrolyte ions and impurities. While the electrolyte ions are immobilized, conductivity measurements show that electrons in the semiconductor films remain mobile. These results highlight the potential of using solidified electrolytes to stabilize injected charges, which is a promising step toward making semiconductor devices based on electrochemically doped semiconductor thin films., ChemE/Chemical Engineering, ChemE/Opto-electronic Materials, BN/Technici en Analisten

Published

2019

15. Electrochemical Modulation of the Photophysics of Surface-Localized Trap States in Core/Shell/(Shell) Quantum Dot Films

Author

van der Stam, W. (author), Grimaldi, G. (author), Geuchies, J.J. (author), Gudjónsdóttir, S. (author), Van Uffelen, Pieter T. (author), Van Overeem, Mandy (author), Brynjarsson, Baldur (author), Kirkwood, N.R.M. (author), Houtepen, A.J. (author), van der Stam, W. (author), Grimaldi, G. (author), Geuchies, J.J. (author), Gudjónsdóttir, S. (author), Van Uffelen, Pieter T. (author), Van Overeem, Mandy (author), Brynjarsson, Baldur (author), Kirkwood, N.R.M. (author), and Houtepen, A.J. (author)

Abstract

In this work, we systematically study the spectroelectrochemical response of CdSe quantum dots (QDs), CdSe/CdS core/shell QDs with varying CdS shell thicknesses, and CdSe/CdS/ZnS core/shell/shell QDs in order to elucidate the influence of localized surface trap states on the optoelectronic properties. By correlating the differential absorbance and the photoluminescence upon electrochemically raising the Fermi level, we reveal that trap states near the conduction band (CB) edge give rise to nonradiative recombination pathways regardless of the CdS shell thickness, evidenced by quenching of the photoluminescence before the CB edge is populated with electrons. This points in the direction of shallow trap states localized on the CdS shell surface that give rise to nonradiative recombination pathways. We suggest that these shallow trap states reduce the quantum yield because of enhanced hole trapping when the Fermi level is raised electrochemically. We show that these shallow trap states are removed when additional wide band gap ZnS shells are grown around the CdSe/CdS core/shell QDs., ChemE/Opto-electronic Materials

Published

2019

16. Spectroscopic Evidence for the Contribution of Holes to the Bleach of Cd-Chalcogenide Quantum Dots

Author

Grimaldi, G. (author), Geuchies, J.J. (author), van der Stam, W. (author), du Fossé, I. (author), Brynjarsson, Baldur (author), Kirkwood, N.R.M. (author), Kinge, S.S. (author), Siebbeles, L.D.A. (author), Houtepen, A.J. (author), Grimaldi, G. (author), Geuchies, J.J. (author), van der Stam, W. (author), du Fossé, I. (author), Brynjarsson, Baldur (author), Kirkwood, N.R.M. (author), Kinge, S.S. (author), Siebbeles, L.D.A. (author), and Houtepen, A.J. (author)

Abstract

In transient absorption (TA) measurements on Cd-chalcogenide quantum dots (QDs), the presence of a band-edge (BE) bleach signal is commonly attributed entirely to conduction-band electrons in the 1S(e) state, neglecting contributions from BE holes. While this has been the accepted view for more than 20 years, and has often been used to distinguish electron and hole kinetics, the reason for the absence of a hole contribution to the BE-bleach has remained unclear. Here, we show with three independent experiments that holes do in fact have a significant impact on the BE-bleach of well-passivated Cd-chalcogenide QD samples. Transient absorption experiments on high photoluminescence quantum yield CdSe/CdS/ZnS core-shell-shell QDs clearly show an increase of the band-edge bleach as holes cool down to the band edge. The relative contribution of electron-to-hole bleach is 2:1, as predicted by theory. The same measurements on core-only CdSe QDs with a lower quantum yield do not show a contribution of holes to the band-edge bleach. We assign the lack of hole bleach to the presence of ultrafast hole trapping in samples with insufficient passivation of the QD surface. In addition, we show measurements of optical gain in core-shell-shell QD solutions, providing clear evidence of a significant hole contribution to the BE transient absorption signal. Finally, we present spectroelectrochemical measurements on CdTe QDs films, showing the presence of a BE-bleach for both electron and hole injections. The presence of a contribution of holes to the bleach in passivated Cd-chalcogenides QDs bears important implications for quantitative studies on optical gain as well as for TA determinations of carrier dynamics., ChemE/Opto-electronic Materials

Published

2019

17. Interplay between Surface Chemistry, Precursor Reactivity, and Temperature Determines Outcome of ZnS Shelling Reactions on CuInS2 Nanocrystals

Author

Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, Berends, A.C., van der Stam, W., Hofmann, Jan Philipp, Bladt, Eva, Meeldijk, J.D., Bals, Sara, de Mello-Donega, C., Sub Condensed Matter and Interfaces, Sub Inorganic Chemistry and Catalysis, Condensed Matter and Interfaces, Inorganic Chemistry and Catalysis, Berends, A.C., van der Stam, W., Hofmann, Jan Philipp, Bladt, Eva, Meeldijk, J.D., Bals, Sara, and de Mello-Donega, C.

Published

2018

18. Spectroelectrochemical Signatures of Surface Trap Passivation on CdTe Nanocrystals

Author

van der Stam, W. (author), du Fossé, I. (author), Grimaldi, G. (author), Monchen, J.O.V. (author), Kirkwood, Nicholas (author), Houtepen, A.J. (author), van der Stam, W. (author), du Fossé, I. (author), Grimaldi, G. (author), Monchen, J.O.V. (author), Kirkwood, Nicholas (author), and Houtepen, A.J. (author)

Abstract

The photoluminescence (PL) quantum yield of semiconductor nanocrystals (NCs) is hampered by in-gap trap states due to dangling orbitals on the surface of the nanocrystals. While crucial for the rational design of nanocrystals, the understanding of the exact origin of trap states remains limited. Here, we treat CdTe nanocrystal films with different metal chloride salts and we study the effect on their optical properties with in situ spectroelectrochemistry, recording both changes in absorption and photoluminescence. For untreated CdTe NC films we observe a strong increase in the PL intensity as the Fermi-level is raised electrochemically and trap states in the bandgap become occupied with electrons. Upon passivation of these in-gap states we observe an increase in the steady state PL and, for the best treatments, we observe that the PL no longer depends on the position of the Fermi level in the band gap, demonstrating the effective removal of trap states. The most effective treatment is obtained for Z-type passivation with CdCl2, for which the steady state PL increased by a factor 40 and the PL intensity became nearly unaffected by the applied potential. X-ray Photoelectron Spectroscopy measurements show that treatment with ZnCl2 mainly leads to X-type passivation with chloride ions, which increased the PL intensity by a factor four and made the PL less susceptible to modulation by applying a potential with respect to unpassivated nanocrystal films. We elucidate the spectroelectrochemical signatures of trap states within the bandgap and conclude that undercoordinated Te at the surface constitutes the largest contribution to in-gap trap states, but that other surface states that likely originate on Cd atoms should also be considered., ChemE/Opto-electronic Materials, Applied Sciences

Published

2018

19. Finding and Fixing Traps in II-VI and III-V Colloidal Quantum Dots: The Importance of Z-Type Ligand Passivation

Author

Kirkwood, N.R.M. (author), Monchen, J.O.V. (author), Crisp, R.W. (author), Grimaldi, G. (author), Bergstein, Huub A.C. (author), du Fossé, I. (author), van der Stam, W. (author), Infante, Ivan (author), Houtepen, A.J. (author), Kirkwood, N.R.M. (author), Monchen, J.O.V. (author), Crisp, R.W. (author), Grimaldi, G. (author), Bergstein, Huub A.C. (author), du Fossé, I. (author), van der Stam, W. (author), Infante, Ivan (author), and Houtepen, A.J. (author)

Abstract

Energy levels in the band gap arising from surface states can dominate the optical and electronic properties of semiconductor nanocrystal quantum dots (QDs). Recent theoretical work has predicted that such trap states in II-VI and III-V QDs arise only from two-coordinated anions on the QD surface, offering the hypothesis that Lewis acid (Z-type) ligands should be able to completely passivate these anionic trap states. In this work, we provide experimental support for this hypothesis by demonstrating that Z-type ligation is the primary cause of PL QY increase when passivating undercoordinated CdTe QDs with various metal salts. Optimized treatments with InCl3 or CdCl2 afford a near-unity (>90%) photoluminescence quantum yield (PL QY), whereas other metal halogen or carboxylate salts provide a smaller increase in PL QY as a result of weaker binding or steric repulsion. The addition of non-Lewis acidic ligands (amines, alkylammonium chlorides) systematically gives a much smaller but non-negligible increase in the PL QY. We discuss possible reasons for this result, which points toward a more complex and dynamic QD surface. Finally we show that Z-type metal halide ligand treatments also lead to a strong increase in the PL QY of CdSe, CdS, and InP QDs and can increase the efficiency of sintered CdTe solar cells. These results show that surface anions are the dominant source of trap states in II-VI and III-V QDs and that passivation with Lewis acidic Z-type ligands is a general strategy to fix those traps. Our work also provides a method to tune the PL QY of QD samples from nearly zero up to near-unity values, without the need to grow epitaxial shells., ChemE/Opto-electronic Materials

Published

2018

20. Tuning and Probing the Distribution of Cu+ and Cu2+ Trap States Responsible for Broad-Band Photoluminescence in CuInS2 Nanocrystals

Author

van der Stam, W. (author), de Graaf, M. (author), Gudjónsdóttir, S. (author), Geuchies, J.J. (author), Dijkema, J.J. (author), Kirkwood, N.R.M. (author), Evers, W.H. (author), Longo, Alessandro (author), Houtepen, A.J. (author), van der Stam, W. (author), de Graaf, M. (author), Gudjónsdóttir, S. (author), Geuchies, J.J. (author), Dijkema, J.J. (author), Kirkwood, N.R.M. (author), Evers, W.H. (author), Longo, Alessandro (author), and Houtepen, A.J. (author)

Abstract

The processes that govern radiative recombination in ternary CuInS2 (CIS) nanocrystals (NCs) have been heavily debated, but recently, several research groups have come to the same conclusion that a photoexcited electron recombines with a localized hole on a Cu-related trap state. Furthermore, it has been observed that single CIS NCs display narrower photoluminescence (PL) line widths than the ensemble, which led to the conclusion that within the ensemble there is a distribution of Cu-related trap states responsible for PL. In this work, we probe this trap-state distribution with in situ photoluminescence spectroelectrochemistry. We find that Cu2+ states result in individual "dark" nanocrystals, whereas Cu+ states result in "bright" NCs. Furthermore, we show that we can tune the PL position, intensity, and line width in a cyclic fashion by injecting or removing electrons from the trap-state distribution, thereby converting a subset of "dark" Cu2+ containing NCs into "bright" Cu+ containing NCs and vice versa. The electrochemical injection of electrons results in brightening, broadening, and a red shift of the PL, in line with the activation of a broad distribution of "dark" NCs (Cu2+ states) into "bright" NCs (Cu+ states) and a rise of the Fermi level within the ensemble trap-state distribution. The opposite trend is observed for electrochemical oxidation of Cu+ states into Cu2+. Our work shows that there is a direct correlation between the line width of the ensemble Cu+/Cu2+ trap-state distribution and the characteristic broad-band PL feature of CIS NCs and between Cu2+ cations in the photoexcited state (bright) and in the electrochemically oxidized ground state (dark)., ChemE/Opto-electronic Materials, Applied Sciences, BN/Technici en Analisten

Published

2018

21. The Role of Dopant Ions on Charge Injection and Transport in Electrochemically Doped Quantum Dot Films

Author

Gudjónsdóttir, S. (author), van der Stam, W. (author), Kirkwood, Nicholas (author), Evers, W.H. (author), Houtepen, A.J. (author), Gudjónsdóttir, S. (author), van der Stam, W. (author), Kirkwood, Nicholas (author), Evers, W.H. (author), and Houtepen, A.J. (author)

Abstract

Control over the charge density is very important for implementation of colloidal semiconductor nanocrystals into various optoelectronic applications. A promising approach to dope nanocrystal assemblies is charge injection by electrochemistry, in which the charge compensating electrolyte ions can be regarded as external dopant ions. To gain insight into the doping mechanism and the role of the external dopant ions, we investigate charge injection in ZnO nanocrystal assemblies for a large series of charge compensating electrolyte ions with spectroelectrochemical and electrochemical transistor measurements. We show that charge injection is limited by the diffusion of cations in the nanocrystal films as their diffusion coefficient are found to be ∼7 orders of magnitude lower than those of electrons. We further show that the rate of charge injection depends strongly on the cation size and cation concentration. Strikingly, the onset of electron injection varies up to 0.4 V, depending on the size of the electrolyte cation. For the small ions Li+ and Na+ the onset is at significantly less negative potentials. For larger ions (K+, quaternary ammonium ions) the onset is always at the same, more negative potential, suggesting that intercalation may take place for Li+ and Na+. Finally, we show that the nature of the charge compensating cation does not affect the source-drain electronic conductivity and mobility, indicating that shallow donor levels from intercalating ions fully hybridize with the quantum confined energy levels and that the reorganization energy due to intercalating ions does not strongly affect electron transport in these nanocrystal assemblies., ChemE/Opto-electronic Materials, ChemE/Chemical Engineering, BN/Technici en Analisten

Published

2018

22. Interplay between Surface Chemistry, Precursor Reactivity, and Temperature Determines Outcome of ZnS Shelling Reactions on CuInS2 Nanocrystals

Author

Berends, Anne C. (author), van der Stam, W. (author), Hofmann, Jan P. (author), Bladt, Eva (author), Meeldijk, Johannes D. (author), Bals, Sara (author), De Mello Donega, Celso (author), Berends, Anne C. (author), van der Stam, W. (author), Hofmann, Jan P. (author), Bladt, Eva (author), Meeldijk, Johannes D. (author), Bals, Sara (author), and De Mello Donega, Celso (author)

Abstract

ZnS shelling of I-III-VI2 nanocrystals (NCs) invariably leads to blue-shifts in both the absorption and photoluminescence spectra. These observations imply that the outcome of ZnS shelling reactions on I-III-VI2 colloidal NCs results from a complex interplay between several processes taking place in solution, at the surface of, and within the seed NC. However, a fundamental understanding of the factors determining the balance between these different processes is still lacking. In this work, we address this need by investigating the impact of precursor reactivity, reaction temperature, and surface chemistry (due to the washing procedure) on the outcome of ZnS shelling reactions on CuInS2 NCs using a seeded growth approach. We demonstrate that low reaction temperatures (150 °C) favor etching, cation exchange, and alloying regardless of the precursors used. Heteroepitaxial shell overgrowth becomes the dominant process only if reactive S- and Zn-precursors (S-ODE/OLAM and ZnI2) and high reaction temperatures (210 °C) are used, although a certain degree of heterointerfacial alloying still occurs. Remarkably, the presence of residual acetate at the surface of CIS seed NCs washed with ethanol is shown to facilitate heteroepitaxial shell overgrowth, yielding for the first time CIS/ZnS core/shell NCs displaying red-shifted absorption spectra, in agreement with the spectral shifts expected for a type-I band alignment. The insights provided by this work pave the way toward the design of improved synthesis strategies to CIS/ZnS core/shell and alloy NCs with tailored elemental distribution profiles, allowing precise tuning of the optoelectronic properties of the resulting materials., ChemE/Opto-electronic Materials

Published

2018

23. Switching between Plasmonic and Fluorescent Copper Sulfide Nanocrystals

Author

van der Stam, W. (author), Gudjónsdóttir, S. (author), Evers, W.H. (author), Houtepen, A.J. (author), van der Stam, W. (author), Gudjónsdóttir, S. (author), Evers, W.H. (author), and Houtepen, A.J. (author)

Abstract

Control over the doping density in copper sulfide nanocrystals is of great importance and determines its use in optoelectronic applications such as NIR optical switches and photovoltaic devices. Here, we demonstrate that we can reversibly control the hole carrier density (varying from >1022 cm-3 to intrinsic) in copper sulfide nanocrystals by electrochemical methods. We can control the type of charge injection, i.e., capacitive charging or ion intercalation, via the choice of the charge compensating cation (e.g., ammonium salts vs Li+). Further, the type of intercalating ion determines whether the charge injection is fully reversible (for Li+) or leads to permanent changes in doping density (for Cu+). Using fully reversible lithium intercalation allows us to switch between thin films of covellite CuS NCs (Eg = 2.0 eV, hole density 1022 cm-3, strong localized surface plasmon resonance) and low-chalcocite CuLiS NCs (Eg = 1.2 eV, intrinsic, no localized surface plasmon resonance), and back. Electrochemical Cu+ ion intercalation leads to a permanent phase transition to intrinsic low-chalcocite Cu2S nanocrystals that display air stable fluorescence, centered around 1050 nm (fwhm â145 meV, PLQY ca. 1.8%), which is the first observation of narrow near-infrared fluorescence for copper sulfide nanocrystals. The dynamic control over the hole doping density and fluorescence of copper sulfide nanocrystals presented in this work and the ability to switch between plasmonic and fluorescent semiconductor nanocrystals might lead to their successful implementation into photovoltaic devices, NIR optical switches and smart windows., ChemE/Opto-electronic Materials, BN/Technici en Analisten

Published

2017

24. Tailoring on the nanoscale: Control over size, shape, composition and self-assembly of copper chalcogenide nanocrystals

Author

van der Stam, W., Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Meijerink, Andries, de Mello-Donega, Celso, and University Utrecht

Subjects

nanocrystals, synthesis, heterostructures, earth-abundant, colloidal, cation exchange, self-assembly

Abstract

Semiconductor materials are commonplace in everyday life and most people could not live without them. Recently, colloidal semiconductor nanocrystals have gained a lot of interest, due to the possibility to precisely tune their optoelectronic properties by tuning the size and shape of the nanocrystals. Nowadays, such colloidal semiconductor nanocrystals show potential use in applications such as television screens, solar cells and light-emitting diodes (LEDs). However, the integration of semiconductor nanocrystals into devices is severely hindered by toxicity issues concerning the use of heavy metals such as Cd and Pb. Copper chalcogenide nanomaterials offer an interesting alternative, since they have shown to possess similar (e.g. photoluminescence), or novel (e.g. plasmonics), properties and are comprised of less toxic and more abundant elements such as Cu, Zn and Sn. Although a lot of research has been performed to obtain the same level of mastery over the synthesis of Cu-chalcogenide nanocrystals, as is currently available for Cd- and Pb-chalcogenide nanocrystals, and hence precisely tune the optoelectronic properties of colloidal Cu chalcogenide nanomaterials, there is still room for improvement. In this thesis, synthetic methodologies are discussed, that were developed to gain control over the synthesis and the optoelectronic properties of colloidal Cu-chalcogenide nanomaterials, with special emphasis on alternative synthesis approaches. This thesis shows that by controlling the size, shape, composition and interactions of colloidal semiconductor nanocrystals, tailored materials can be prepared with high precision, which should possibly lead to unprecedented properties that will impact on a number of applications.

Published

2016

25. Near-infrared Emitting CulnSe2/CulnS2 Dot Core/Rod Shell Heteronanorods by Sequential Cation Exchange

Author

van der Stam, W., Bladt, Eva, Rabouw, F.T., Bals, S., de Mello-Donega, C., Condensed Matter and Interfaces, and Sub Condensed Matter and Interfaces

Subjects

heteronanocrystals, Taverne, cation exchange, quantum dots, copper indium chalcogenide, nanorods

Abstract

The direct synthesis of heteronanocrystals (HNCs) combining different ternary semiconductors is challenging and has not yet been successful. Here, we report a sequential topotactic cation exchange (CE) pathway that yields CuInSe2/CuInS2 dot core/rod shell nanorods with near-infrared luminescence. In our approach, the Cu+ extraction rate is coupled to the In3+ incorporation rate by the use of a stoichiometric trioctylphosphine-InCl3 complex, which fulfills the roles of both In-source and Cu-extracting agent. In this way, Cu+ ions can be extracted by trioctylphosphine ligands only when the In–P bond is broken. This results in readily available In3+ ions at the same surface site from which the Cu+ is extracted, making the process a direct place exchange reaction and shifting the overall energy balance in favor of the CE. Consequently, controlled cation exchange can occur even in large and anisotropic heterostructured nanocrystals with preservation of the size, shape, and heterostructuring of the template NCs into the product NCs. The cation exchange is self-limited, stopping when the ternary core/shell CuInSe2/CuInS2 composition is reached. The method is very versatile, successfully yielding a variety of luminescent CuInX2 (X = S, Se, and Te) quantum dots, nanorods, and HNCs, by using Cd-chalcogenide NCs and HNCs as templates. The approach reported here thus opens up routes toward materials with unprecedented properties, which would otherwise remain inaccessible.

Published

2015

26. Near-infrared emitting <tex>CuInSe_{2}/CuInS_{2}$</tex> dot core/rod shell heteronanorods by sequential cation exchange

Author

van der Stam, W., Bladt, Eva, Rabouw, F.T., Bals, S., de Mello-Donega, C., Condensed Matter and Interfaces, and Sub Condensed Matter and Interfaces

Subjects

Chemistry, Physics, Inorganic chemistry, General Engineering, Trioctylphosphine, cation exchange, General Physics and Astronomy, quantum dots, Article, Ion, Crystallography, chemistry.chemical_compound, Template, heteronanocrystals, Nanocrystal, Quantum dot, Taverne, General Materials Science, Nanorod, copper indium chalcogenide, Luminescence, Ternary operation, nanorods, Engineering sciences. Technology

Abstract

The direct synthesis of heteronanocrystals (HNCs) combining different ternary semiconductors is challenging and has not yet been successful. Here, we report a sequential topotactic cation exchange (CE) pathway that yields CuInSe2/CuInS2 dot core/rod shell nanorods with near-infrared luminescence. In our approach, the Cu(+) extraction rate is coupled to the In(3+) incorporation rate by the use of a stoichiometric trioctylphosphine-InCl3 complex, which fulfills the roles of both In-source and Cu-extracting agent. In this way, Cu(+) ions can be extracted by trioctylphosphine ligands only when the In-P bond is broken. This results in readily available In(3+) ions at the same surface site from which the Cu(+) is extracted, making the process a direct place exchange reaction and shifting the overall energy balance in favor of the CE. Consequently, controlled cation exchange can occur even in large and anisotropic heterostructured nanocrystals with preservation of the size, shape, and heterostructuring of the template NCs into the product NCs. The cation exchange is self-limited, stopping when the ternary core/shell CuInSe2/CuInS2 composition is reached. The method is very versatile, successfully yielding a variety of luminescent CuInX2 (X = S, Se, and Te) quantum dots, nanorods, and HNCs, by using Cd-chalcogenide NCs and HNCs as templates. The approach reported here thus opens up routes toward materials with unprecedented properties, which would otherwise remain inaccessible.

Published

2015

27. Prospects of Colloidal Copper Chalcogenide Nanocrystals

Author

van der Stam, W., Berends, A.C., de Mello-Donega, Celso, van der Stam, W., Berends, A.C., and de Mello-Donega, Celso

Abstract

Over the past few years, colloidal copper chalcogenide nanocrystals (NCs) have emerged as promising alternatives to conventional Cd and Pb chalcogenide NCs. Owing to their wide size, shape, and composition tunability, Cu chalcogenide NCs hold great promise for several applications, such as photovoltaics, lighting and displays, and biomedical imaging. They also offer characteristics that are unparalleled by Cd and Pb chalcogenide NCs, such as plasmonic properties. Moreover, colloidal Cu chalcogenide NCs have low toxicity, potentially lower costs, and excellent colloidal stability. This makes them attractive materials for the large-scale deployment of inexpensive, sustainable, and environmentally benign solution-processed devices. Nevertheless, the synthesis of colloidal Cu chalcogenide NCs, especially that of ternary and quaternary compositions, has yet to reach the same level of mastery as that available for the prototypical Cd chalcogenide based NCs. This review provides a concise overview of this rapidly advancing field, sketching the state of the art and highlighting the key challenges. We discuss recent developments in the synthesis of size-, shape-, and composition-controlled NCs of Cu chalcogenides, with emphasis in strategies to circumvent the limitations arising from the need to precisely balance the reactivities of multiple precursors in synthesizing ternary and quaternary compositions. In this respect, we show that topotactic cation-exchange reactions are a promising alternative route to complex multinary Cu chalcogenide NCs and hetero-NCs, which are not attainable by conventional routes. The properties and potential applications of Cu chalcogenide NCs and hetero-NCs are also addressed.

Published

2016

28. Prospects of Colloidal Copper Chalcogenide Nanocrystals

Author

Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, van der Stam, W., Berends, A.C., de Mello-Donega, Celso, Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, van der Stam, W., Berends, A.C., and de Mello-Donega, Celso

Published

2016

29. Tailoring on the nanoscale: Control over size, shape, composition and self-assembly of copper chalcogenide nanocrystals

Author

Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Meijerink, Andries, de Mello-Donega, Celso, van der Stam, W., Sub Condensed Matter and Interfaces, Condensed Matter and Interfaces, Meijerink, Andries, de Mello-Donega, Celso, and van der Stam, W.

Published

2016

30. In situ probing of stack-templated growth of ultrathin Cu2-xS nanosheets

Author

Van Der Stam, W., Rabouw, F.T., Geuchies, J.J., Berends, A.C., Hinterding, S.O.M., Geitenbeek, R.G., Van Der Lit, J., Prévost, S., Petukhov, A.V., de Mello Donegá, C., Van Der Stam, W., Rabouw, F.T., Geuchies, J.J., Berends, A.C., Hinterding, S.O.M., Geitenbeek, R.G., Van Der Lit, J., Prévost, S., Petukhov, A.V., and de Mello Donegá, C.

Abstract

Ultrathin two-dimensional (2D) nanomaterials have attracted intense research efforts due to their extraordinary optoelectronic properties. However, the nucleation and growth mechanisms of 2D colloidal nanosheets are still poorly understood. Here, we follow the formation of ultrathin colloidal Cu2-xS nanosheets by in situ small-angle X-ray scattering. While thermal decomposition of copper-dodecanethiolates produces spheroidal Cu2-xS nanocrystals, the addition of chloride to the reaction mixture results in 2 nm thick Cu2-xS nanosheets with well-defined shape and size. Our results show that chloride stabilizes stacks of lamellar copper-thiolate supramolecular complexes, so that they remain intact beyond the onset of Cu2-xS nucleation at 230 °C, leading to 2D-constrained stack-templated nucleation and growth. The face-to-face stacking of the nanosheets reinforces the 2D constraints imposed by the lamellar soft template, since it prevents internanosheet mass transport and nanosheet coalescence, thereby inhibiting growth in the thickness direction and allowing only for lateral growth. Our work thus provides novel insights into soft-templating formation mechanisms of ultrathin colloidal nanosheets, which may be exploited for other metal sulfide compositions.

Published

2016

31. Oleic acid-induced atomic alignment of ZnS polyhedral nanocrystals

Author

van der Stam, W., Rabouw, F.T., Vonk, S.J.W., Geuchies, J.J., Ligthart, H., Petukhov, A.V., de Mello Donega, C., van der Stam, W., Rabouw, F.T., Vonk, S.J.W., Geuchies, J.J., Ligthart, H., Petukhov, A.V., and de Mello Donega, C.

Abstract

Ordered two-dimensional (2D) superstructures of colloidal nanocrystals (NCs) can be tailored by the size, shape, composition, and surface chemistry of the NC building blocks, which can give directionality to the resulting superstructure geometry. The exact formation mechanism of 2D NC superstructures is however not yet fully understood. Here, we show that oleic acid (OA) ligands induce atomic alignment of wurtzite ZnS bifrustum-shaped NCs. We find that in the presence of OA ligands the {002} facets of the ZnS bifrustums preferentially adhere to the liquid-air interface. Furthermore, OA ligands induce inter-NC interactions that also orient the NCs in the plane of the liquid-air interface, resulting in atomically aligned 2D superstructures. We follow the self-assembly process in real-time with in situ grazing incidence small-angle X-ray scattering and find that the NCs form a hexagonal superstructure at early stages after which they come closer over time, resulting in a close-packed NC superstructure. Our results demonstrate the profound influence that surface ligands have on the directionality of 2D NC superstructures and highlight the importance of detailed in situ studies in order to understand the self-assembly of NCs into 2D superstructures.

Published

2016

32. Prospects of Colloidal Copper Chalcogenide Nanocrystals

Author

Condensed Matter and Interfaces, Sub Condensed Matter and Interfaces, van der Stam, W., Berends, A.C., de Mello-Donega, Celso, Condensed Matter and Interfaces, Sub Condensed Matter and Interfaces, van der Stam, W., Berends, A.C., and de Mello-Donega, Celso

Published

2016

33. Near-infrared Emitting CulnSe2/CulnS2 Dot Core/Rod Shell Heteronanorods by Sequential Cation Exchange

Author

Condensed Matter and Interfaces, Sub Condensed Matter and Interfaces, van der Stam, W., Bladt, Eva, Rabouw, F.T., Bals, S., de Mello-Donega, C., Condensed Matter and Interfaces, Sub Condensed Matter and Interfaces, van der Stam, W., Bladt, Eva, Rabouw, F.T., Bals, S., and de Mello-Donega, C.

Published

2015

34. Interrogation of Oxidative Pulsed Methods for the Stabilization of Copper Electrodes for CO 2 Electrolysis.

Author

Kok J, de Ruiter J, van der Stam W, and Burdyny T

Abstract

Using copper (Cu) as an electrocatalyst uniquely produces multicarbon products (C 2+ -products) during the CO 2 reduction reaction (CO2RR). However, the CO2RR stability of Cu is presently 3 orders of magnitude shorter than required for commercial operation. One means of substantially increasing Cu catalyst lifetimes is through periodic oxidative processes, such as cathodic-anodic pulsing. Despite 100-fold improvements, these oxidative methods only delay, but do not circumvent, degradation. Here, we provide an interrogation of chemical and electrochemical Cu oxidative processes to identify the mechanistic processes leading to stable CO2RR through electrochemical and in situ Raman spectroscopy measurements. We first examine chemical oxidation using an open-circuit potential (OCP), identifying that copper oxidation is regulated by the transient behavior of the OCP curve and limited by the rate of the oxygen reduction reaction (ORR). Increasing O 2 flux to the cathode subsequently increased ORR rates, both extending lifetimes and reducing "off" times by 3-fold. In a separate approach, the formation of Cu 2 O is achieved through electrochemical oxidation. Here, we establish the minimum electrode potentials required for fast Cu oxidation (-0.28 V vs Ag/AgCl, 1 M KHCO 3 ) by accounting for transient local pH changes and tracking oxidation charge transfer. Lastly, we performed a stability test resulting in a 20-fold increase in stable ethylene production versus the continuous case, finding that spatial copper migration is slowed but not mitigated by oxidative pulsing approaches alone.

Published

2024

35. Luminescence Thermometry Probes Local Heat Effects at the Platinum Electrode Surface during Alkaline Water Electrolysis.

Author

Jacobs TS, Park S, Schönig M, Weckhuysen BM, Koper MTM, and van der Stam W

Abstract

Accurate determination of the temperature dynamics at the electrode surface is crucial for advancing electrocatalysis, particularly in the development of stable materials that aid energy conversion and storage technologies. Here, lanthanide-based in situ luminescence thermometry was used to probe local heat effects at the platinum electrode surface during alkaline water electrolysis. It is demonstrated that the oxygen evolution reaction (OER) induces a more significant temperature increase compared to the hydrogen evolution reaction (HER) under the same electrochemical conditions. This difference is attributed to variations in overpotential heating and local effects on Joule heating. Furthermore, local heat effects are not observed at increased electrolyte concentrations during the HER, whereas substantial temperature variations (up to 2 K) are detected for the OER at higher electrolyte concentrations. Our observations highlight the potential of in situ luminescence thermometry to measure interfacial temperature effects during electrocatalytic reactions., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

36. Alternative nano-lithographic tools for shell-isolated nanoparticle enhanced Raman spectroscopy substrates.

Author

Srivastava K, Jacobs TS, Ostendorp S, Jonker D, Brzesowsky FA, Susarrey-Arce A, Gardeniers H, Wilde G, Weckhuysen BM, van den Berg A, van der Stam W, and Odijk M

Abstract

Chemically synthesized metal nanoparticles (MNPs) have been widely used as surface-enhanced Raman spectroscopy (SERS) substrates for monitoring catalytic reactions. In some applications, however, the SERS MNPs, besides being plasmonically active, can also be catalytically active and result in Raman signals from undesired side products. The MNPs are typically insulated with a thin (∼3 nm), in principle pin-hole-free shell to prevent this. This approach, which is known as shell-isolated nanoparticle-enhanced Raman spectroscopy (SHINERS), offers many advantages, such as better thermal and chemical stability of the plasmonic nanoparticle. However, having both a high enhancement factor and ensuring that the shell is pin-hole-free is challenging because there is a trade-off between the two when considering the shell thickness. So far in the literature, shell insulation has been successfully applied only to chemically synthesized MNPs. In this work, we alternatively study different combinations of chemical synthesis (bottom-up) and lithographic (top-down) routes to obtain shell-isolated plasmonic nanostructures that offer chemical sensing capabilities. The three approaches we study in this work include (1) chemically synthesized MNPs + chemical shell, (2) lithographic substrate + chemical shell, and (3) lithographic substrate + atomic layer deposition (ALD) shell. We find that ALD allows us to fabricate controllable and reproducible pin-hole-free shells. We showcase the ability to fabricate lithographic SHINER substrates which report an enhancement factor of 7.5 × 10 3 ± 17% for our gold nanodot substrates coated with a 2.8 nm aluminium oxide shell. Lastly, by introducing a gold etchant solution to our fabricated SHINER substrate, we verified that the shells fabricated with ALD are truly pin-hole-free.

Published

2024

37. Tailoring the facet distribution on copper with chloride.

Author

Couce PM, Madsen TK, Plaza-Mayoral E, Kristoffersen HH, Chorkendorff I, Dalby KN, van der Stam W, Rossmeisl J, Escudero-Escribano M, and Sebastián-Pascual P

Abstract

Electrocatalytic reactions are sensitive to the catalyst surface structure. Therefore, finding methods to determine active surface sites with different geometry is essential to address the structure-electrocatalytic performance relationships. In this work, we propose a simple methodology to tune and quantify the surface structure on copper catalysts. We tailor the distribution and ratio of facets on copper by electrochemically oxidizing and reducing the surface in chloride-rich aqueous solutions. We then address the formation of new facets with voltammetric lead (Pb) underpotential deposition (UPD). We first record the voltammetric lead UPD on different single facets, which have intense peaks at different potential values. We use this data to decouple each facet peak-contribution in the lead (Pb) UPD curves of the tailored and multifaceted copper surfaces and determine the geometry of the active sites. We combine experiments with density functional theory (DFT) calculations to assess the ligand effect of chloride anions on the copper facet distribution during the surface oxidation/electrodeposition treatment. Our experiments and Wulff constructions suggest that chloride preferentially adsorbs on the (310) facet, reducing the number of (111) sites and inducing the growth of (310) or n (100) × (110) domains. Our work provides a tool to correlate active sites with copper geometries, which is needed to assess the structure-performance relationships in electrocatalysis. We also demonstrate an easy method for selectively tailoring the facet distribution of copper, which is essential to design a well-defined nanostructured catalyst., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2023

38. Mapping Temperature Heterogeneities during Catalytic CO 2 Methanation with Operando Luminescence Thermometry.

Author

Jacobs TS, van Swieten TP, Vonk SJW, Bosman IP, Melcherts AEM, Janssen BC, Janssens JCL, Monai M, Meijerink A, Rabouw FT, van der Stam W, and Weckhuysen BM

Abstract

Controlling and understanding reaction temperature variations in catalytic processes are crucial for assessing the performance of a catalyst material. Local temperature measurements are challenging, however. Luminescence thermometry is a promising remote-sensing tool, but it is cross-sensitive to the optical properties of a sample and other external parameters. In this work, we measure spatial variations in the local temperature on the micrometer length scale during carbon dioxide (CO 2 ) methanation over a TiO 2 -supported Ni catalyst and link them to variations in catalytic performance. We extract local temperatures from the temperature-dependent emission of Y 2 O 3 :Nd 3+ particles, which are mixed with the CO 2 methanation catalyst. Scanning, where a near-infrared laser locally excites the emitting Nd 3+ ions, produces a temperature map with a micrometer pixel size. We first designed the Y 2 O 3 :Nd 3+ particles for optimal temperature precision and characterized cross-sensitivity of the measured signal to parameters other than temperature, such as light absorption by the blackened sample due to coke deposition at elevated temperatures. Introducing reaction gases causes a local temperature increase of the catalyst of on average 6-25 K, increasing with the reactor set temperature in the range of 550-640 K. Pixel-to-pixel variations in the temperature increase show a standard deviation of up to 1.5 K, which are attributed to local variations in the catalytic reaction rate. Mapping and understanding such temperature variations are crucial for the optimization of overall catalyst performance on the nano- and macroscopic scale.

Published

2023

39. Spatiotemporal Mapping of Local Heterogeneities during Electrochemical Carbon Dioxide Reduction.

Author

An H, de Ruiter J, Wu L, Yang S, Meirer F, van der Stam W, and Weckhuysen BM

Abstract

The activity and selectivity of a copper electrocatalyst during the electrochemical CO 2 reduction reaction (eCO 2 RR) are largely dominated by the interplay between local reaction environment, the catalyst surface, and the adsorbed intermediates. In situ characterization studies have revealed many aspects of this intimate relationship between surface reactivity and adsorbed species, but these investigations are often limited by the spatial and temporal resolution of the analytical technique of choice. Here, Raman spectroscopy with both space and time resolution was used to reveal the distribution of adsorbed species and potential reaction intermediates on a copper electrode during eCO 2 RR. Principal component analysis (PCA) of the in situ Raman spectra revealed that a working electrocatalyst exhibits spatial heterogeneities in adsorbed species, and that the electrode surface can be divided into CO-dominant (mainly located at dendrite structures) and C-C dominant regions (mainly located at the roughened electrode surface). Our spectral evaluation further showed that in the CO-dominant regions, linear CO was observed (as characterized by a band at ∼2090 cm -1 ), accompanied by the more classical Cu-CO bending and stretching vibrations located at ∼280 and ∼360 cm -1 , respectively. In contrast, in the C-C directing region, these three Raman bands are suppressed, while at the same time a band at ∼495 cm -1 and a broad Cu-CO band at ∼2050 cm -1 dominate the Raman spectra. Furthermore, PCA revealed that anodization creates more C-C dominant regions, and labeling experiments confirmed that the 495 cm -1 band originates from the presence of a Cu-C intermediate. These results indicate that a copper electrode at work is very dynamic, thereby clearly displaying spatiotemporal heterogeneities, and that in situ micro-spectroscopic techniques are crucial for understanding the eCO 2 RR mechanism of working electrocatalyst materials., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

40. How Temperature Affects the Selectivity of the Electrochemical CO 2 Reduction on Copper.

Author

Vos RE, Kolmeijer KE, Jacobs TS, van der Stam W, Weckhuysen BM, and Koper MTM

Abstract

Copper is a unique catalyst for the electrochemical CO 2 reduction reaction (CO2RR) as it can produce multi-carbon products, such as ethylene and propanol. As practical electrolyzers will likely operate at elevated temperatures, the effect of reaction temperature on the product distribution and activity of CO2RR on copper is important to elucidate. In this study, we have performed electrolysis experiments at different reaction temperatures and potentials. We show that there are two distinct temperature regimes. From 18 up to ∼48 °C, C2+ products are produced with higher Faradaic efficiency, while methane and formic acid selectivity decreases and hydrogen selectivity stays approximately constant. From 48 to 70 °C, it was found that HER dominates and the activity of CO2RR decreases. Moreover, the CO2RR products produced in this higher temperature range are mainly the C1 products, namely, CO and HCOOH. We argue that CO surface coverage, local pH, and kinetics play an important role in the lower-temperature regime, while the second regime appears most likely to be related to structural changes in the copper surface., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

41. Low-Variance Surface-Enhanced Raman Spectroscopy Using Confined Gold Nanoparticles over Silicon Nanocones.

Author

Jonker D, Srivastava K, Lafuente M, Susarrey-Arce A, van der Stam W, van den Berg A, Odijk M, and Gardeniers HJGE

Abstract

Surface-enhanced Raman spectroscopy (SERS) substrates are of utmost interest in the analyte detection of biological and chemical diagnostics. This is primarily due to the ability of SERS to sensitively measure analytes present in localized hot spots of the SERS nanostructures. In this work, we present the formation of 67 ± 6 nm diameter gold nanoparticles supported by vertically aligned shell-insulated silicon nanocones for ultralow variance SERS. The nanoparticles are obtained through discrete rotation glancing angle deposition of gold in an e-beam evaporating system. The morphology is assessed through focused ion beam tomography, energy-dispersive X-ray spectroscopy, and scanning electron microscopy. The optical properties are discussed and evaluated through reflectance measurements and finite-difference time-domain simulations. Lastly, the SERS activity is measured by benzenethiol functionalization and subsequent Raman spectroscopy in the surface scanning mode. We report a homogeneous analytical enhancement factor of 2.2 ± 0.1 × 10 7 (99% confidence interval for N = 400 grid spots) and made a comparison to other lithographically derived assemblies used in SERS. The strikingly low variance (4%) of our substrates facilitates its use for many potential SERS applications., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

42. Restructuring of titanium oxide overlayers over nickel nanoparticles during catalysis.

Author

Monai M, Jenkinson K, Melcherts AEM, Louwen JN, Irmak EA, Van Aert S, Altantzis T, Vogt C, van der Stam W, Duchoň T, Šmíd B, Groeneveld E, Berben P, Bals S, and Weckhuysen BM

Abstract

Reducible supports can affect the performance of metal catalysts by the formation of suboxide overlayers upon reduction, a process referred to as the strong metal-support interaction (SMSI). A combination of operando electron microscopy and vibrational spectroscopy revealed that thin TiO x overlayers formed on nickel/titanium dioxide catalysts during 400°C reduction were completely removed under carbon dioxide hydrogenation conditions. Conversely, after 600°C reduction, exposure to carbon dioxide hydrogenation reaction conditions led to only partial reexposure of nickel, forming interfacial sites in contact with TiO x and favoring carbon-carbon coupling by providing a carbon species reservoir. Our findings challenge the conventional understanding of SMSIs and call for more-detailed operando investigations of nanocatalysts at the single-particle level to revisit static models of structure-activity relationships.

Published

2023

43. Elucidating the Roles of Nafion/Solvent Formulations in Copper-Catalyzed CO 2 Electrolysis.

Author

Ding P, An H, Zellner P, Guan T, Gao J, Müller-Buschbaum P, Weckhuysen BM, van der Stam W, and Sharp ID

Abstract

Nafion ionomer, composed of hydrophobic perfluorocarbon backbones and hydrophilic sulfonic acid side chains, is the most widely used additive for preparing catalyst layers (CLs) for electrochemical CO 2 reduction, but its impact on the performance of CO 2 electrolysis remains poorly understood. Here, we systematically investigate the role of the catalyst ink formulation on CO 2 electrolysis using commercial CuO nanoparticles as the model pre-catalyst. We find that the presence of Nafion is essential for achieving stable product distributions due to its ability to stabilize the catalyst morphology under reaction conditions. Moreover, the Nafion content and solvent composition (water/alcohol fraction) regulate the internal structure of Nafion coatings, as well as the catalyst morphology, thereby significantly impacting CO 2 electrolysis performance, resulting in variations of C 2+ product Faradaic efficiency (FE) by >3×, with C 2+ FE ranging from 17 to 54% on carbon paper substrates. Using a combination of ellipsometry and in situ Raman spectroscopy during CO 2 reduction, we find that such selectivity differences stem from changes to the local reaction microenvironment. In particular, the combination of high water/alcohol ratios and low Nafion fractions in the catalyst ink results in stable and favorable microenvironments, increasing the local CO 2 /H 2 O concentration ratio and promoting high CO surface coverage to facilitate C 2+ production in long-term CO 2 electrolysis. Therefore, this work provides insights into the critical role of Nafion binders and underlines the importance of optimizing Nafion/solvent formulations as a means of enhancing the performance of electrochemical CO 2 reduction systems., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

44. Near-Unity Electrochemical CO 2 to CO Conversion over Sn-Doped Copper Oxide Nanoparticles.

Author

Yang S, Liu Z, An H, Arnouts S, de Ruiter J, Rollier F, Bals S, Altantzis T, Figueiredo MC, Filot IAW, Hensen EJM, Weckhuysen BM, and van der Stam W

Abstract

Bimetallic electrocatalysts have emerged as a viable strategy to tune the electrocatalytic CO 2 reduction reaction (eCO 2 RR) for the selective production of valuable base chemicals and fuels. However, obtaining high product selectivity and catalyst stability remain challenging, which hinders the practical application of eCO 2 RR. In this work, it was found that a small doping concentration of tin (Sn) in copper oxide (CuO) has profound influence on the catalytic performance, boosting the Faradaic efficiency (FE) up to 98% for carbon monoxide (CO) at -0.75 V versus RHE, with prolonged stable performance (FE > 90%) for up to 15 h. Through a combination of ex situ and in situ characterization techniques, the in situ activation and reaction mechanism of the electrocatalyst at work was elucidated. In situ Raman spectroscopy measurements revealed that the binding energy of the crucial adsorbed *CO intermediate was lowered through Sn doping, thereby favoring gaseous CO desorption. This observation was confirmed by density functional theory, which further indicated that hydrogen adsorption and subsequent hydrogen evolution were hampered on the Sn-doped electrocatalysts, resulting in boosted CO formation. It was found that the pristine electrocatalysts consisted of CuO nanoparticles decorated with SnO 2 domains, as characterized by ex situ high-resolution scanning transmission electron microscopy and X-ray photoelectron spectroscopy measurements. These pristine nanoparticles were subsequently in situ converted into a catalytically active bimetallic Sn-doped Cu phase. Our work sheds light on the intimate relationship between the bimetallic structure and catalytic behavior, resulting in stable and selective oxide-derived Sn-doped Cu electrocatalysts., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

45. Waste-Derived Copper-Lead Electrocatalysts for CO 2 Reduction.

Author

Yang S, An H, Anastasiadou D, Xu W, Wu L, Wang H, de Ruiter J, Arnouts S, Figueiredo MC, Bals S, Altantzis T, van der Stam W, and Weckhuysen BM

Abstract

It remains a real challenge to control the selectivity of the electrocatalytic CO 2 reduction (eCO 2 R) reaction to valuable chemicals and fuels. Most of the electrocatalysts are made of non-renewable metal resources, which hampers their large-scale implementation. Here, we report the preparation of bimetallic copper-lead (CuPb) electrocatalysts from industrial metallurgical waste. The metal ions were extracted from the metallurgical waste through simple chemical treatment with ammonium chloride, and Cu x Pb y electrocatalysts with tunable compositions were fabricated through electrodeposition at varying cathodic potentials. X-ray spectroscopy techniques showed that the pristine electrocatalysts consist of Cu 0 , Cu 1+ and Pb 2+ domains, and no evidence for alloy formation was found. We found a volcano-shape relationship between eCO 2 R selectivity toward two electron products, such as CO, and the elemental ratio of Cu and Pb. A maximum Faradaic efficiency towards CO was found for Cu 9.00 Pb 1.00 , which was four times higher than that of pure Cu, under the same electrocatalytic conditions. In situ Raman spectroscopy revealed that the optimal amount of Pb effectively improved the reducibility of the pristine Cu 1+ and Pb 2+ domains to metallic Cu and Pb, which boosted the selectivity towards CO by synergistic effects. This work provides a framework of thinking to design and tune the selectivity of bimetallic electrocatalysts for CO 2 reduction through valorization of metallurgical waste., Competing Interests: The authors declare no conflict of interest., (© 2022 The Authors. ChemCatChem published by Wiley-VCH GmbH.)

Published

2022

46. Probing the Dynamics of Low-Overpotential CO 2 -to-CO Activation on Copper Electrodes with Time-Resolved Raman Spectroscopy.

Author

de Ruiter J, An H, Wu L, Gijsberg Z, Yang S, Hartman T, Weckhuysen BM, and van der Stam W

Abstract

Oxide-derived copper electrodes have displayed a boost in activity and selectivity toward valuable base chemicals in the electrochemical carbon dioxide reduction reaction (CO2RR), but the exact interplay between the dynamic restructuring of copper oxide electrodes and their activity and selectivity is not fully understood. In this work, we have utilized time-resolved surface-enhanced Raman spectroscopy (TR-SERS) to study the dynamic restructuring of the copper (oxide) electrode surface and the adsorption of reaction intermediates during cyclic voltammetry (CV) and pulsed electrolysis (PE). By coupling the electrochemical data to the spectral features in TR-SERS, we study the dynamic activation of and reactions on the electrode surface and find that CO 2 is already activated to carbon monoxide (CO) during PE (10% Faradaic efficiency, 1% under static applied potential) at low overpotentials (-0.35 V RHE ). PE at varying cathodic bias on different timescales revealed that stochastic CO is dominant directly after the cathodic bias onset, whereas no CO intermediates were observed after prolonged application of low overpotentials. An increase in cathodic bias (-0.55 V RHE ) resulted in the formation of static adsorbed CO intermediates, while the overall contribution of stochastic CO decreased. We attribute the low-overpotential CO 2 -to-CO activation to a combination of selective Cu(111) facet exposure, partially oxidized surfaces during PE, and the formation of copper-carbonate-hydroxide complex intermediates during the anodic pulses. This work sheds light on the restructuring of oxide-derived copper electrodes and low-overpotential CO formation and highlights the power of the combination of electrochemistry and time-resolved vibrational spectroscopy to elucidate CO2RR mechanisms.

Published

2022

47. Sub-Second Time-Resolved Surface-Enhanced Raman Spectroscopy Reveals Dynamic CO Intermediates during Electrochemical CO 2 Reduction on Copper.

Author

An H, Wu L, Mandemaker LDB, Yang S, de Ruiter J, Wijten JHJ, Janssens JCL, Hartman T, van der Stam W, and Weckhuysen BM

Abstract

The electrocatalytic carbon dioxide (CO 2 ) reduction reaction (CO 2 RR) into hydrocarbons is a promising approach for greenhouse gas mitigation, but many details of this dynamic reaction remain elusive. Here, time-resolved surface-enhanced Raman spectroscopy (TR-SERS) is employed to successfully monitor the dynamics of CO 2 RR intermediates and Cu surfaces with sub-second time resolution. Anodic treatment at 1.55 V vs. RHE and subsequent surface oxide reduction (below -0.4 V vs. RHE) induced roughening of the Cu electrode surface, which resulted in hotspots for TR-SERS, enhanced time resolution (down to ≈0.7 s) and fourfold improved CO 2 RR efficiency toward ethylene. With TR-SERS, the initial restructuring of the Cu surface was followed (<7 s), after which a stable surface surrounded by increased local alkalinity was formed. Our measurements revealed that a highly dynamic CO intermediate, with a characteristic vibration below 2060 cm -1 , is related to C-C coupling and ethylene production (-0.9 V vs. RHE), whereas lower cathodic bias (-0.7 V vs. RHE) resulted in gaseous CO production from isolated and static CO surface species with a distinct vibration at 2092 cm -1 ., (© 2021 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2021

48. Stabilization effects in binary colloidal Cu and Ag nanoparticle electrodes under electrochemical CO 2 reduction conditions.

Author

Wu L, Kolmeijer KE, Zhang Y, An H, Arnouts S, Bals S, Altantzis T, Hofmann JP, Costa Figueiredo M, Hensen EJM, Weckhuysen BM, and van der Stam W

Abstract

Nanoparticle modified electrodes constitute an attractive way to tailor-make efficient carbon dioxide (CO2) reduction catalysts. However, the restructuring and sintering processes of nanoparticles under electrochemical reaction conditions not only impedes the widespread application of nanoparticle catalysts, but also misleads the interpretation of the selectivity of the nanocatalysts. Here, we colloidally synthesized metallic copper (Cu) and silver (Ag) nanoparticles with a narrow size distribution (<10%) and utilized them in electrochemical CO2 reduction reactions. Monometallic Cu and Ag nanoparticle electrodes showed severe nanoparticle sintering already at low overpotential of -0.8 V vs. RHE, as evidenced by ex situ SEM investigations, and potential-dependent variations in product selectivity that resemble bulk Cu (14% for ethylene at -1.3 V vs. RHE) and Ag (69% for carbon monoxide at -1.0 V vs. RHE). However, by co-deposition of Cu and Ag nanoparticles, a nanoparticle stabilization effect was observed between Cu and Ag, and the sintering process was greatly suppressed at CO2 reducing potentials (-0.8 V vs. RHE). Furthermore, by varying the Cu/Ag nanoparticle ratio, the CO2 reduction reaction (CO2RR) selectivity towards methane (maximum of 20.6% for dense Cu2.5-Ag1 electrodes) and C2 products (maximum of 15.7% for dense Cu1-Ag1 electrodes) can be tuned, which is attributed to a synergistic effect between neighbouring Ag and Cu nanoparticles. We attribute the stabilization of the nanoparticles to the positive enthalpies of Cu-Ag solid solutions, which prevents the dissolution-redeposition induced particle growth under CO2RR conditions. The observed nanoparticle stabilization effect enables the design and fabrication of active CO2 reduction nanocatalysts with high durability.

Published

2021

49. Quantitative Electrochemical Control over Optical Gain in Quantum-Dot Solids.

Author

Geuchies JJ, Brynjarsson B, Grimaldi G, Gudjonsdottir S, van der Stam W, Evers WH, and Houtepen AJ

Abstract

Solution-processed quantum dot (QD) lasers are one of the holy grails of nanoscience. They are not yet commercialized because the lasing threshold is too high: one needs >1 exciton per QD, which is difficult to achieve because of fast nonradiative Auger recombination. The threshold can, however, be reduced by electronic doping of the QDs, which decreases the absorption near the band-edge, such that the stimulated emission (SE) can easily outcompete absorption. Here, we show that by electrochemically doping films of CdSe/CdS/ZnS QDs, we achieve quantitative control over the gain threshold. We obtain stable and reversible doping of more than two electrons per QD. We quantify the gain threshold and the charge carrier dynamics using ultrafast spectroelectrochemistry and achieve quantitative agreement between experiments and theory, including a vanishingly low gain threshold for doubly doped QDs. Over a range of wavelengths with appreciable gain coefficients, the gain thresholds reach record-low values of ∼1 × 10 -5 excitons per QD. These results demonstrate a high level of control over the gain threshold in doped QD solids, opening a new route for the creation of cheap, solution-processable, low-threshold QD lasers.

Published

2021

50. Operando Nanoscale Sensors in Catalysis: All Eyes on Catalyst Particles.

Author

Hartman T, Geitenbeek RG, Wondergem CS, van der Stam W, and Weckhuysen BM

Abstract

An era of circularity requires robust and flexible catalysts and reactors. We need profound knowledge of catalytic surface reactions on the local scale ( i.e. , angstrom-nanometer), whereas the reaction conditions, such as reaction temperature and pressure, are set and controlled on the macroscale ( i.e. , millimeter-meter). Nanosensors operating on all relevant length scales can supply this information in real time during operando working conditions. In this Perspective, we demonstrate the potential of nanoscale sensors, with special emphasis on local molecular sensing with shell-isolated nanoparticle-enhanced Raman spectroscopy (SHINERS) and local temperature sensing with luminescence thermometry, to acquire new insights of the reaction pathways. We also argue that further developments should be focused on local pressure measurements and on expanding the applications of these local sensors in other areas, such as liquid-phase catalysis, electrocatalysis, and photocatalysis. Ideally, a combination of sensors will be applied to monitor catalyst and reactor "health" and serve as feedback to the reactor conditions.

Published

2020