High Optical Contrast of Quartet Dual-Band Electrochromic Device for Energy-Efficient Smart Window

Kim, Jiseon; Shin, Dong-Ho; Son, Minhee; Lee, Caroline Sunyong

doi:10.1021/acsami.2c19151

Cited by 11 publications

(18 citation statements)

References 32 publications

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“…Second, the optical contrast (Δ T ) which measures the degree of color change was quantified for all three thin films (Figures b, S30, and S31). Very high optical contrast (absorption change of up to 2.5 OD and Δ T up to 97%) is consistently obtained for all members of the isoreticular MOF series (measured at characteristic λ of [XDI] 0/•– ), which is among the highest in electrochromic materials. , Meanwhile, the switching time between the bleached state and the colored state (90% of optical contrast) was determined for all thin films (Figures c and S32). Both coloration time and bleaching time are in the range of a few seconds (Figure c), demonstrating their practical feasibility. , Lastly, the electrochromic stability of the isoreticular MOFs was investigated in accelerated reduction and oxidation operation cycles (details in the SI).…”

Section: Resultsmentioning

confidence: 72%

“…Very high optical contrast (absorption change of up to 2.5 OD and ΔT up to 97%) is consistently obtained for all members of the isoreticular MOF series (measured at characteristic λ of [XDI] 0/•− ), which is among the highest in electrochromic materials. 59,64 Meanwhile, the switching time between the bleached state and the colored state (90% of optical contrast) was determined for all thin films (Figures 5c and S32). Both coloration time and bleaching time are in the range of a few seconds (Figure 5c), demonstrating their practical feasibility.…”

Section: Resultsmentioning

confidence: 99%

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Electrochromism in Isoreticular Metal–Organic Framework Thin Films with Record High Coloration Efficiency

Kumar,

Li,

Inge

et al. 2023

ACS Nano

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The power of isoreticular chemistry has been widely exploited to engineer metal–organic frameworks (MOFs) with fascinating molecular sieving and storage properties but is underexplored for designing MOFs with tunable optoelectronic properties. Herein, three dipyrazole-terminated XDIs (X = PM (pyromellitic), N (naphthalene), or P (perylene); DI = diimide) with different lengths and electronic properties are prepared and employed as linkers for the construction of an isoreticular series of Zn-XDI MOFs with distinct electrochromism. The MOFs are grown on fluorine-doped tin oxide (FTO) as high-quality crystalline thin films and characterized by X-ray diffraction (XRD) and scanning electron microscopy (SEM). Due to the constituting electronically isolated XDI linkers, each member of the isoreticular thin film series exhibits two reversible one-electron redox events, each at a distinct electrochemical potential. The orientation of the MOFs as thin films as well as their isoreticular nature results in identical cation-coupled electron hopping transport rates in all three materials, as demonstrated by comparable apparent electron diffusion coefficients, D e app. Upon electrochemical reduction to either the [XDI]•– or [XDI]2– state, each MOF undergoes characteristic changes in its optical properties as a function of linker length and redox state of the linker. Operando spectroelectrochemistry measurements reveal that Zn-PDI@FTO (PDI = perylene diimide) thin films exhibit a record high coloration efficiency of 941 cm2 C–1 at 746 nm, which is attributed to the maximized Faradaic transformations at each electronically isolated PDI unit. The electrochromic response of the thin film is retained to more than 99% over 100 reduction–oxidation cycles, demonstrating the applicability of the presented materials.

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Section: Resultsmentioning

confidence: 72%

Section: Resultsmentioning

confidence: 99%

Electrochromism in Isoreticular Metal–Organic Framework Thin Films with Record High Coloration Efficiency

Kumar,

Li,

Inge

et al. 2023

ACS Nano

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“…Since smart windows typically require high transmission contrast, recently reported EC devices have demonstrated high modulation depths, approaching ≈99% at specific wavelengths. [86] However, their operation speeds typically fall in the range of seconds to tens of seconds, [10][11][12][13]85] making them less suitable for high-speed processing of optical information signals. Furthermore, the fabrication of EC devices necessitates the integration of multiple components and most EC layers involve the integration of NIR-active and visible-active components to achieve dual-band modulation, adding complexity to device structure and fabrication.…”

Section: Comparison With Other Dual-band Modulation Technologiesmentioning

confidence: 99%

“…[9] Thus, various dual-band devices capable of selectively sensing [2,3,5] and modulating [10][11][12][13] visible-infrared signals have been intensively developed. However, most existing visible-infrared dual-band modulators rely on electrochromic methods that typically operate on timescales of seconds to minutes, [10][11][12][13] which are unsuitable for processing ultrafast optical signals in the GHz-THz frequency range. Furthermore, such devices often require a combination of multiple materials or structural elements for electrical control, leading to increased complexity in integrated systems.…”

Section: Introductionmentioning

confidence: 99%

“…[3] Furthermore, it introduces novel functionalities in domains such as bio-imaging, [7] food engineering, [8] and computer vision. [9] Thus, various dual-band devices capable of selectively sensing [2,3,5] and modulating [10][11][12][13] visible-infrared signals have been intensively developed. However, most existing visible-infrared dual-band modulators rely on electrochromic methods that typically operate on timescales of seconds to minutes, [10][11][12][13] which are unsuitable for processing ultrafast optical signals in the GHz-THz frequency range.…”

Section: Introductionmentioning

confidence: 99%

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Ultrafast Visible/Near‐Infrared Dual‐Band Selective Optical Switching via Polarization Control in Layered Low‐Symmetry TlSe

Suk,

Nah,

Sajjad

et al. 2023

Laser & Photonics Reviews

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Dual‐band optical signals, consisting of visible and infrared wavelengths, hold significant potential in various fields such as night vision, vehicle safety, bioimaging, and optical communications. Consequently, considerable attention has focused on modulation techniques for visible‐infrared dual‐band signals, including various electrochromic devices. However, these devices often suffer from low speeds and complex structures, making them unsuitable for satisfying the current demand for ultrafast on‐chip nanophotonics. Here, an ultrafast, dual‐band selective optical switching is presented in thallium selenide (TlSe), a layered nanomaterial with low‐symmetry. Transient absorption microscopy directly reveals distinct modulation bands in the visible and near‐infrared (NIR) regions. Notably, these bands exhibit orthogonal polarization dependencies, enabling the selective modulation of visible and NIR light via polarization control. Theoretical analysis reveals that the modulation bands in the visible and NIR regions arise from the perpendicularly anisotropic excited‐state absorption of electrons and holes, respectively. This is supported by distinct ultrafast cooling times observed for electrons and holes. The modulations exhibit picosecond‐scale dynamics owing to efficient Auger recombination. These exceptional characteristics highlight the promising nature of low‐symmetry TlSe as a novel material for ultrafast dual‐band nanophotonics. Furthermore, this work provides fundamental insights into anisotropic carrier dynamics, including effective mass‐dependent cooling and many‐body interactions.

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Toward Next‐Generation Smart Windows: An In‐depth Analysis of Dual‐Band Electrochromic Materials and Devices

Wang,

Zhang

et al. 2024

Advanced Optical Materials

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As the proportion of buildings energy consumption increases, the issue of low energy utilization efficiency becomes increasingly prominent. Approximately 45% of the energy is lost through doors and windows, a significant concern that has drawn society's attention to the potential of electrochromic technology, which can regulate light transmittance and absorption effectively. Specifically, dual‐band electrochromic materials offer a promising solution to this issue, as they can manipulate the transmission ratios of visible (VIS) and near‐infrared (NIR) light to obtain “bright,” “cold,” “warm,” and “dark” independent modes. However, research on dual‐band electrochromic materials and smart windows is still infant, and many challenges including performance and assembly issues, are significant obstacles to the advancement and application of this technology. This review clarifies the basic characteristics of dual‐band electrochromic materials and smart windows, including configurations, operational mechanisms, and performance assessment parameters. In‐depth examination of potential dual‐band electrochromic materials and methods for achieving independent modulation is provided, along with an analysis of the challenges and potential solutions for performance and assembly issues. Finally, the future prospects of dual‐band electrochromic smart windows (ESWs) are underscored. The hope is to eventually facilitate the commercial application of these windows, which can significantly contribute to the creation of modern, energy‐efficient buildings.

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High Optical Contrast of Quartet Dual-Band Electrochromic Device for Energy-Efficient Smart Window

Cited by 11 publications

References 32 publications

Electrochromism in Isoreticular Metal–Organic Framework Thin Films with Record High Coloration Efficiency

Electrochromism in Isoreticular Metal–Organic Framework Thin Films with Record High Coloration Efficiency

Ultrafast Visible/Near‐Infrared Dual‐Band Selective Optical Switching via Polarization Control in Layered Low‐Symmetry TlSe

Toward Next‐Generation Smart Windows: An In‐depth Analysis of Dual‐Band Electrochromic Materials and Devices

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