Emerging non-traditional Förster resonance energy transfer configurations with semiconductor quantum dots: Investigations and applications

Algar, W. Russ; Kim, Hyungki; Medintz, Igor L.; Hildebrandt, Niko

doi:10.1016/j.ccr.2013.07.015

Cited by 171 publications

(220 citation statements)

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“…Charge transfer acts by perturbing excited states in the particle core to either enhance or quench emission. RET processes include Förster resonance energy transfer (FRET) and bioluminescence or chemiluminescence (BRET and CRET) and can involve a variety of materials, including organic dyes, lanthanide complexes, fluorescent proteins, graphene, chemi-and bioluminescent enzymes, and inorganic materials like AuNPs, which may function as acceptors or donors and can be arranged in relays (63). The use of long-lifetime luminescent nanoparticles and RET agents allows for time-gated detection, which will be an important area of development for commercial nanoparticle biosensors (64).…”

Section: Biosensing Mechanismsmentioning

confidence: 99%

Colloidal nanoparticles as advanced biological sensors

Howes

Chandrawati

Stevens

2014

Science

892

686

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Colloidal nanoparticle biosensors have received intense scientific attention and offer promising applications in both research and medicine. We review the state of the art in nanoparticle development, surface chemistry, and biosensing mechanisms, discussing how a range of technologies are contributing toward commercial and clinical translation. Recent examples of success include the ultrasensitive detection of cancer biomarkers in human serum and in vivo sensing of methyl mercury. We identify five key materials challenges, including the development of robust mass-scale nanoparticle synthesis methods, and five broader challenges, including the use of simulations and bioinformatics-driven experimental approaches for predictive modeling of biosensor performance. The resultant generation of nanoparticle biosensors will form the basis of high-performance analytical assays, effective multiplexed intracellular sensors, and sophisticated in vivo probes.Evolution has given rise to organisms of staggering complexity. Our now extensive knowledge of biological systems pales in comparison to the remaining mysteries. Unraveling these requires tools that probe the molecular machinery of life and provide detailed feedback on complex networks of subtle interactions. Such tools are cornerstones of biomedical research and practice, and improvements in these lead directly to a better understanding of fundamental biology, monitoring of health, and diagnosis of disease. Colloidal nanoparticle biosensors are a class of biological probe that will not only yield improved biological sensing but also provide a step change in our ability to probe the biomolecular realm. Nanoparticles can act as high-performance sensors because nanomaterials exhibit unique and useful behaviors not present in their bulk form: for example, bright tunable fluorescence from semiconductor nanoparticles and localized surface plasmon resonance (LSPR) phenomena in metallic nanoparticles. These particles exhibit intense responses to incident light (or other stimuli), and the ability to modulate this response by interaction with target analytes makes them excellent biosensor signal transducers. Outputs can be quantitative or qualitative depending on the functionality of

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Section: Biosensing Mechanismsmentioning

confidence: 99%

Colloidal nanoparticles as advanced biological sensors

Howes

Chandrawati

Stevens

2014

Science

892

686

View full text Add to dashboard Cite

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“…This is one of the main pathways by which energy transfer occurs at the nanoscale. It plays important roles in biology, [50][51][52][53] nanophotonics (light harvesting, LEDs, nanolasers), [54][55][56][57][58][59][60] microscopy, 61,62 sensing, 63,64 and for optical rulers, 65 etc. The process is determined by the dipole-dipole interaction between the donor and acceptor and, in the short distance limit, has a r −6 dependence on the donor-acceptor separation, r, the FRET regime.…”

Section: Introductionmentioning

confidence: 99%

A theoretical investigation of the influence of gold nanosphere size on the decay and energy transfer rates and efficiencies of quantum emitters

Marocico

Zhang

Bradley

2016

The Journal of Chemical Physics

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Articles you may be interested inWe present in this contribution a comprehensive investigation of the effect of the size of gold nanospheres on the decay and energy transfer rates of quantum systems placed close to these nanospheres. These phenomena have been investigated before, theoretically and experimentally, but no comprehensive study of the influence of the nanoparticle size on important dependences of the decay and energy transfer rates, such as the dependence on the donor-acceptor spectral overlap and the relative positions of the donor, acceptor, and nanoparticle, exists. As such, different accounts of the energy transfer mechanism have been presented in the literature. We perform an investigation of the energy transfer mechanisms between emitters and gold nanospheres and between donor-acceptor pairs in the presence of the gold nanospheres using a Green's tensor formalism, experimentally verified in our lab. We find that the energy transfer rate to small nanospheres is greatly enhanced, leading to a strong quenching of the emission of the emitter. When the nanosphere size is increased, it acts as an antenna, increasing the emission of the emitter. We also investigate the emission wavelength and intrinsic quantum yield dependence of the energy transfer to the nanosphere. As evidenced from the literature, the energy transfer process between the quantum system and the nanosphere can have a complicated distance dependence, with a r −6 regime, characteristic of the Förster energy transfer mechanism, but also exhibiting other distance dependences. In the case of a donor-acceptor pair of quantum systems in the presence of a gold nanosphere, when the donor couples strongly to the nanosphere, acting as an enhanced dipole; the donor-acceptor energy transfer rate then follows a Förster trend, with an increased Förster radius. The coupling of the acceptor to the nanosphere has a different distance dependence. The angular dependence of the energy transfer efficiency between donor and acceptor exhibits a strong focusing effect and the same enhanced donor-dipole character in different angular arrangements. The spectral overlap of the donor emission and acceptor absorption spectra shows that the energy transfer follows the near-field scattering efficiency, with a red-shift from the localized surface plasmon peak for small sphere sizes. C 2016 AIP Publishing LLC. [http://dx

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“…This paper is a state-of-the-art review which presents results of studying photochromic nanoparticles including author's own data. The results of earlier research are also surveyed in some other reviews [1][2][3][4][5][6][7][8][9][10][11][12][13]. …”

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confidence: 99%

Nanophotochromism

Barachevsky¹

2015

Organic Photonics and Photovoltaics

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Abstract:The review presents the state-of-the-art analysis of investigations in the field of a new line of research of photochromism -nanophotochromism. The design, properties, and possible applications of photochromic nanoparticles prepared by different methods with the use of photochromic substances (aggregates, host-guest, and polymer systems, solid nanoparticles) as well as core-shell photochromic nanostructures based on polymers, silica, quantum dots, doped upconversion nanocrystals, and Ag, Au, etc. nanoparticles have been reviewed. Keywords: photochromism; photochromic nanoparticles; core-shell photochromic nanoparticles design; photoswitching; aggregates; polymer systems, host-guest systems IntroductionPhotochromism is a very important phenomenon for different applications in photonics. The applications are based on reversible phototransformations of photochromic compounds between two states and changes of their properties that accompany these transformations At present, systems and materials containing photochromic nanopatricles have become highly significant. Among these are nanodimensional particles of photochromic substances, including aggregates, and coreshell systems. As a core, inorganic nanoparticles of gold, silver, metal oxides, quantum dots (QD), and also polymeric nanoparticles are used. The shell consists of photochromic molecules or their aggregates connected to a core surface either chemically or physically. Photochromic nanoparticles with photocontrolled fluorescence arouse a special interest because the fluorescence technique is becoming a leading strategy in biological diagnosis, imaging, and detection applications. This paper is a state-of-the-art review which presents results of studying photochromic nanoparticles including author's own data. The results of earlier research are also surveyed in some other reviews [1][2][3][4][5][6][7][8][9][10][11][12][13]. Photochromic nanoparticles:properties and applications Nanoparticles based on photochromic substances AggregatesThe most known photochromic nanoparticles are aggregates of photochromic organic compounds [14]. These compounds experience reversible photoinduced transformations between two states, Sch. 1A and Sch. 1B. Scheme 1The photoinduced colored merocyanine form B absorbing visible irradiation is formed from a colorless form A as a result of photodissociation of the -C-O-bond of the pyran heterocycle under UV radiation, and this is followed by spontaneous isomerization of the cis-form to the trans one. The colored form B can be converted back to the initial colorless form A upon absorption of visible light or spontaneously during the dark relaxation, which is accelerated by heating.The J-aggregates of nitro-substituted indoline spiropyrans Sch. 2 with long alkyl substituents are of special interest [15].The narrow absorption bands of J-aggregates of these photochromic compounds (Fig. 1) made it possible prepare a specimen of the multilayered optical disk providing freUnauthenticated Download

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Emerging non-traditional Förster resonance energy transfer configurations with semiconductor quantum dots: Investigations and applications

Cited by 171 publications

References 195 publications

Colloidal nanoparticles as advanced biological sensors

Colloidal nanoparticles as advanced biological sensors

A theoretical investigation of the influence of gold nanosphere size on the decay and energy transfer rates and efficiencies of quantum emitters

Nanophotochromism

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