Dipartimento di Fisica, Politecnico di Milano, 20133 Milan, Italy.
Department of Chemistry, Sorbonne University, 75005 Paris, France.
Proc Natl Acad Sci U S A. 2019 Apr 23;116(17):8161-8166. doi: 10.1073/pnas.1817850116. Epub 2019 Apr 5.
We investigate, with a combination of ultrafast optical spectroscopy and semiclassical modeling, the photothermal properties of various water-soluble nanocrystal assemblies. Broadband pump-probe experiments with ∼100-fs time resolution in the visible and near infrared reveal a complex scenario for their transient optical response that is dictated by their hybrid composition at the nanoscale, comprising metallic (Au) or semiconducting ([Formula: see text]) nanostructures and a matrix of organic ligands. We track the whole chain of energy flow that starts from light absorption by the individual nanocrystals and subsequent excitation of out-of-equilibrium carriers followed by the electron-phonon equilibration, occurring in a few picoseconds, and then by the heat release to the matrix on the 100-ps timescale. Two-dimensional finite-element method electromagnetic simulations of the composite nanostructure and multitemperature modeling of the energy flow dynamics enable us to identify the key mechanism presiding over the light-heat conversion in these kinds of nanomaterials. We demonstrate that hybrid (organic-inorganic) nanocrystal assemblies can operate as efficient nanoheaters by exploiting the high absorption from the individual nanocrystals, enabled by the dilution of the inorganic phase that is followed by a relatively fast heating of the embedding organic matrix, occurring on the 100-ps timescale.
我们采用超快光学光谱学和半经典建模相结合的方法研究了各种水溶性纳米晶组装体的光热特性。在可见光和近红外区域进行的具有 100 飞秒时间分辨率的宽带泵浦-探测实验揭示了它们瞬态光学响应的复杂情况,这是由它们在纳米尺度上的混合组成决定的,包括金属(Au)或半导体([Formula: see text])纳米结构和有机配体基质。我们跟踪了从单个纳米晶体吸收光并随后激发非平衡载流子开始的整个能量流动链,接着是电子-声子平衡,这发生在几皮秒内,然后在 100 皮秒的时间尺度上释放到基质中的热量。对复合材料的二维有限元方法电磁模拟和能量流动动力学的多温度建模使我们能够确定控制这些纳米材料中光热转换的关键机制。我们证明,通过利用单个纳米晶体的高吸收率,以及随后的无机相稀释和相对较快的嵌入有机基质加热(发生在 100 皮秒的时间尺度上),可以使混合(有机-无机)纳米晶组装体作为高效纳米加热器工作。