全校師生:
我校定于2019年4月29日舉辦研究生靈犀學(xué)術(shù)殿堂——Michel Versluis教授報(bào)告會(huì)���,現(xiàn)將有關(guān)事項(xiàng)通知如下:
1.報(bào)告會(huì)簡(jiǎn)介
報(bào)告人:Michel Versluis教授
時(shí)間:2019年4月29日(星期一)上午10:00
地點(diǎn):友誼校區(qū)航空樓A706
主題:Bubbles and droplets for nanotechnology and nanomedicine(納米技術(shù)和納米醫(yī)學(xué)的氣泡和液滴)
內(nèi)容簡(jiǎn)介:The acoustic excitation of bubbles and droplets has widespread use in medical technology and nanotechnology applications. These applications include bulk and surface acoustic waves for bubble and droplet production, as well as bubble and droplet actuation to perform local drug delivery or local and well-controlled surface cleaning. For example, the controlled jet breakup of droplets can be accelerated through the resonant acoustic excitation of instable modes on the jet to form monodisperse droplets at a uniform production rate. Beat frequencies can be exploited to form larger droplet constructs through well-controlled coalescence in flight to be used to efficiently generate extreme ultraviolet wavelengths for the next generation nanolithography technology. Acoustically driven bubbles can promote efficient mixing on the microscale through acoustic streaming and stable cavitation. Microbubbles and low-boiling point nanodroplets can also be decorated with a payload which carries great potential for their use as drug delivery agents in the context of personalized medical therapy. Key to all these emerging applications is a precise acoustic control of the interaction of ultrasound with the bubbles and droplets. The challenge here is the combined microscopic length scales and ultrashort time scales associated with the mechanisms controlling bubble and droplet formation and its activation processes, which we solve by high-resolution ultrafast microscopy, even down to the nanosecond. Together with theoretical modeling and numerical simulations these experiments assist in our in-depth fundamental understanding of bubble and droplet behavior, which then provides intriguing new prospects for innovative solutions in nanotechnology industry and in nanomedicine.
(氣泡和液滴的聲激發(fā)在醫(yī)療技術(shù)和納米技術(shù)應(yīng)用中廣泛使用。這些應(yīng)用包括用于氣泡和液滴產(chǎn)生的表面聲波���,以及用于執(zhí)行局部藥物輸送或局部良好控制的表面清潔氣泡和液滴致動(dòng)。例如���,可以通過(guò)噴射器上的不穩(wěn)定模式的共振聲激發(fā)來(lái)加速液滴的受控噴射破裂���,從而以均勻的產(chǎn)生速率形成單分散液滴。通過(guò)在飛行中聚結(jié)的良好控制���,可利用節(jié)拍頻率形成更大的液滴構(gòu)造���,以用于有效地產(chǎn)生用于下一代納米光刻技術(shù)的紫外波長(zhǎng)。聲學(xué)驅(qū)動(dòng)的氣泡可以通過(guò)聲流和穩(wěn)定的空化促進(jìn)微尺度上的有效混合���。微泡和低沸點(diǎn)納米液滴也可以用有效載荷裝飾���,其在個(gè)性化醫(yī)學(xué)治療的背景下具有作為藥物遞送劑使用的巨大潛力���。所有這些新興應(yīng)用的關(guān)鍵是超聲波與氣泡和液滴相互作用的精確聲學(xué)控制。這里的挑戰(zhàn)是結(jié)合微觀(guān)尺度和超短時(shí)間尺度與控制氣泡和液滴形成及其激活過(guò)程的機(jī)制相關(guān)聯(lián)���,我們通過(guò)高分辨率超快速顯微鏡解決���,甚至低至納秒。結(jié)合理論建模和數(shù)值模擬���,這些實(shí)驗(yàn)有助于我們對(duì)氣泡和液滴行為的深入基礎(chǔ)理解���,從而為納米技術(shù)行業(yè)和納米醫(yī)學(xué)領(lǐng)域的創(chuàng)新解決方案提供了有趣的新前景。)
2.歡迎各學(xué)院師生前來(lái)聽(tīng)報(bào)告���。報(bào)告會(huì)期間請(qǐng)關(guān)閉手機(jī)或?qū)⑹謾C(jī)調(diào)至靜音模式���。
黨委學(xué)生工作部
航空學(xué)院
2019年4月26日
報(bào)告人簡(jiǎn)介
Andreas Michael Versluis博士是特文特大學(xué)的全職教授和美國(guó)聲學(xué)學(xué)會(huì)的會(huì)員。 他的研究興趣在于物理和醫(yī)學(xué)聲學(xué)領(lǐng)域,特別是對(duì)微泡和微滴在醫(yī)學(xué)應(yīng)用中的應(yīng)用研究非常深入���,包括成像和治療���,以及醫(yī)學(xué)和微流體應(yīng)用中氣泡和液滴的物理和控制。他在知名期刊上發(fā)表了178篇論文���。他的出版物總引用次數(shù)超過(guò)5800次(直到2019年1月)���,目前的h指數(shù)為41。他同時(shí)也是許多著名國(guó)際期刊的審稿人���。
