公开(公告)号：US09099292B1

公开(公告)日：2015-08-04

申请号：US12787827

申请日：2010-05-26

Applicant: Ilya Bezel ,  Anatoly Shchemelinin ,  Yanming Zhao ,  Gildardo R. Delgado

Inventor： Ilya Bezel ,  Anatoly Shchemelinin ,  Yanming Zhao ,  Gildardo R. Delgado

IPC: H01J1/02 ,  H01J61/28 ,  H01J61/52 ,  H01J61/54

CPC classification number: H05H1/24 ,  H01J1/025 ,  H01J23/033 ,  H01J61/09 ,  H01J61/28 ,  H01J61/52 ,  H01J61/54 ,  H01J61/545 ,  H01J65/042

Abstract: A laser sustained plasma light source having a cell formed as a continuous tube with a circular cross section, a gas volume contained within the cell, at least one laser directed into the gas volume, for sustaining a plasma within the gas volume, the plasma producing a light, where the gas volume is heated as it leaves the plasma, cools as it circulates around the continuous tube of the cell, and reenters the plasma cooler than when it left the plasma and in a laminar flow, and a reflector for collecting the light and providing the light to a desired location.

Abstract translation: 一种激光持续等离子体光源，其具有形成为圆形横截面的连续管的单元，容纳在该单元内的气体体积，至少一个引导到气体体积中的激光，用于维持气体体积内的等离子体，等离子体产生 气体体积在离开等离子体时被加热的光在其围绕电池的连续管周围循环时冷却，并且比等离子体离开等离子体和层流时重新进入等离子体冷却器，以及用于收集等离子体的反射器 光并将光提供到所需位置。

公开(公告)号：US20130003384A1

公开(公告)日：2013-01-03

申请号：US13529582

申请日：2012-06-21

Applicant: Ilya Bezel ,  Anatoly Shchemelinin ,  Yanming Zhao ,  Matthew Derstine

Inventor： Ilya Bezel ,  Anatoly Shchemelinin ,  Yanming Zhao ,  Matthew Derstine

IPC: F21V13/00

CPC classification number: G01J3/021 ,  G01J3/0208 ,  G02B26/06 ,  H01J65/04

Abstract: A system for compensating abberative effects caused by a bulb of a plasma cell includes an illumination source configured to generate illumination; a plasma cell, the plasma cell including a bulb for containing a volume of gas; an ellipse configured to focus illumination from the illumination source into the volume of gas in order to generate a plasma within the volume of gas; and one or more adaptive optical elements configured to compensate for aberrations produced by one or more optical elements, the one or more adaptive optics elements positioned along an illumination pathway between the illumination source and the plasma cell.

Abstract translation: 用于补偿由等离子体电池的灯泡引起的阻尼效应的系统包括被配置为产生照明的照明源; 等离子体电池，所述等离子体电池包括用于容纳一定体积气体的灯泡; 被配置为将来自照明源的照明聚焦到气体体积中以在气体体积内产生等离子体的椭圆形; 以及配置成补偿由一个或多个光学元件产生的像差的一个或多个自适应光学元件，所述一个或多个自适应光学元件沿着照明源和等离子体单元之间的照明路径定位。

公开(公告)号：USD1055654S1

公开(公告)日：2024-12-31

申请号：US29963289

申请日：2024-09-16

Applicant: Yanming Zhao

Designer： Yanming Zhao

公开(公告)号：US09097577B2

公开(公告)日：2015-08-04

申请号：US13529582

申请日：2012-06-21

Applicant: Ilya Bezel ,  Anatoly Shchemelinin ,  Yanming Zhao ,  Matthew Derstine

Inventor： Ilya Bezel ,  Anatoly Shchemelinin ,  Yanming Zhao ,  Matthew Derstine

IPC: F21V13/00 ,  G01J3/02 ,  G02B26/06 ,  H01J65/04

CPC classification number: G01J3/021 ,  G01J3/0208 ,  G02B26/06 ,  H01J65/04

Abstract: A system for compensating abberative effects caused by a bulb of a plasma cell includes an illumination source configured to generate illumination; a plasma cell, the plasma cell including a bulb for containing a volume of gas; an ellipse configured to focus illumination from the illumination source into the volume of gas in order to generate a plasma within the volume of gas; and one or more adaptive optical elements configured to compensate for aberrations produced by one or more optical elements, the one or more adaptive optics elements positioned along an illumination pathway between the illumination source and the plasma cell.

Abstract translation: 用于补偿由等离子体电池的灯泡引起的阻尼效应的系统包括被配置为产生照明的照明源; 等离子体电池，所述等离子体电池包括用于容纳一定体积气体的灯泡; 被配置为将来自照明源的照明聚焦到气体体积中以在气体体积内产生等离子体的椭圆形; 以及配置成补偿由一个或多个光学元件产生的像差的一个或多个自适应光学元件，所述一个或多个自适应光学元件沿着照明源和等离子体单元之间的照明路径定位。

公开(公告)号：US20220267361A1

公开(公告)日：2022-08-25

申请号：US17636717

申请日：2020-08-20

Applicant: Yanming ZHAO ,  University of South Florida

Inventor： Shengqian MA ,  Yanming ZHAO

IPC: C07F15/02 ,  B01J31/16

Abstract: Described herein are corrole-based frameworks and methods for making the same. The corrole-based frameworks have unique structural and physical properties, which lends them to be versatile in a number of different applications and uses such as in gas storage/separation, proton conduction, biomedicine, sensing, and catalysis. In one aspect, the corrole-based frameworks are organic frameworks. In other aspects, the corrole-based frameworks are metal-organic frameworks.