Disclosed in some embodiments is a chamber component (such as an end effector body) coated with an ultrathin electrically-dissipative material to provide a dissipative path from the coating to the ground. The coating may be deposited via a chemical precursor deposition to provide a uniform, conformal, and porosity free coating in a cost effective manner. In an embodiment wherein the chamber component comprises an end effector body, the end effector body may further comprise replaceable contact pads for supporting a substrate and the contact surface of the contact pads head may also be coated with an electrically-dissipative material.

Disclosed in some embodiments is a chamber component (such as an end effector body) coated with an ultrathin electrically-dissipative material to provide a dissipative path from the coating to the ground. The coating may be deposited via a chemical precursor deposition to provide a uniform, conformal, and porosity free coating in a cost effective manner. In an embodiment wherein the chamber component comprises an end effector body, the end effector body may further comprise replaceable contact pads for supporting a substrate and the contact surface of the contact pads head may also be coated with an electrically-dissipative material.

Provided is a vehicle with a smart key system that can suppress damage to vehicles original driving performance. The vehicle includes a driving control unit for controlling driving of the vehicle. An in-vehicle device includes: an in-vehicle communication unit including an in-vehicle transmitter for transmitting a search signal for searching a mobile device at a predetermined field strength; and a communication control unit for controlling communication of the in-vehicle communication unit. The in-vehicle device or the mobile device includes a control switch for starting or stopping a main power supply of the driving control unit. After the main power supply of the driving control unit is started by the control switch and at least before the vehicle starts driving, the communication control unit controls the in-vehicle transmitter to implement a limitation to set a low or zero field strength of the search signal transmitted from the in-vehicle transmitter.

Provided is a vehicle with a smart key system that can suppress damage to vehicles original driving performance. The vehicle includes a driving control unit for controlling driving of the vehicle. An in-vehicle device includes: an in-vehicle communication unit including an in-vehicle transmitter for transmitting a search signal for searching a mobile device at a predetermined field strength; and a communication control unit for controlling communication of the in-vehicle communication unit. The in-vehicle device or the mobile device includes a control switch for starting or stopping a main power supply of the driving control unit. After the main power supply of the driving control unit is started by the control switch and at least before the vehicle starts driving, the communication control unit controls the in-vehicle transmitter to implement a limitation to set a low or zero field strength of the search signal transmitted from the in-vehicle transmitter.

The present disclosure provides a technology which can suppress separation of an airflow while a change in an appearance of a vehicle is suppressed. This exemplary embodiment is a vehicle including a self-discharging static eliminator which neutralizes and eliminates positive charges generated on a vehicle body by self-discharging which causes negative air ions to be generated and a transparent conductive material, and the self-discharging static eliminator and the transparent conductive material are electrically continuous.

A method and system for extruding multiple laminated flow streams using microlayer extrusion, and in particular to creating and forming products with electrical properties that are formed from layers and particles with dimensions in the micro to nanometer range.

A method and system for extruding multiple laminated flow streams using microlayer extrusion, and in particular to creating and forming products with electrical properties that are formed from layers and particles with dimensions in the micro to nanometer range.

An optical fiber comprises a glass fiber comprising a core and a cladding, and a coating resin layer covering the outer periphery of the glass fiber, wherein the coating resin layer has a primary resin layer being in contact with the glass fiber and covering the glass fiber and a secondary resin layer covering the outer periphery of the primary resin layer, the secondary resin layer comprises hydrophobic spherical silica particles, and the content of the silica particles is 7% by mass or more and 60% by mass or less based on the total amount of the secondary resin layer, and the absolute value of the surface potential of the optical fiber is 10 mV or more and 60 mV or less.

A method and system for extruding multiple laminated flow streams using microlayer extrusion, and in particular to creating and forming products with electrical properties that are formed from layers and particles with dimensions in the micro to nanometer range.

A method and system for extruding multiple laminated flow streams using microlayer extrusion, and in particular to creating and forming products with electrical properties that are formed from layers and particles with dimensions in the micro to nanometer range.