Up to 1.5 MW of fast wave (FW) power has been successfully coupled to the core of ELMing H-mode discharges with βN˜2.5 in conjunction with ˜7 MW of neutral beam injection and 1.5 MW of electron cyclotron (EC) heating. FW core heating efficiency is observed to be comparable to that of an equal amount of incremental EC power, as expected with first-pass FW absorption on core electrons of 76%. Antenna loading is in quantitative agreement with modeling when edge density profiles measured with a reflectometer adjacent to the antenna are used in the model. Local deuterium puffing is used in some cases to increase the loading and hence the coupled power. Comparison of gas puffing and other techniques to increase the antenna loading are evaluated w...
30 MHz high-harmonic fast wave (HHFW) heating and current drive are being developed to assist fully ...
Plasma heating using fast waves was successfully performed on the Experimental Advanced Superconduct...
The physics of non-inductive current drive and current profile control using the fast magnetosonic w...
Up to 2.5 MW of fast wave (FW) heating power has been coupled to the core of ELMing H-mode discharge...
Fast Waves (FWs) at 60 MHz and 90 MHz are used in DIII‐D for central electron heating and current dr...
Fast Wave (FW) heating and electron cyclotron heating (ECH) are used in the DIII-D tokamak to study ...
Efficient direct electron heating by fast waves has been observed on the DIII-D tokamak. A four stra...
The physics of electron heating and current drive with the fast magnetosonic wave has been demonstra...
Recent improvements in high-harmonic fast wave (HHFW) core heating in NSTX are attributed to using l...
Coupling to plasma in the H-mode is essential to the success of future ignited machines such as CIT....
Initial experiments have been performed on the DIII-D tokamak on coupling, direct electron heating, ...
Fast waves (FWs) at 60 MHz and at 90 MHz are coupled to DIII-D discharges for central heating and cu...
Plasma heating using compressional Alfvén waves ["fast waves" (FWs)] in the ion cyclotron range of f...
One method of radio-frequency heating which shows theoretical promise for both heating and current d...
The impact of a contemplated conversion of the directly driven high power antenna arrays in DIII-D t...
30 MHz high-harmonic fast wave (HHFW) heating and current drive are being developed to assist fully ...
Plasma heating using fast waves was successfully performed on the Experimental Advanced Superconduct...
The physics of non-inductive current drive and current profile control using the fast magnetosonic w...
Up to 2.5 MW of fast wave (FW) heating power has been coupled to the core of ELMing H-mode discharge...
Fast Waves (FWs) at 60 MHz and 90 MHz are used in DIII‐D for central electron heating and current dr...
Fast Wave (FW) heating and electron cyclotron heating (ECH) are used in the DIII-D tokamak to study ...
Efficient direct electron heating by fast waves has been observed on the DIII-D tokamak. A four stra...
The physics of electron heating and current drive with the fast magnetosonic wave has been demonstra...
Recent improvements in high-harmonic fast wave (HHFW) core heating in NSTX are attributed to using l...
Coupling to plasma in the H-mode is essential to the success of future ignited machines such as CIT....
Initial experiments have been performed on the DIII-D tokamak on coupling, direct electron heating, ...
Fast waves (FWs) at 60 MHz and at 90 MHz are coupled to DIII-D discharges for central heating and cu...
Plasma heating using compressional Alfvén waves ["fast waves" (FWs)] in the ion cyclotron range of f...
One method of radio-frequency heating which shows theoretical promise for both heating and current d...
The impact of a contemplated conversion of the directly driven high power antenna arrays in DIII-D t...
30 MHz high-harmonic fast wave (HHFW) heating and current drive are being developed to assist fully ...
Plasma heating using fast waves was successfully performed on the Experimental Advanced Superconduct...
The physics of non-inductive current drive and current profile control using the fast magnetosonic w...
Add to ORKG