The Compact Linear Collider (CLIC) main linac uses waveguide damped structure as its baseline design. The current baseline structure design written in the CLIC Conceptual Design Report is named "CLIC-G." Recent activities on the CLIC-G design including high power tests on structure prototypes and the study of machining cost assessment had raised the need of reoptimizing the structure design to minimize the machining cost and the pulse surface temperature rise. This work presents optimization of the structure geometry, high-order-mode (HOM) damping loads and the design of a HOM-free power splitter for the input coupler. Compared to the current baseline design CLIC-G, the new structure design reduced the pulse surface temperature rise, input power and manufacturing cost and achieves better suppression to the long range transverse wakefield. Cell disks and damping loads for the new structure design are also more compact than those of the CLIC-G design.
Milling on two longitudinally split halves is one method to manufacture accelerating structures. This method is simple and allows one to avoid electromagnetic fields at bonding joints, making it attractive in manufacturing high-gradient accelerating structures. An X-band structure design with strong wakefield damping based on this manufacturing approach is studied in this work as an alternative design for the Compact Linear Collider (CLIC) main linac accelerating structures. The geometry of the structure is optimized to greatly reduce the surface fields, improve the efficiency, and suppress the wakefield. This structure features the baseline design of the CLIC main linac with additional advantages. This study may serve as a reference for designing other high frequency-band corrugated structures.
China
has been promoting one of the world’s largest campaigns
for clean heating renovation since 2017. Here, we present an integrated
cost–benefit analysis in a major prefecture-level city by combining
a large-scale household energy survey and PM2.5 exposure
measurement, high-resolution chemical transport simulation, and health
impact assessment. We find that the completed renovation decreases
the share of solid fuels in the heating energy mix from 96 to 6% and
achieves a concomitant reduction of cooking solid-fuel use by 70%.
The completed renovation decreases the ambient PM2.5 concentration
in Linfen by 0.5–5 μg m–3 (2.4 μg
m–3 on average) and decreases the integrated PM2.5 exposure by 4.2 (3.5–5.0) μg m–3. The renovation is estimated to avoid 162 (125–225) and 328
(254–457) premature deaths annually based on two health impact assessment methods. The ratios
of monetized health benefits to cost are 1.51 (0.73–2.59) and
3.06 (1.49–5.23) based on the above two methods. The benefit-to-cost
ratio is projected to remain high if the renovation is further expanded.
More polluted and less wealthy households enjoy larger health benefits
but also experience a higher expense increase, suggesting that a more
carefully designed subsidy policy is needed to protect low-income
households.
Choke-mode damped structures are being studied as an alternative design to waveguide damped structures for the main linac of the Compact Linear Collider (CLIC). Choke-mode structures have the potential for lower pulsed temperature rise and simpler and less expensive fabrication. An equivalent circuit model based on transmission line theory for higher-order-mode damping is presented. Using this model, a new choke geometry is proposed and the wakefield performance is verified using GDFIDL. This structure has a comparable wakefield damping effect to the baseline design which uses waveguide damping. A prototype structure with the same iris dimensions and accelerating gradient as the nominal CLIC design, but with the new choke geometry, has been designed for high-power tests.
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