This means that when the brominated molecule absorbs energy, it is more likely to emit light compared to the other two molecules. This is due to the presence of bromine atoms which have a higher atomic number than carbon or hydrogen atoms, and thus have a greater ability to interact with light. Additionally, the brominated molecule has a high quantum efficiency, meaning that a larger proportion of absorbed energy is converted into light emission. Overall, these factors contribute to the higher radiative luminescence intensity observed in the brominated molecule.
![/data # iw --debug dev wlan0 connect -w "lucky-5g" auth open key 0:1234567890
Usage: iw [options] dev connect [-w] [] [] [auth open|shared] [key 0:abcde d:1:6162636465] [mfp:req/opt/no]
Join the network with ...](https://linuxcpp.0voice.com/zb_users/upload/2023/05/202305162239148267954.png)
![驱动代码
void kalRxTaskletSchedule(struct GLUE_INFO *pr)
{
static unsigned int num = 0;
tasklet_hi_schedule(&pr->rRxTask[(num++)%NR_CPUS]);
// tasklet_hi_schedule(&pr->rRxTask);
DBGLOG(HAL, ERROR,](https://linuxcpp.0voice.com/zb_users/upload/2023/05/202305162226144313964.png)
