**2. Main**

We explain the results for computing-experiment, experiment-theory, and theorycomputing for the analysis of particle physics. While many previous works have only used 76 Particle Physics

Collider Detector at Fermilab (CDF) experiment in the USA and the Belle/Belle II

For computing-experiment, we construct and use the components of the e-Science research environment, including data production, data processing, and data analysis using collaborative tools. We also develop new computational tools for future experiments. In high energy physics, the goal of e-Science is to perform and/or analyze high energy physics experiments anytime and anywhere. We apply this system to the Belle II experiment at KEK. For data processing, WLCG is one of the original new research infrastructures that show how an effective collaboration might be conducted between users and facilities (Cho, 2007). The Asia Pacific area should develop both an e-Science platform and best practices for collaboration in order to fill the gaps in e-Science development between other continents. The Academia Sinica Grid Centre (ASGC), as the coordinator of the Asia federation under Enabling Grid in e-Science (EGEE), has worked closely with partners for region specific applications in data processing. For data analysis using collaborative tools, community building should be the foundation for collaboration rather than just offering technology. The e-Science research environment provides a trusted way to allow people, resources, and knowledge to connect and participate via a virtual organization. More and more countries will deploy a grid system and take part in the e-Science research environment. According to Simon C. Lin (Simon & Yen, 2009), we are widening the uptake of e-Science through close

For experiment-theory, we develop a combination of phenomenology and data analysis. Experiments give results and tools for theories and theories give feedback to experiments. We apply this system to the CDF, D0, and Belle experiments in order to probe the standard model and search for new physics. For theory-computing, we study lattice gauge theory and use the supercomputer at the Korea Institute of Science and Technology Information

Fig. 1. The paradigm of e-Science in high energy physics, which is a fusion of experiment,

We explain the results for computing-experiment, experiment-theory, and theorycomputing for the analysis of particle physics. While many previous works have only used

experiment at High Energy Accelerator Research Organization (KEK) in Japan.

collaboration regionally and internationally.

computing, and theory research.

(KISTI).

**2. Main** 

supercomputers, in our work computing results are combined with theory and experiment. We use a combination of supercomputers and an e-Science environment. The components of an e-Science environment are data production for remote shifts, data processing for grid farms, and data analysis using the Enabling Virtual Organization (EVO) collaborative tool.
