• Monthly Duck's Village
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• s.190
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• pp.46-47
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• 2019

• Monthly Duck's Village
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• s.211
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• pp.45-47
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• 2021

• Monthly Duck's Village
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• s.205
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• pp.46-47
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• 2020

• Monthly Duck's Village
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• s.200
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• pp.44-47
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• 2020

• Monthly Duck's Village
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• s.207
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• pp.43-47
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• 2020

• Monthly Duck's Village
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• s.206
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• pp.47-48
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• 2020

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• s.201
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• 2020

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• 2020

• 순환기질환의공학회:학술대회논문집
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• 2005.12a
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• pp.47-50
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• 2005

• Bulletin of the Korean Mathematical Society
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• v.47 no.6
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• pp.1181-1188
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• 2010

q-Volkenborn integrals ([8]) and fermionic invariant q-integrals ([12]) are introduced by T. Kim. By using these integrals, Euler q-zeta functions are introduced by T. Kim ([18]). Then, by using the Euler q-zeta functions, S.-H. Rim, S. J. Lee, E. J. Moon, and J. H. Jin ([25]) studied q-Genocchi zeta functions. And also Y. H. Kim, W. Kim, and C. S. Ryoo ([7]) investigated twisted q-zeta functions and their applications. In this paper, we consider the q-analogue of twisted Lerch type Euler zeta functions defined by $${\varsigma}E,q,\varepsilon(s)=[2]q \sum\limits_{n=0}^\infty\frac{(-1)^n\epsilon^nq^{sn}}{[n]_q}$$ where 0 < q < 1, $\mathfrak{R}$(s) > 1, $\varepsilon{\in}T_p$, which are compared with Euler q-zeta functions in the reference ([18]). Furthermore, we give the q-extensions of the above twisted Lerch type Euler zeta functions at negative integers which interpolate twisted q-Euler polynomials.