Some identities of special numbers and polynomials arising from p$-adic integrals on Zp

In recent years, studying degenerate versions of various special polynomials and numbers have attracted many mathematicians. Here we introduce degenerate type 2 Bernoulli polynomials, fully degenerate type 2 Bernoulli polynomials and degenerate type 2 Euler polynomials, and their corresponding numbers, as degenerate and type 2 versions of Bernoulli and Euler numbers. Regarding to those polynomials and numbers, we derive some identities, distribution relations, Witt type formulas and analogues for the Bernoulli's interpretation of powers of the first $m$ positive integers in terms of Bernoulli polynomials. The present study was done by using the bosonic and fermionic $p$-adic integrals on $\mathbb{Z}_p$.


INTRODUCTION
Studies on degenerate versions of some special polynomials and numbers began with the papers by Carlitz in [3,4]. In recent years, studying degenerate versions of various special polynomials and numbers have regained interests of many mathematicians. The researches have been carried out by several different methods like generating functions, combinatorial approaches, umbral calculus, p-adic analysis and differential equations. This idea of studying degenerate versions of some special polynomials and numbers turned out to be very fruitful so as to introduce degenerate Laplace transforms and degenerate gamma functions (see [12]).
In this paper, we introduce degenerate type 2 Bernoulli polynomials, fully degenerate type 2 Bernoulli polynomials and degenerate type 2 Euler polynomials, and their corresponding numbers, as degenerate and type 2 versions of Bernoulli and Euler numbers. We investigate those polynomials and numbers by means of bosonic and fermionic p-adic integrals and derive some identities, distribution relations, Witt type formulas and analogues for the Bernoulli's interpretation of powers of the first m positive integers in terms of Bernoulli polynomials. In more detail, our main results are as follows.
As to the analogues for the Bernoulli's interpretation of power sums, in Theorem 2.6 we express powers of the first m odd integers in terms of type 2 Bernoulli polynomials b n (x), in Theorem 2.11 alternating sum of powers of the first m odd integers in terms of type 2 Euler polynomials E n (x), in Theorem 2.9 sum of the values of the generalized falling factorials at the first m odd positive integers in terms of degenerate Carlitz type 2 Bernoulli polynomials b n,λ (x), and in Theorem 2.17 alternating sum of the values of the generalized falling factorials at the first m odd positive integers in terms of degenerate type 2 Euler polynomials E n,λ (x). Witt type formulas are obtained for b n (x), B n,λ (x), E n (x), and E n,λ (x), respectively in Lemma 2.1, Theorem 2.7, Lemma 2.10 and Theorem 2.16. Distribution relations are derived for b n (x), and E n (x), respectively in Theorem 2.3 and Theorem 2.13.
In the rest of this section, we will introduce type 2 Bernoulli and Euler numbers, recall the bosonic and fermionic p-adic integrals and mention the degenerate exponential function.
Let p be a fixed odd prime number. Throughout this paper, Z p , Q p and C p will denote the ring of p-adic integers, the field of p-adic rational numbers and the completion of an algebraic closure of Q p , respectively. The p-adic norm | · | p is normalized by |p| p = 1 p . It is well known that the ordinary Bernoulli polynomials are defined by [2,5,14,15,17]).
When x = 0, B n = B n (0) are called the Bernoulli numbers. Also, the type 2 Bernoulli polynomials are given by For x = 0, b n = b n (0) are called the type 2 Bernoulli numbers so that they are given by In fact, the type 2 Bernoulli polynomials and numbers are slightly differently defined in [8].
For x = 0, E n = E n (0) are called the type 2 Euler numbers so that they are given by Again, the type 2 Euler polynomials and numbers are slightly differently defined in [8]. From (4) and (6), we note that E * n 1 2 = E n , (n ≥ 0), (see [8]).
Let f be a uniformly differentiable function on Z p . The bosonic (also called Volkenborn) p-adic integral on Z p is defined by , (see [10,11,13]). From (7), we note that . The fermionic p-adic integral on Z p was introduced by Kim as , (see [10,11]).

SOME IDENTITIES OF SPECIAL POLYNOMIALS ARISING FROM p-ADIC INTEGRALS ON Z p
From (8), we note that On the other hand, we have Therefore, by (13) and (14), we obtain the following lemma.
By (7), we get where d is a positive integer. Therefore, by (15), we obtain the following lemma.
Thus, by (16), we get By comparing the coefficients on both sides of (17), we get By Lemma 2.1 and (18), we get where d is a positive integer.
For r ∈ N, we consider the multivariate p-adic integral on Z p as follows: Now, we define the type 2 Bernoulli numbers of order r by By (20) and (21), we see that On the other hand, Therefore, by (22) and (23), we obtain the following theorem.
where T (m, r) are the central factorial numbers of the second kind. Therefore, by (24), we obtain the following theorem.  Now, we observe that On the other hand, By (27) and (28), we get Therefore, by (29), and interchanging m and n, we obtain the following theorem.
Theorem 2.6. For m ∈ N and n ∈ N ∪ {0}, we have We define the fully degenerate type 2 Bernoulli polynomials by When x = 0, B n,λ = B n,λ (0) are called the fully degenerate type 2 Bernoulli numbers. We note that Thus, by (31) and (12) we obtain (32) As is known, the degenerate Stirling numbers of the first kind are defined by Also, from (12) and (31) we observe that Therefore, from (32), (34) and (35), we have the following theorem.
Theorem 2.7. For n ≥ 0, we have As is known, the degenerate Carlitz type 2 Bernoulli polynomials are defined by Therefore, by (38) and (12), we obtain the following theorem.
Theorem 2.8. For n ≥ 0, we have For n ∈ N, by (8), we easily get By applying (39) to f (x) = e From (40), we derive the following equation.
Theorem 2.9. For n ≥ 0, m ∈ N, we have From (10), we observe that Thus from (43) and (12), we have the following lemma.
Theorem 2.11. For m ∈ N with m ≡ 1(mod2), n ∈ N ∪ {0}, we have The following lemma can be easily shown.
Let us apply Lemma 2.12 to f (y) = (x + y + 1/2) n . Then we have Therefore, by (49), we have the following theorem.
For r ∈ N, let us consider the following fermionic p-adic integral on Z p .
Let us define the type 2 Euler numbers of order r by On the other hand, Therefore, by (52) and (53), we obtain the following theorem.
Theorem 2.14. For n ≥ 0, we have From (51), we have Comparing the coefficients on both sides of (54), we obtain the following theorem.

CONCLUSION
In recent years, studying degenerate versions of various special polynomials and numbers have attracted many mathematicians and been carried out by several different methods like generating functions, combinatorial approaches, umbral calculus, p-adic analysis and differential equations. In this paper, we introduced degenerate type 2 Bernoulli polynomials, fully degenerate type 2 Bernoulli polynomials and degenerate type 2 Euler polynomials, and their corresponding numbers, as degenerate and type 2 versions of Bernoulli and Euler numbers. We investigated those polynomials and numbers by means of bosonic and fermionic p-adic integrals and derived some identities, distribution relations, Witt type formulas and analogues for the Bernoulli's interpretation of powers of the first m positive integers in terms of Bernoulli polynomials. In more detail, our main results are as follows.
As to the analogues for the Bernoulli's interpretation of power sums, in Theorem 2.6 we expressed powers of the first m odd integers in terms of type 2 Bernoulli polynomials b n (x), in Theorem 2.11 alternating sum of powers of the first m odd integers in terms of type 2 Euler polynomials E n (x), in Theorem 2.9 sum of the values of the generalized falling factorials at the first m odd positive integers in terms of degenerate Carlitz type 2 Bernoulli polynomials b n,λ (x), and in Theorem 2.17 alternating sum of the values of the generalized falling factorials at the first m odd positive integers in terms of degenerate type 2 Euler polynomials E n,λ (x). Witt type formulas were obtained for b n (x), B n,λ (x), E n (x), and E n,λ (x), respectively in Lemma 2.1, Theorem 2.7, Lemma 2.10 and Theorem 2.16. Distribution relations were derived for b n (x), and E n (x), respectively in Theorem 2.3 and Theorem 2.13.
As one of our future projects, we would like to continue to do researches on degenerate versions of various special numbers and polynomials, and find many applications of them in mathematics, sciences and engineering.