Graphs and Combinatorics (1999) 15 : 463±471
Graphs and Combinatorics ( Springer-Verlag 1999
3; k-Factor-Critical Gr...
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Graphs and Combinatorics (1999) 15 : 463±471
Graphs and Combinatorics ( Springer-Verlag 1999
3; k-Factor-Critical Graphs and Toughness* MinyÇong Shi1, Xudong Yuan 1y , Mao-cheng Cai1, and Odile Favaron2 1 Institute of Systems Science, Academia Sinica, Beijing 100080, China 2 LRI, URA 410 CNRS, BaÃt. 410, Universite de Paris-Sud, 91405 Orsay cedex, France
Abstract. A graph is
r; k-factor-critical if the removal of any set of k vertices results in a graph with an r-factor (i.e. an r-regular spanning subgraph). Let t
G denote the toughness of graph G. In this paper, we show that if t
G V 4, then G is
3; k-factor-critical for every non-negative integer k such that n k even, k < 2t
G ÿ 2 and k U n ÿ 7.
1. Introduction All graphs G
V ; E under consideration are simple and ®nite. The following notation and de®nitions will be used. If A J V , we denote by hAi the subgraph of G induced by A and write G ÿ A for hV nAi. Sometimes we use T to denote the subgraph hTi of G. For a vertex x of G, NA
x is the set of neighbors of x in A and dA
x jNA
xj. We denote by d
G the minimum degree of G. For any two subsets A and B of V, E
A; B is the set of edges between A and B and e
A; B jE
A; Bj. In particular, for B A, we simply write E
A for E
A; A and e
A for e
A; A. For an S J V , let o
G ÿ S denote the number of connected components of G its toughness is de®ned by t
G : ÿ S. When G is not complete, jSj j S is a cutset of G . Obviously by the de®nition of t
G, if G is min o
G ÿ S not complete, then d
G V 2t
G. An r-factor of G, where r is a positive integer, is an r-regular spanning subgraph of G. A graph G is said to be (r; k)-factor-critical if G ÿ X admits an r-factor for every subset X of k elements of V. Tutte gave necessary and su½cient conditions for a graph to have an r-factor ([7] for r 1 and [8] for r V 2). Let us recall these conditions for r V 2. For a given positive integer r and a pair S; T of disjoint subsets of V, we call a component C of G ÿ
S U T odd if rjCj e
T; C is odd. Let o1
S; T and l o
U denote the numbers of odd components P and components of U : G ÿ
S U T, respectively. Let qG
S; T : rjSj ÿ rjTj v A T dGÿS
v ÿ o1
S; T. * Research partially supported by National Natural Science Foundation of China y Present address: Department of Mathematics, Guanxi Normal University, Guilin 541004, China
464
M. Shi et al.
Theorem A. (Tutte [8]): (i) qG
S; T has always the same parity as nr. (ii) G has an r-factor if and only if qG
S; T V 0 for every pair S; T of disjoint subsets of V. Using Tutte's Theorem, Liu and Yu found the following characterization of
r; k-factor-critical graphs. Theorem B. (Liu and Yu [6]): Let r; k be integers with r V 2 and k V 0, and G a graph of order n V r k 1. Then G is
r; k-factor-critical if and only if qG
S; T V rk for any pair S; T of disjoint subsets of V with jSj V k. The following result was conjectured by Liu and Yu [6] and was proved by Cai, Favaron and Li [1] and by Enomoto [2] independently. Theorem C. Let G be a graph of order n with t
G V 2. Then G is
2; kfactor-critical for every non-negative integer k such that k U 2t
G ÿ 2 and k U n ÿ 3. The following open problem was proposed in [1]. Open problem: For larger r, determine functions t0
r and k0
t
G; r such that any graph with t
G > t0
r is
r; k-factor-critical for every non-negative integer k with
n kr even, k U k0
t
G; r and k U n ÿ
r 1. The purpose of this paper is to present the following main result concerning this problem for r 3. Theorem 1. Suppose t
G V 4. Then G is
3; k-factor-critical for every non-negative integer k with n k even, k < 2t
G ÿ 2 and k U n ÿ 7. In the next section, we give the proof of Theorem 1. In the last section, we indicate directions for further research. 2. Proof of Theorem 1 The proof is by contradiction. Suppose Theorem 1 were not true, let G be a counterexample, that is, G satis®es the conditions of Theorem 1 but is not a
3; kfactor-critical for some k, where k is an integer with n k even, k < 2t
G ÿ 2 and n V k 7. Obviously, G is not complete. Let us choose a pair of disjoint subsets
S; T of V with jSj V k such that: (i) qG
S; T is minimum; and (ii) subject to (i), T is minimal under inclusion. Let jSj s; jTj t; s 0 s ÿ k: P Then, by Theorem B, qG
S; T 3s ÿ 3t v A T dGÿS
v ÿ o1
S; T < 3k and, by Theorem A (i), qG
S; T U 3k ÿ 2. U : G ÿ
S U T;
l o
U;
3; k-Factor-Critical Graphs and Toughness
465
P Note that T 6 q, for otherwise v A T dGÿS
v 0. Then o1
S; T V 3s ÿ
3k ÿ 2 V 2. So S is a cutset of G, and s jSj V t
G o1
S; q > k2 o1
S; q. Since o1
S; q V 2, s > k o1
S; q and thus 3k ÿ 2 V 2 qG
S; T 3s ÿ o1
S; q > 3k 2o1
S; q, a contradiction. Claim 1. For any v A T, dGÿS
v U o1
S; T ÿ o1
S; T ÿ v 1, and dT
v U 1. In particular, dGÿS
v U l 1 for any v A T. Proof. For any v A T, let T 0 T ÿ fvg. Then qG
S; T 0 V qG
S; T 2 by the choice of
S; T and by parity. So 2 U qG
S; T 0 ÿ qG
S; T 3 ÿ dGÿS
v o1
S; T ÿ o1
S; T 0 , implying dGÿS
v U o1
S; T ÿ o1
S; T 0 1 U o1
S; T 1 U l 1. Obviously e
v; U V o1
S; T ÿ o1
S; T 0 , yielding dT
v dGÿS
v ÿ e
v; U U dGÿS
v ÿ
o1
S; T ÿ o1
S; T 0 U 1. By Claim 1, hTi consists of some isolated vertices and some independent edges. Let T1 be a maximal independent vertex set in hTi and T2 T ÿ T1 . Then T2 is also independent if T2 0 q, and jT2 j U jT1 j. Claim 2. U 0 q. Proof. Suppose U q. If jT1 j U 1, then jTj U 2; jSj n ÿ jTj V n ÿ 2 V k 5. So qG
S; T V 3jSj ÿ 3jTj V 3
k 5 ÿ 6 > 3k, a contradiction. Hence jT1 j V 2, S is a cutset of G and G ÿ S contains P jT1 j components. We have jSj V t
GjT1 j and qG
S; T 3jSj ÿ 3jTj u A T dGÿS
u ÿ o1
S; T V 3t
GjT1 j ÿ 3
jT1 j jT2 j 2jT2 j V 3t
GjT1 j ÿ 4jT1 j V 2
3t
G ÿ 4 > 3
k 2 ÿ8 3k ÿ 2, a contradiction. By Claim 2, we have l V 1. Claim 3. (i) If there exists A H
G ÿ S such that S U A is a cutset of G, then s 0 V 3 ÿ jAj. In particular, s 0 V 1 if jAj U 2. If G ÿ
S U A contains at least three components, then s 0 V 7 ÿ jAj. In particular, s 0 V 1 if jAj U 6. (ii) s 0 dGÿS
x V 3 for each x A U U T. Proof. (i) If there exists A H
G ÿ S such that S U A is a cutset of G, then jS U Aj V 2t
G > k 2 and thus s 0 s ÿ k >
k 2 ÿ jAj ÿ k 2 ÿ jAj. Since s 0 is an integer, s 0 V 3 ÿ jAj. If jAj U 2, then s 0 V 1. If G ÿ
S U A contains at least three components, then, since t
G V 4 and k2 ; jS U Aj V 3t
G V 4 2t
G > 4
k 2 k 6. Hence, s 0 t
G > 2 k jAj > k 6 and since s 0 is an integer, s 0 V 7 ÿ jAj. And if jAj U 6, then s 0 V 1. (ii) For each x A U U T, s dGÿS
x V d
G V 2t
G > k 2, yielding (ii) since s dGÿS
x is an integer. Claim 4. jTj t V 4. Proof. Suppose ®rst t U 2, then,Pby Claim 3 (ii), 3k ÿ 2 V qG
S; T V 3 s P 0 0 0 x A T
dGÿS
x ÿ 3 ÿ l V 3k x A T
s dGÿS
x ÿ 3 s ÿ l V 3k s ÿ l, k2 implying s 0 U l ÿ 2. Hence l V 2 and thus s t V t
G l > l V k l. There2 0 fore s s ÿ k > l ÿ t V l ÿ 2, a contradiction.
466
M. Shi et al.
If t 3, then 3k ÿ 2 V qG
S; T V 3s
X
dGÿS
x ÿ 3 ÿ l
xAT
V 3k
X
s 0 dGÿS
x ÿ 3 ÿ l:
xAT
So l V 2 and if l 2, then s 0 dGÿS
x 3 for each x A T. If l V 3 then, by Claim 3 (i) applied with A T, s 0 V 7 ÿ jTj 4 and thus 3k ÿ 2 V qG
S; T V 3
k 4 ÿ 9 ÿ l. Hence l V 5. On the other hand, since s t V t
Gl > t
G
l ÿ 2 k 2, we have 3k ÿ 2 V qG
S; T > 3t
G
l ÿ 2 3
k 2 ÿ 9 ÿ 9 ÿ l V 11l 3k ÿ 36 since t
G V 4. This yields 11l < 34, a contradiction. Hence l 2. Under this condition, we have s 0 dGÿS
x 3 for each x A T and l o1
S; T by (*), thus two components are odd. Let C1 , C2 be the two components of hUi, We check three cases. If s 0 V 2, then dGÿS
x U 1 for any x A T. Let l 0 o
hU U Ti, then l 0 V 2. Hence s V l 0 t
G, s 0 s ÿ k > l 0 t
G ÿ
2t
G ÿ 2 2
l 0 ÿ 2t
G. Considering s 0 dGÿS
x 3 for each x A T, we get 3 > 2
l 0 ÿ 2t
G dGÿS
x and thus dGÿS
x 0 for each x A T. This implies l 0 V 3 and contradicts with 1 >
l 0 ÿ 2t
G since t
G V 4. When s 0 U 1, notice t 3 and dT
x U 1 for any x A T, then there exist two non-adjacent vertices in T. If s 0 1, then dGÿS
x 2 for any x A T, and jU U Tj V k 7 ÿ
k 1 6. If jU U Tj V 7, let x; y be two non-adjacent vertices in T, and A NGÿS
fx; yg, then T U U ÿ
A U fx; yg 0 q, G ÿ
S U A has at least three components. As jAj U 4, s 0 V 3 by Claim 3 (i), a contradiction. If jU U Tj 6, then n k s 6 k 2k 7 is odd, a contradiction. If s 0 0, then dGÿS
x 3 for any x A T, and jU U Tj V 7. If jU U Tj V 9, similarly we arrive at a contradiction by Claim 3 (i). So what remain to be considered are the cases jUj 4 or 5. If jUj 4, then n k s 7 k 2k 7 is odd, a contradiction. If jUj 5, we may assume jC1 j < jC2 j, then jC1 j U 2. If jC1 j 1, say C1 fxg, then jC2 j 4 and e
x; T is even as C1 is odd, thus e
C1 ; T U 2 for jTj 3. But, by Claim 3 (ii), e
x; T dGÿS
x V 3, a contradiction. Thus jC1 j 2 and jC2 j 3. As C1 is odd, e
C1 ; T is odd too. By Claim 3 (ii), e
C1 ; T V 4, implying e
C1 ; T V 5. Similarly, e
C2 ; T is even and e
C2 ; T V 3, yielding e
C2 ; T V 4. Therefore e
T 0. So G ÿ
S U U consists of three components, by Claim 3 (i) s 0 V 2, a contradiction. Claim 5. (i) jSj jT2 j e
T1 ; U ÿ l V t
GjT1 j. (ii) If 1 U jT2 j < jT1 j, then jSj jT2 j e
T2 ; U V t
G
jT2 j 1. Proof. Let C1 ; C2 ; . . . ; Cl be the components of U, L1 fCi j e
Ci ; T1 > 0g and L2 fCi j e
ui ; T1 1 for some ui A Ci g. Clearly L2 J L1 . We may assume L1 fC1 ; C2 ; . . . ; Cl1 g and L2 fC1 ; C2 ; . . . ; Cl2 g (l2 U l1 ). For each Ci A L2 ,
3; k-Factor-Critical Graphs and Toughness
467
choose ui A Ci with e
ui ; T1 1. Let U2 fui j i 1; 2; . . . ; l2 g, U1 fu A U j e
u; T1 > 0g and U3 U1 ÿ U2 . Then jU3 j U e
T1 ; U ÿ l1 . Let G1 G ÿ
S U T2 U U3 . Then vertices in T1 belong to di¨erent components of G1 since T1 is independent. Hence o
G1 V jT1 j
l ÿ l1 . First let us show (i). Seeing t V 4, jT1 j V 2, implying o
G1 V 2. Thus jS U T2 U U3 j V t
G o
G1 V t
G
jT1 j l ÿ l1 . On the other hand, jS U T2 U U3 j U jSj jT2 j e
T1 ; U ÿ l1 . We have jSj jT2 j e
T1 ; U ÿ l1 V t
Go
G1 V jSj jT2 j e
T1 ; U ÿ l V t
GjT1 j
t
G ÿ 1
l ÿ l1 V t
G
jT1 j l ÿ l1 , t
GjT1 j, as required. Now we show (ii). Let T0 be the set of vertices in T1 which are not adjacent with vertices in T2 . Since jT2 j < jT1 j, T0 0 q by Claim 1. Let G2 G ÿ
S U NG
T2 . Then G2 contains at least jT2 j 1 V 2 components. Therefore, jSj e
T2 ; U jT2 j V jSj e
T2 ; U e
T2 ; T1 V jS U NG
T2 j V t
G
jT2 j 1. Claim 6. T is not independent in G. Proof. Assuming T is independent, then T T1 and T2 q. By Claim 5P (i), jSj e
T; U ÿ l V t
GjTj. Therefore 3k ÿ 2 V qG
S; T 3s ÿ 3t 0 0 x A T dGÿS
x ÿ o1
S; T V 2
k s ÿ 3t jSj e
T; U ÿ l V 2k 2s k2 , this
t
G ÿ 3t V 2k 4
t
G ÿ 3 as t V 4. On one hand, since t
G > 2 yields 3k ÿ 2 > 2k 2
k 2 ÿ 12 4k ÿ 8 and thus k < 6; on the other hand, since t
G V 4; 3k ÿ 2 V 2k 4 and thus k V 6, a contradiction. In order to complete the proof, we distinguish two cases according to whether jT2 j < jT1 j or jT2 j jT1 j. Case 1. jT2 j < jT1 j. e
T1 ; U ÿ l V t
GjT1 j and jSj jT2 j By Claim 5 (i) and (ii), jSj jT2 j P e
T2 ; U V t
G
jT2 j 1. So 2jSj u A T dGÿS
u ÿ o1
S; T V 2jSj 2jT2 j e
T1 ; U e
T2 ; U ÿ l V t
G
jT1 j jT2 j 1 t
G
t 1. We have 3k ÿ 2 V qG
S; T V k s 0 ÿ 3t t
G
t 1 k s 0
t
G ÿ 3
t ÿ 4 4
t
G ÿ 3 t
G and thus 2k V s 0
t
G ÿ 3
t ÿ 4 5t
G ÿ 10. If k U 5, then, since t
G V 4; 10 V 2k V s 0
t
G ÿ 3
t ÿ 4 10 and thus, since t V 4, we get s 0 0 and t 4. By Claim 6, hTi consists of one edge and two isolated vertices. Let x1 and x2 be two non-adjacent vertices. Clearly o
G ÿ
S U NGÿS
x1 U NGÿS
x2 V 3, thus s dGÿS
x1 dGÿS
x2 V 3t
G > k 6, yielding dGÿS
x1 dGÿS
x2 V 7. We may assume dGÿS
x1 V 4, then l V dGÿS
x1 ÿ 1 V 3 by Claim 1. But, by Claim 3 (i), s 0 V 3 since G ÿ
S U T contains at least three components, a contradiction. k2 , 2k > s 0
t
G ÿ 3
t ÿ 4 t
G 2k ÿ 6, If k V 6 then, since t
G > 2 and thus 2 > s 0
t
G ÿ 3
t ÿ 4 as t
G V 4. If t V 5, then s 0 0. As in the case k U 5, we can obtain s 0 V 2, a contradiction. Then t 4 by Claim 4, and thus s 0 U 1. If s 0 0 or l V 3, similarly, we can obtain a contradiction. Hence, s 0 1 and l U 2. Now let T1 fx1 ; x2 ; x3 g J T, with no two vertices adjacent in T. Let A NGÿS
T1 and for 1 U i 0 j U 3; Aij NGÿS
fxi ; xj g. By Claim 1, jAij j U dGÿS
xi dGÿS
xj U 6. Notice G ÿ
S U Aij has at least three components, by
468
M. Shi et al.
Claim 3 (i), then 1 s 0 V 7 ÿ jAij j. Hence, jAij j 6 for all 1 U i 0 j U 3. Therefore, jAj 9 and NU
T1 8. Since n ÿ k is even, s 0 t jUj 5 jUj is even and thus UnNU
T1 0 q. Then the set G ÿ
S U A has at least four components and 1 k 9 V 4t
G > 2k 4, yielding k < 6, a contradiction. Case 2. 1 U jT2 j jT1 j. Claim 7. l s 0 U 9 ÿ t and t U 6. Proof. Since jT1 j jT2 j, t is even, T2 is also a maximal independent set of T. By Claim (5) (i), we have jSj jT2 j e
T P 1 ; U ÿ l V t
GjT1 j and jSj jT1 j e
T2 ; U ÿ l V t
GjT2 j. So, 2jSj u A T dGÿS
u ÿ o1
S; T V 2jSj jT2 j jT1 j e
T1 ; U e
T2 ; U ÿ l V t
G
jT1 j jT2 j l t
Gt l. We have 3k ÿ 2 V qG
S; T V k s 0 ÿ 3t t
Gt l V k s 0
t
G ÿ 3
t ÿ 4 4
t
G ÿ 3 l: k2 , then 2k V s 0
t ÿ 4
2k 4 ÿ 12 Since t
G V 4, t V 4 and t
G > 2 l 2, and s 0 l t < 10, thus s 0 l U 9 ÿ t. By Claim 1 and Claim 3 (ii), 3 ÿ s 0 U dGÿS
v U l 1 for all v A T. Hence, 0 s l V 2, yielding 2 t U 9 and thus, since t is even, t U 6. If l V 3 then, by Claim 3 (i), s 0 V 7 ÿ jTj and thus l s 0 t V l 7 V 10, a contradiction. Therefore l U 2. By Claim 4 and Claim 7, t 4 or 6 and we consider two cases. Subcase 2.1. t 6; 2 U l s 0 U 3 and 1 U l U 2 (which implies by Claim 1, dGÿS
v U 3 for all v A T). In this case, hTi consists of three independent edges xi yi with 1 U i U 3. If l 1, then s 0 U 2. By Claim 1, dGÿS
v U 2 for any v A T. Let A NGÿS
fx1 ; x2 g, then jAj U 4 and G ÿ
S U A contains at least three components. By Claim 3 (i), s 0 V 3, a contradiction. If l 2 and s 0 0, then by Claim 1 and Claim 3 (ii), dGÿS
v 3 for any v of T. Let A NGÿS
fx1 ; x2 g. Then jAj U 6 and G ÿ
S U A contains at least three components. By Claim 3 (i), s 0 V 1, a contradiction. If l 2 and s 0 1, then by the proof of Claim 7, we have 2k V s 0
t
G ÿ 3t l 2 V 5 2
t
G ÿ 3 4 > 9 k 2 ÿ 6 k 5 since t
G V 4, k2 and t 6, thus k V 6. t
G V 2 We take T1 fx1 ; x2 ; x3 g; A NGÿS
T1 and for 1 U i 0 j U 3, Aij NGÿS
fxi ; xj g. Then, as in the proof of Case 1 for k V 6, we can obtain a contradiction. Subcase 2.2. t 4; 2 U l s 0 U 5 and 1 U l U 2. In this case, hTi consists of two independent edges xi yi with i 1; 2. Moreover, if 3s 0 ÿ l V 7, then 3k ÿ 2 V qG
S; T V 3k 7 ÿ 3t
4 e
T; U V 3k ÿ 1, a contradiction. Hence, 3s 0 U 6 l U 8 and thus s 0 U 2. So we only need to check the following cases. If l 1, then s 0 V 1.
3; k-Factor-Critical Graphs and Toughness
469
When s 0 2, then S is not Pa cutset of G (if S is a cutset of G , then we have s V 3 by Claim 3 (i) ), thus v A T dGÿS
v V 6. We also have 3k ÿ 2 V qG
S; T V 3k ÿ 1, a contradiction. When s 0 1, then jUj V n ÿ k ÿ 1 ÿ 4 V 2. By Claim 1 and Claim 3 (ii), dGÿS
v 2 for each v A T and thus e
U; T 4. Then jUj V 3, otherwise U consists of two vertices, then hUi is an even component since e
T; U 4, so we have 3k ÿ 2 V qG
S; T V 3k 3 ÿ 12 8 3k ÿ 1, a contradiction. But if jUj V 3, take A NGÿS
fx1 ; x2 g, so jAj U dGÿS
x1 dGÿS
x2 U 4 and Gÿ
S U A contains at least three components. By Claim 3 (i), s 0 V 3, a contradiction. If l 2, let C1 and C2 be the two components of U with jC1 j U jC2 j. By Claim 1, dGÿS
v U 3 for each v A T. When s 0 2, either e
U; T V 3 or e
U; T U 2. In the former case 3k ÿ 2 V qG
S; T V 3
k 2 ÿ 12 7 ÿ 2 3k ÿ 1, and in the latter case S is a cutset of G since l 2, thus s 0 V 3 by Claim 3 (i), a contradiction. When s 0 1, then 3 V dGÿS
v V 2 for any v A T by Claim 3 (ii), and jUj V n ÿ k ÿ 1 ÿ 4 V 2. Then there are at least three vertices in T with dGÿS
v 2 and thus 4 U e
T; U U 5. For otherwise, there are at most two vertices in T with dGÿS
v 2, and then 3k ÿ 2 V qG
S; T V 3k 3 ÿ 12 10 ÿ 2 3k ÿ 1. Similarly if jUj V 3, there exists A H
T U U with jAj U 4 such that G ÿ
S U A contains at least three components. By Claim 3, s 0 V 3, a contradiction. If jUj 2, then each component of U consists of just one vertex. If e
T; U 5, then one component of U is even, thus 3k ÿ 2 V qG
S; T V 3k 3 ÿ 12 5 4 ÿ 1 3k ÿ 1, a contradiction. If e
T; U 4, then dGÿS
v 2 for each v A T U U by Claim 3 (ii), and hT U Ui consists of two triangles or a cycle of length 6. The former case implies s 0 V 3, the latter case implies that there exists A H
T U U with jAj 3 such that G ÿ
S U A contains three components. By Claim 3, s 0 V 4, a contradiction. When s 0 0, then jUj n ÿ k ÿ 4 V 3. By Claim 1 and Claim 3 (ii), dGÿS
v 3 for each v A T, and e
U; T 8. And thus two components C1 and C2 of U are odd, for otherwise, 3k ÿ 2 V qG
S; T V 3k ÿ 12 12 ÿ 1 3k ÿ 1. Hence, jUj V 4, otherwise jUj 3 implies that jC1 j 1 and jC2 j 2, and that one of them is an even component since e
C1 ; T e
C2 ; T 8. If jUj V 5, take A NGÿS
fx1 ; x2 g, then A H
T U U with jAj U 6, and G ÿ
S U A contains at least three components, by Claim 3 (i), s 0 V 1, a contradiction. If jUj 4, we distinguish two cases. For jC1 j 1 and jC2 j 3, then each vertex in C2 is adjacent to at least two vertices of T. For otherwise, we can choose one vertex v 0 A C2 , and two vertices x; y A T such that any two vertices are non-adjacent in G, let A
T U U ÿ fx; y; v 0 g, so jAj 5 and G ÿ
S U A contains at least three components. By Claim 3 (i), s 0 V 2, a contradiction. Then e
C2 ; T V 6, thus dGÿS
v e
C1 ; T U 2, where C1 fvg, that contradict with Claim 3 (ii). For jC1 j jC2 j 2, since both C1 ; C2 are odd components, then both e
C1 ; T; e
C2 ; T are odd numbers. Since dGÿS
v V 3 for any v A T U U by Claim 3 (ii), so for i 1; 2, e
Ci ; T V 6 ÿ 2 4, and thus e
Ci ; T V 5, and 8 V e
U; T V 10, a contradiction. 0
470
M. Shi et al.
The proof is complete.
r
3. Remark Remark 1. The condition k < 2t
G ÿ 2 is necessary for Theorem 1 to be true. Indeed, if k 2t
G ÿ 2, the graph G is not necessarily
3; k-factor-critical, as shown by the following example. Let graph G consist of a clique Kkm2 and a vertex fxg which is adjacent to k 2 vertices of the Kkm2 , where m is odd. Then k2 , i.e. k 2t
G ÿ 2, and is not a
3; kthe graph G has toughness t
G 2 factor-critical by Theorem B since qG
S; T 3k ÿ 2, where S consists of k vertices which are adjacent to x and T fxg. Remark 2. The condition n V k 7 is necessary for Theorem 1 to be true. Indeed, if n k 6, the graph G is not necessarily
3; k-factor-critical, as shown by the following example. Let graph G consist of a clique S F Kk1 and a cycle with ®ve vertices such that the vertices of the cycle are adjacent to all the vertices of the k3 and is not a
3; kclique. Then the graph G has toughness t
G 2 factor-critical by Theorem B since qG
S; T 3
k 1 ÿ 9 6 ÿ 2 3k ÿ 2, where T consists of 3 vertices of the cycle such that G ÿ
S U T consists of two isolated vertices. For r 1, a theorem similar to Theorem C and the main Theorem already exists: Theorem D. (Favaron [5]). Let G be a graph of order n with t
G > 1. Then G is
1; k-factor-critical for every non-negative integer k such that n k is even, k U 2t
G ÿ 1 and k U n ÿ 2. Conjecture E. Let G be a graph of order n and toughness t
G. Then there exists an t0
r and an integer k0 such that G is
r; k-factor-critical when t
G V t0
r, n k even when r is odd, k U 2t
G ÿ r and k U n ÿ k0 . Note. After this paper was accepted, Professor Enomoto kindly informed us that the problem due to Cai et al. (Conjecture E), had been completely solved [3]. References 1. Cai, M., Favaron O., Li, H.:
2; k-factor-critical graphs and toughness, Graph. Comb. 15(2), 137±142 2. Enomoto, H.: Toughness and the existence of k-factor (III), Discrete Math. 189, 277± 282 (1998) 3. Enomoto, H., Hagia, M.: Toughness and the existence of k-factor (IV), submitted 4. Enomoto, H., Jackson, B., Katerinis P., Saito, A.: Toughness and the existence of k-factors, J. Graph Theory 9, 87±95 (1985)
3; k-Factor-Critical Graphs and Toughness
471
5. Favaron, O.: On k-factor-critical graphs, Discuss. Math. Graph Theory 16, 41±51 (1996) 6. Liu G., Yu, Q.: k-factors and extendability with prescribed components, submitted 7. Tutte, W.T.: The factorization of linear graphs, J. Lond. Math. Soc. 22, 107±111 (1947) 8. Tutte, W.T.: The factors of graphs, Can. J. Math. 4, 314±328 (1952)
Received: July 28, 1997 Revised: September 21, 1998