Methods for pruning the roots of tree seedlings

FIELD OF THE INVENTION

The present invention relates to the cultivation of trees, such as coniferous trees, and to methods of pruning the roots of tree seedlings.

BACKGROUND OF THE INVENTION

The demand for trees, such as coniferous trees, to provide lumber for making wood products continues to increase. There is therefore a need for methods that improve the growth rate of commercially desirable trees, so that the time from planting to harvest of the tree is reduced. The present inventors have discovered methods of pruning tree seedling roots that stimulate an unexpectedly high level of root growth. Enhanced root growth also promotes growth of the whole seedling, thereby improving the efficiency of commercial tree culture.

SUMMARY OF THE INVENTION

In accordance with the foregoing, in one aspect the present invention provides methods for pruning the roots of tree seedlings. The methods of this aspect of the invention include: (a) a first root pruning step wherein the roots of a majority of members of a population of tree seedlings are laterally pruned; and (b) a second root pruning step, that occurs after the first root pruning step, wherein the roots of the majority of members of the population of tree seedlings are again laterally pruned. In the practice of the methods of this aspect of the invention, the population of tree seedlings is arranged as at least two adjacent pairs of rows (hereinafter referred to as “row pairs”) of seedlings, and the roots of the majority of the seedlings are pruned shorter during the first pruning step than during the second pruning step. In some embodiments of the invention, the population of tree seedlings is arranged as six adjacent row pairs of seedlings. In some embodiment of the methods of the invention, a multiplicity of Coulter discs (hereinafter referred to as Coulters) are used to prune the seedling roots. Typically the second root pruning steps takes place within six months of the first root pruning step. For example, the first root pruning step can occur in July and the second root pruning step can occur in December of the same year.

In one embodiment, the present invention provides methods for pruning the roots of a population of tree seedlings wherein: (a) the population of tree seedlings comprises a first row pair, a second row pair, a third row pair, a fourth row pair, a fifth row pair, and a sixth row pair; (b) a first adjacent area is adjacent to the first row pair, and external to the population of tree seedlings; (c) a second adjacent area is adjacent to the sixth row pair, and external to the population of tree seedlings; (d) a first inter-row space is defined by the first row pair and the second row pair, a second inter-row space is defined by the second row pair and the third row pair, a third inter-row space is defined by the third row pair and the fourth row pair, a fourth inter-row space is defined by the fourth row pair and the fifth row pair, and a fifth inter-row space is defined by the fifth row pair and the sixth row pair; (e) the first pruning step utilizes a first Coulter, a second Coulter, a third Coulter, a fourth Coulter, a fifth Coulter, a sixth Coulter, a seventh Coulter, an eighth Coulter, and a ninth Coulter, wherein the first Coulter prunes roots in the first adjacent area, the second Coulter prunes roots in the first inter-row space, the third and fourth Coulters prune roots in the second inter-row space, the fifth Coulter prunes roots in the third inter-row space, the sixth and seventh Coulters prune roots in the fourth inter-row space, the eighth Coulter prunes roots in the fifth inter-row space, and the ninth Coulter prunes roots in the second adjacent area; and (f) the second pruning step utilizes a tenth Coulter, an eleventh Coulter, a twelfth Coulter, and a thirteenth Coulter, wherein the tenth Coulter prunes roots in the first adjacent area, the eleventh Coulter prunes roots in the second inter-row space, the twelfth Coulter prunes roots in the fourth inter-row space, and the thirteenth Coulter prunes roots in the second adjacent area.

The methods of the invention promote tree seedling root growth, thereby promoting the growth and development of the seedlings. The methods of the invention are useful in any situation in which it is desired to prune the roots of tree seedlings. For example, the methods of the invention are useful for pruning the roots of coniferous tree seedlings, thereby promoting the growth of a fibrous root system which, in turn, promotes the survival and growth of the whole seedling upon transplantation or outplanting to a new growth environment.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:

FIG. 1

shows an aerial view of a population of tree seedlings arranged as eight adjacent pairs rows (referred to as row pairs) of seedlings.

FIG. 2

shows a cross-sectional end view of the population of tree seedlings shown in FIG.

1

.

FIG. 3

shows an aerial view of a population of tree seedlings arranged as six adjacent row pairs.

FIG. 4

shows a cross-sectional end view of the population of tree seedlings shown in FIG.

3

.

FIG. 5

shows the location of the Coulters used in the first pruning step of a representative embodiment of a method of the invention to trim the roots of a population of seedlings arranged as shown in FIG.

4

.

FIG. 6

shows the location of the Coulters used in the second pruning step of a representative embodiment of a method of the invention to trim the roots of a population of seedlings arranged as shown in FIG.

4

.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

In one aspect, the present invention provides methods for pruning the roots of tree seedlings. The methods of this aspect of the invention include: (a) a first root pruning step wherein the roots of a majority of members of a population of tree seedlings are laterally pruned; and (b) a second root pruning step, that occurs after the first root pruning step, wherein the roots of the majority of members of the population of tree seedlings are laterally pruned. In the practice of the methods of this aspect of the invention, the population of tree seedlings is arranged as at least two adjacent row pairs of seedlings, and the roots of a majority of the seedlings are pruned shorter during the first pruning step than during the second pruning step.

The term “laterally pruned,” and grammatical equivalents thereof, refers to pruning the roots that grow outward from the vertical axis of a tree seedling. For example, when seedlings are arranged in adjacent row pairs, the seedling roots can be laterally pruned between the row pairs.

The term “majority” when used in the phrases, “majority of members of a population of tree seedlings,” or “majority of members of the population of tree seedlings,” or “majority of the seedlings,” means between 50% and 100% of the tree seedlings (e.g., more than 60%, more than 70%, more than 80%, more than 90%, more than 95%, or more than 99%.

Some embodiments of the invention include at least one additional pruning step (e.g., one, two, three, four or five root pruning steps) between the first and the second root pruning steps. In each of these additional root pruning steps the roots of a majority of the seedlings are pruned shorter than in the second pruning step (i.e., the roots of each individual seedling within the majority of seedlings are pruned closer to the vertical axis of the seedling during the additional pruning step than during the second pruning step). In each of these additional root pruning steps the roots of a majority of the seedlings may be pruned shorter or wider compared to the first pruning step. For example, in some embodiments the roots are pruned wider in the additional root pruning step compared to the first root pruning step (i.e., the roots of each individual seedling within the majority of seedlings are pruned further from the vertical axis of the seedling during the additional pruning step than during the first pruning step).

Other root pruning techniques (e.g., root wrenching, root undercutting) may be utilized in the practice of the present invention. A representative method of root wrenching involves sliding a metal blade under the bed of seedlings, and moving the blade through the soil. The blade is not horizontal, but is tipped forward slightly and so creates shock waves in the soil as the blade moves. The shock waves damage at least some of the seedling roots. The roots of the seedlings can be wrenched on one or more occasions (e.g., before and/or after any of the root pruning steps).

The methods of the invention are applicable to any tree species, such as coniferous tree species including firs and pines. Representative examples of tree species that can be treated in accordance with the methods of the invention include loblolly pine, shortleaf pine, slash pine, radiata pine, ponderosa pine and douglas fir.

Typically, in the practice of the invention tree seedlings are between four months old and six months old when they are pruned in the first root pruning step. The roots must have grown sufficiently long to be pruned by whatever pruning means is utilized. The second root pruning step typically occurs within six months after the first root pruning step, but may occur later than six months after the first root pruning step.

The population of tree seedlings is arranged as at least two adjacent row pairs of seedlings. An advantage to arranging the seedlings in adjacent row pairs is that the area between the row pairs is readily accessible for laterally pruning the seedling roots. Thus, for example,

FIG. 1

shows an aerial view of a population of tree seedlings

10

. The arrangement of individual tree seedlings

12

shown in

FIG. 1

is an art-recognized arrangement that is used by foresters to commercially cultivate coniferous tree species, such as douglas-firs, true firs and pines. Individual seedlings

12

are arranged in rows, which, in turn, are arranged as eight adjacent row pairs which are numbered

14

,

16

,

18

,

20

,

22

,

24

,

26

and

28

. In the exemplary embodiment shown in

FIG. 1

, each row pair

14

,

16

,

18

,

20

,

22

,

24

,

26

and

28

contains twenty seedlings

12

; although, in operation, each row pair

14

,

16

,

18

,

20

,

22

,

24

,

26

and

28

may contain more, or less, than twenty seedlings

12

. Exemplary seedling densities are from 30 to 120 seedlings per lineal bed foot (a lineal bed foot (LBF) is 4 ft

2

of bed surface space). Seedling densities for some tree species, such as douglas-fir, can be as high as 200 to 300 seedlings per lineal bed foot.

FIG. 2

shows an end view of population of tree seedlings

10

shown in

FIG. 1

, with the soil cut away. Thus,

FIG. 2

shows seedling roots

30

and seedling aerial portions

32

.

As shown in

FIGS. 3 and 4

, in one embodiment of the invention, only row pairs

14

,

16

,

20

,

22

,

26

and

28

are present. Row pair

14

is hereinafter referred to as first row pair

14

; row pair

16

is hereinafter referred to as second row pair

16

; row pair

20

is hereinafter referred to as third row pair

20

; row pair

22

is hereinafter referred to as fourth row pair

22

; row pair

26

is hereinafter referred to as fifth row pair

26

; and row pair

28

is hereinafter referred to as sixth row pair

28

.

Seedlings

12

that would otherwise be present in row pairs

18

and

24

are disposed in first row pair

14

, second row pair

16

, third row pair

20

, fourth row pair

22

, fifth row pair

26

and sixth row pair

28

, thereby leaving gaps where row pairs

18

and

24

would otherwise be located. Typically, although not necessarily, the seed from row pairs

18

and

24

are distributed evenly among first row pair

14

, second row pair

16

, third row pair

20

, fourth row pair

22

, fifth row pair

26

and sixth row pair

28

.

Thus, in the embodiment shown in

FIGS. 3 and 4

, first row pair

14

and second row pair

16

define first inter-row space

34

; second row pair

16

and third row pair

20

define second inter-row space

36

; third row pair

20

and fourth row pair

22

define third inter-row space

38

; fourth row pair

22

and fifth row pair

26

define fourth inter-row space

40

; and fifth row pair

26

; and sixth row pair

28

define fifth inter-row space

42

. The area adjacent to first row pair

14

, and external to population of tree seedlings

10

, is first adjacent area

44

; and the area adjacent to sixth row pair

28

, and external to population of tree seedlings

10

, is second adjacent area

46

.

In the practice of the invention, growth of roots

30

of tree seedlings

12

is stimulated by laterally pruning roots

30

on two separate occasions. Roots

30

are pruned shorter during the first root pruning step than during the second root pruning step. For example, as shown in

FIG. 5

, in an embodiment of the invention utilizing the arrangement of seedlings

12

shown in

FIGS. 3 and 4

, the first lateral pruning step utilizes a set of nine, spaced, circular, blades, called Coulter discs (that are typically attached to a motorized frame that pushes them through the soil), that are identified in

FIG. 5

as first Coulter

48

, second Coulter

50

, third Coulter

52

, fourth Coulter

54

, fifth Coulter

56

, sixth Coulter

58

, seventh Coulter

60

, eighth Coulter

62

, and ninth Coulter

64

. Coulters

48

,

50

,

52

,

54

,

56

,

58

,

60

,

62

,

64

are rolled through the soil in inter-row spaces

34

,

36

,

38

,

40

, and

42

, and through the soil in adjacent areas

44

and

46

, so that the circumference of each Coulter cuts roots

30

growing outward from seedlings

12

.

As shown in

FIG. 6

, in the embodiment of the invention utilizing the arrangement of seedlings

12

shown in

FIGS. 3 and 4

, the second lateral pruning step utilizes a set of four Coulters identified as tenth Coulter

66

, eleventh Coulter

68

, twelfth Coulter

70

and thirteenth Coulter

72

, that are rolled through the soil in second inter-row space

36

and fourth inter-row space

40

, and through adjacent regions

44

and

46

. Thus, fewer Coulters are used to accomplish the second lateral pruning step than the first lateral pruning step, and Coulters

66

,

68

,

70

and

72

are spaced further from seedlings

12

than are Coulters

48

,

50

,

52

,

54

,

56

,

58

,

60

,

62

,

64

. Consequently, roots

30

of seedlings

12

are pruned shorter during the first pruning step than during the second pruning step. It will be understood that tenth Coulter

66

, eleventh Coulter

68

, twelfth Coulter

70

and thirteenth Coulter

72

can be an appropriately spaced subset of first Coulter

48

, second Coulter

50

, third Coulter

52

, fourth Coulter

54

, fifth Coulter

56

, sixth Coulter

58

, seventh Coulter

60

, eighth Coulter

62

, and ninth Coulter

64

. Although Coulters having a smooth circumference are shown in the figures, other types of Coulters are also useful, such as Coulters having a serrated circumference. Examples of useful Coulters are those sold by Summit Equipment, New Zealand.

The following examples merely illustrate the best mode now contemplated for practicing the invention, but should not be construed to limit the invention.

EXAMPLE 1

This Example describes a representative method of the invention for pruning the roots of loblolly pine seedlings.

Three row pairs of loblolly pine seeds are each planted in a nursery bed in the pattern shown in

FIGS. 3 and 4

. The width of the nursery bed is typically about four feet. The length of the nursery bed is typically in the range of from one hundred feet to 1600 feet. Typically, eight seeds are planted, per foot, in each row within each row pair. The seed are sown in Spring and thereafter germinate to yield three row pairs of seedlings. In July of the year in which the seed are planted, the seedling roots are laterally pruned using nine Coulter discs that are rolled through the soil on either side of each row pair of seedlings. The arrangement of the nine Coulter discs is as shown in FIG.

5

.

The seedling roots are again laterally pruned, usually sometime after October of the year in which the seedlings were planted, although this pruning can occur earlier (e.g., in September of the year in which the seedlings were planted), or later (e.g., in January of the following year). This pruning uses only four Coulter discs, which are spaced further from the seedlings than in the root pruning step in July. The arrangement of the four Coulter discs is as shown in FIG.

6

. Typically, in January of the year following the year in which the seed are planted, the seedlings are removed from the nursery beds, and may be stored or transplanted to a growth site, such as a tree plantation. The seedlings may be removed from the nursery beds anytime from November of the year in which they are planted to March of the second year after the year in which they are planted.

While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention.