This study tested the effectiveness of direct seeding to establish framework tree species, for restoring forest ecosystems at an opencast lignite mine in Lampang Province, Thailand. A randomized complete block design (RCBD) experiment tested five tree species ( Afzelia xylocarpa (Kurz) Craib, Eugenia cumini (L.) Druce, Ficus racemosa Roxb., Gmelina arborea Roxb. and Schleichera oleosa (Lour.) Oken) with 5 substrate amelioration treatments and 3 replicates. Germination percent was the highest for Afzelia xylocarpa (88.1%) and lowest for Ficus racemosa (5.9%). The substrate amelioration treatments had no significant effects on both seed germination and seedling establishment for all species tested. Schleichera oleosa had the highest seedling establishment percent (45%) followed by Afzelia xylocarpa (40%) . A suitability scoring system indicated that these two species were the most suitable for direct seeding to complement other techniques of mine site rehabilitation in northern Thailand, where establishment of indigenous forest tree species is required for biodiversity recovery.
Worldwide, around 13 million ha of forests are destroyed or degraded each year, according to the Food and Agriculture Organization of the UN (FAO, 2010). The main cause is conversion of forestland to agriculture (FAO, 2007; FAO, 2010), but infrastructure developments, also play a major role. Thailand’s Northern provinces were once densely forested, but over the past 100 years, natural forest cover has significantly declined (Walker, 2002). Despite a ban on commercial logging since 1989, eight kinds of infrastructure developments have wiped out over 480,000 hectare of Thailand’s forests (10% of total losses), over the past four decades, including 77128.96 ha destroyed by mining (www.bangkokpost.com/lifestyle/family/374915/clearing-the-way).
Mining of lignite is having a significant impact on the forests of northern Thailand, where large open cast mines, in mostly forested areas, produce around 21 Mt/y, almost exclusively for power generation (Kessels, 2010). With an estimated 1400 Mt of recoverable reserves remaining, the problem of rehabilitating such mines is likely to grow in the future. Mining has huge adverse effects on the surrounding environment, including removal of topsoil and overburden, as well as changes to topography, streams and vegetation. Although Thai Government laws require restoration of natural forest to mine sites (Sivavong and Limkitisupasin, 2005), mining companies are struggling to come up with effective methods to re-establish natural forest ecosystems on such harsh, degraded sites.
Research on forest rehabilitation has often focused on the use of tree plantations to accelerate secondary succession in altered areas (Parrotta, 1992; Lugo, 1997), whilst the most ambitious goal of restoration is the re-establishment of high levels of biomass, structural complexity, biodiversity and ecological functioning, similar to that of the indigenous climax forest ecosystem (Elliott et al., 2013; Schmidt-Vogt, 2001; Nepstad et al., 1996). In recent years, new forms of forest restoration may offer alternative ways of dealing with degraded tropical forest landscapes. Two broad approaches have been tested; one is to use a small number of indigenous tree species to create canopy cover, whilst additional native species reach the site by natural seed dispersal from nearby intact forest.
The framework species method of forest restoration firstly developed in Queensland, Australia (Goosem and Tucker 1995; Lamb et al. 1997; Tucker 2000; Tucker and Murphy 1997). It has been successfully adapted to restore several Thailand’s forest types on non-mine sites (Elliott et al., 2013). It only works where mature forest and seed-dispersing animals still exist nearby. Another approach uses a much greater number of species, representative of more mature succession stages, without relying so much on natural succession to complete biodiversity recovery (Lamb et al., 2005). This is the maximum diversity approach (Goosem and Tucker, 1995). It requires sufficient ecological knowledge to collect seeds and germinate large numbers of seedlings from a wide variety of species (FORRU, 2006) and the key limitation is high cost (Erskine, 2002).
Tree planting is costly and requires high labor inputs. Direct seeding can significantly reduce restoration costs because labor and time for raising seedlings in nurseries are not required (Woods and Elliott, 2004). However, the technique is constrained by the need for adequate soil moisture, to create optimum conditions for germination and early seedling growth (Moles and Westoby, 2006; Shankar, 2006). Therefore, soil amelioration treatments could greatly increase the efficiency of the technique, particularly on more degraded sites, such as mines, although little field research has been done on the effectiveness of soil conditioning materials. Consequently, this project tested the effectiveness of direct seeding of framework species in a lignite mine site, and determined whether soil conditioners could substantially improve success rate.
This study was carried out at the lignite mine of Siam Cement Group in Mae Than district, Lampang Province (17˚57'16"N, 99˚26'05" E; elevation 400 m), Thailand. The mean annual temperature at the site is 27.3˚C, with mean annual precipitation of 1326 mm, most of which falls between May to October. The original vegetation of the area was forest ecosystems typical of lowland northern Thailand: deciduous, dipterocarp-oak forest along ridges and in driers sites, with seasonal, hardwood forest mixed with bamboo in along the gullies and moister sites (Maxwell and Elliott, 2001). At the beginning of the study, there was no vegetation in the study area.
Soil tests showed that the study site soil was moderately alkaline (pH 7.94) with very low organic matter content (0.193%) and nitrogen levels, but relatively high phosphorus and medium potassium levels compared with the normal soil properties range (Jensen, T. L., 2010; see
Chemical properties | pHd | OM%d | Total N (mg/kg)b | Organic carbon (%)d | Available P (mg/kg)c | Exchangeable K (mg/kg)d |
---|---|---|---|---|---|---|
Averagea | 7.94 | 0.193 | 0.06 | 0.11 | 48.59 | 110.05 |
aAverage value for the chemical properties (n = 6), bTotal-N (Bremner & Mulvaney, 1982). cAvailable-P (Olsen & Sommers, 1982), dOthers chemical properties-Siwasil, 1984.
Five indigenous forest tree species were selected: Afzelia xylocarpa (Kurz) Craib, Eugenia cumini (L.) Druce, Ficus racemosa Roxb., Gmelina arborea Roxb., and Schleichera oleosa (Lour.) (
Biosolids were obtained from the Pepsi Cola-Lays Company’s waste water plant, Lamphun, Thailand. The waste was generated from potato chip production. It had a pH of 7.72 and contained 19.75 g organic matter per 100 gm (dry mass), 1.57 g/kg total-nitrogen, 68.72 mg/kg phosphorus and 777.7 mg/kg potassium. Compost used in this study was made from urban organic wastes and cow feces in the ratio 3:1. The fertilizer used in this experiment was N:P:K, 1:2:1.
The field trial was a randomized complete block design (RCBD) with 5 substrate amelioration treatments and 3 replicates. The treatments were: 1) biosolids (1 kg) +fertilizer (50 g); 2) biosolids (1 kg) – fertilizer; 3) compost (1 kg) + fertilizer (50 g); 4) compost (1 kg) − fertilizer and 5) control (no substrate amelioration treatment). Each replicate sub-plot consisted of 36 seed sowing points, each marked by a bamboo pole (color coded by treatment), about 1.2 m apart, laid out in a square grid pattern 6 × 6 points over 7.2 × 7.2 m2. At each sowing point, one seed of each of the five species was sown into PVC tubes (5.5 cm in diameter) about 40 cm apart (color coded to match the species). Seed germination was monitored every week for 3 months. Germination data were collected every one week, to calculate per cent germination and length of dormancy. For each seedling germinated in the field; height, RCD (root collar diameter) and health score (0 = dead to 3 = good health) were recorded for 5 months (FORRU, 2008).
Data were analyzed by Microsoft Excel 2007 Data Analysis Tool pack. The median length of dormancy (MLD) and percent germination were calculated at the end of the germination trial. A two way ANOVA without replication was performed to detect any significant differences in germination and establishment percentages among species and treatments in the experiment. Student’s t-test (paired two samples for means) was performed when ANOVA results showed any significant differences on Percent germination, percent establishment in experiment conditions.
A performance score was calculated based on establishment, combined with RCD to determine which species were most suitable for direct seeding on mine sites. First, species with survival percentages less than 10% by the
Species | Afzelia xylocarpa (Kurz) craib | Eugenia cumini L. Druce | Ficus racemosa L. | Gmelina arborea Roxb. | Schleichera oleosa (Lour.) oken |
---|---|---|---|---|---|
Family | Leguminosae | Myrtaceae | Moraceae | Verbenaceae | Sapiandaceae |
Seed sizea | Large | Small | Small | Medium | Medium |
Seed coatb | Thick | Thin | Thin | Thick | Thick |
Seed shapec | Ovoid | Round | Round | Ovoid | Ovoid |
Orthodox/Recalcitrant | Orthodox | Recalcitrant | Orthodox | Intermediate | Orthodox/ Intermediate |
Pre-sowing treatment | Scarification | Soaked in water and dried in shade | Nothing | Soaked in water and sundried | Soaked in water and sun dried |
aSeed size category based on seed weight: S small (<0.01 - 0.099 g); I intermediate (0.1 - 4.99 g); L Large (>5.0 g) (seed size category determined from mean of a random sample of no less than 20 seeds per species) (Doust et al. 2006). bSeed coat thickness: Thin (<0.01 - 0.099 mm); moderate (0.1 - 0.49 mm); Thick (>0.5 mm) (FORRU, Database). Seed shape: R round (variance < 0.06); O = Oval (variance = 0.06 - 0.09); F flat (variance > 0.09).
middle of 2nd rainy season (expressed as a percentage of seed sown) were rejected. Then for all those species which exceeded this threshold, the score was calculated using the formula:
Germination percentages, averaged across all treatments, differed significantly among species (p < 0.05). Highest germination was achieved by A. xylocarpa 88% and lowest by F. racemosa 5.9%. T-tests revealed that percent germination of Afzelia xylocarpa and Schleichera oleosa was significantly higher than that of other species, across all treatments. Three species exhibited rapid germination (i.e. short MLD) (A. xylocarpa, S. oleosa and G. arborea) (p < 0.05).
Germination by treatment, averaged across species, was highest with biosolids + fertilizer (46%) and lowest with compost + fertilizer (39%) (
The overall performance of Afzelia xylocarpa and Schleichera oleosa was outstanding, within treatments. The rank suitability score of Afzelia xylocarpa and Schleichera oleosa was more than 40% (See 2.6). Highest score was achieved by Afzelia xylocarpa in biosolids + fertilizer (and was assigned a value of 100%) (
Species, suitable for direct seeding, must have not only high germination percent, but also rapid germination. The latter minimizes the time, during which they are vulnerable to seed predation and maximizes the establishment period (particularly root growth), before onset of the dry season (Lamb, 2011). Rapid seedling growth is
Biosolids + fertilizer | Biosolids | Compost + fertilizer | Compost | Control | |
---|---|---|---|---|---|
No. of seed sown in five species | 540 | 540 | 540 | 540 | 540 |
No. of germinated seed | 249 | 229 | 210 | 237 | 238 |
Percent germination | 46.1 (14.44)a | 42.4 (15.44)a | 38.9 (13.77)a | 43.9 (14.77)a | 44.1 (18.04)a |
MLD (in Days) | 40 (7.80)a | 30 (6.69)a | 29 (2.80)a | 44 (7.68)a | 32 (4.05)a |
Percent seedling establishment | 22.8 (8.92)a | 20.0 (9.96)a | 18.0 (7.78)a | 20.0 (8.62)a | 21.5 (10.84)a |
*Note: Standard errors are in brackets (SE).
Species | Treatments | Establishment | Root-collar diameter (mm) | Raw suitability score | Rank suitability score (0% - 100%) |
---|---|---|---|---|---|
Afzelia xylocarpa | Biosolids + fertilizer | 47.2 | 12.0 | 569 | 100 |
Schleichera oleosa | Control | 49.1 | 9.8 | 480.8 | 84.5 |
Schleichera oleosa | Compost | 41.7 | 10.1 | 420.1 | 73.8 |
Schleichera oleosa | Biosolids + fertilizer | 41.7 | 7.8 | 326.6 | 57.4 |
Afzelia xylocarpa | Biosolids | 49.07 | 6.48 | 317.9 | 55.87 |
Schleichera oleosa | Biosolids | 38.09 | 8.0 | 312.1 | 54.8 |
Afzelia xylocarpa | Control | 46.3 | 6.5 | 300.9 | 52.9 |
Afzelia xylocarpa | Compost + Fertilizer | 43.5 | 6.1 | 266 | 46.7 |
Schleichera oleosa | Compost + fertilizer | 28.7 | 9.2 | 262.8 | 46.2 |
Afzelia xylocarpa | Compost | 39.8 | 6.4 | 256.7 | 45.1 |
also needed for successful direct seeding, in order for tree seedlings to out-compete surrounding vegetation (Engel and Parrotta, 2001; Doust et al., 2008). Therefore, both parameters were combined to calculate the suitability score.
Seed characteristics may explain the differences in species’ responses in the trial. A. xylocarpa and S. oleosa both achieved an acceptable level (i.e. percent germination and establishment were significantly higher and MLD’S were significantly shorter, compared with other species). Both species have medium to large seed size with thick seed coats, in agreement with the suitable seed characteristics for direct seeding identified by Tunjai and Elliott (2011). Large seeds have greater tolerance of stresses, since higher resources can be allocated to tolerate particular stresses, such drought or shade (Coomes & Grubb, 2003; Helene C. Muller-Landau, 2010), whereas small-seeded species cannot tolerate stresses, because food resources within the seed are limited.
However, thick seed coats can delay germination (Tunjai, 2005), so pre-sowing treatments are often necessary to shorten dormancy, resulting from a hard seed coat. In this experiment, a pre-sowing treatment was used for the hard-coated seed species. This accounts for the shortened dormancy recorded for the hard-coated species.
The lack of treatment effects may be due to the application of insufficient amounts of the substrate amelioration substances (
The success of A. xylocarpa might be attributable to the fact that it is a leguminous species, notable for being able to fix nitrogen (Cervantes, Carabias and Vazquez-Yanes, (1996); Garg, (1999); Siddique et al., (2008) and thus survive and grow well on degraded, nutrient poor sites (Engel and Parrotta, 2001). Furthermore, high germination percent A. xylocarpa was achieved by scarification to overcome seed coat dormancy (Tunjai, 2005).
The final germination percent and establishment of S. oleosa were also high enough to allow this species to be considered suitable for direct seeding (
Lastly, F. racemosa was unacceptable for direct seeding, because of low percent germination and long dormancy
The suitability score was calculated from percent establishment and growth performance by the middle of the 2nd rainy season after sowing (
However, further study is needed to ensure wider acceptability of this technique. Compact substrates are vulnerable to accumulation of surface water, which was a problem in this study. Further experiments are needed to determine which species may more resistant to water logging. Top soil replacement also needs further investigation, to improve aeration and drainage and provide developing seedlings with more nutrients. This may improve the success rate of direct seeding of more species. Top soil replacement worked very well for conventional seedling planting trials at a nearby mine (Lime stone mine, FORRU (unpublished data)). Further experiments should be conducted on managing the soil ph, since the soil report indicated an acidic soil. Further experiments should also be conducted to test the effects of microbial treatments (Shetty et al., 1994).
In conclusion, direct seeding could make a significant contribution towards mine restoring forest to open cast mines, although the number of species that respond well to the method is limited and further work is clearly needed to develop suitable soil treatments to improve the success rate. This paper showed that A. xylocarpa and S. oleosa have already been used successfully for direct seeding on mine sites in northern Thailand to complement conventional tree planting of other species. Top soil replacement is recommended for further investigation to develop the techniques for other species.
We thank the staff of the Forest Restoration Research Unit, Chiang Mai University for their assistance, as well as SCG staff at the Lampang mine for logistical support on-site. We are also very grateful for institutional support from Environmental Science Program in Chiang Mai University. Last but not the least; I would like to give special thanks to Elephant Nature Park for their cordiality to sponsor the study coast for my Master’s degree in Chiang Mai University.