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"ABSTRAKDengan mengfokuskan berkas pulsa laser karbon dioksida pada berbagai macam target pada tekanan rendah, akan terbentuk plasma yang unik. Dalam disertasi ini struktur dan dinamika dari plasma yang unik ini dapat diperoleh dengan mengembangkan metode pengamatan plasma yang baru yaitu pengukuran distribusi ruang dari intensitas emisi pada berbagai waktu tunda. Plasma ini terdiri atas daft bagian; pertama yaitu bagian kecil dari plasma (disebut plasma primer) yang memancarkan spektrum emisi kontinu hanya untuk beberapa seat diatas permukaan target. Bagian yang lain (plasma sekunder) mengembang sesuai waktu disekeliling plasma primer, memancarkan spektrum garis atomik yang sangat tajam dengan emisi latar belakang yang sangat rendah.Juga ditunjukan bahwa emisi dari atom-atom yang terpancar keluar dari target membentuk struktur kulit (tipis), dan ionisasi dari atom-atom berlangsung lebih lambat dari pada eksitasi dari atom-atom netral. Laju pergeseran dari muka emisi adalah sebanding dengan waktu pangkat due per lima. Juga berhasil diamati bahwa titik dimana sinyal emisi mulal tampak adalah sama untuk berbagai macam target meskipun berbeda pada berat atomnya. Hasil ini mendukung model bahwa plasma sekunder dibentuk mengikuti prinsip gelombang kejut dengan plasma primer sebagai sumber energi awal.Dengan memakal gas helium dan argon disekeliling target pada tekanan rendah, dua proses eksitasi yang berbeda terjadi pada saat pembentukan plasma sekunder. Proses eksitasi pertama disebabkan oleh mekanisma gelombang kejut, sedangkan eksitasi kedua disebabkan oleh tingkat energi metastabil pada gas mulia. Proses eksitasi kedua ini menyalurkan energi metastabil yang disimpan oleh gas mulia pada atom-atom yang dipancarkan oleh target meskipun lama setelah pulsa laser berakhir, sehingga menghasilkan intensitas emisi yang lebih tinggi di gas mulia dibandingkan di udara.Temperatur tinggi pada plasma sekunder sebagai akibat dari kecepatan propagasi yang tinggi dari muka plasma menyebabkan plasma ini sangat cocok digunakan untuk mendeteksi atom-atom halogen yang biasanya sangat sukar diidentifikasi karena tingkat energinya yang sangat tinggi. Aplikasi analitis untuk mendeteksi unsur halogen pada contoh bubuk kimia maupun kalsium pada bahan makanan menunjukkan hubungan yang linter pada kurva kalibrasi. dalam metode Laser Microprobe Spectrochemical Analysis (LHSA) yang umum dipakai hingga saat ini untuk analisa spektrokimia, tidak terdapat hubungan yang tinier pada kurva kalibrasinya karena timbul penyarapan sendiri (self absorption) yang sangat kuat, .lumlah minimum yang dapat dideteksi untuk Cl adalah 5 ppm dan 10 ppm untuk Ca, yang mane Jauh lebih balk dibandingkan dengan metode Induction Couple Plasma (ICP) maupun metode lain. Hingga saat ini metode ICP adalah metode ter-balk yang banyak dipakal untuk analisa elemen-elemen pads bahan makanan. Metode kami akan dikembangkan menjadi metode analisa kuantitatif yang cepat, akurat dan. memiliki sensitivitas yang tinggi tidak Baja pada bahan makanan tetapi juga pada bahan biologi, geologi dan lain-lain.

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ABSTRACT

A study has been conducted on the formation of the unique plasma generated by focusing a TEA CO2 laser onto various targets with low pressure surrounding gases. A new method of time-resolved measurement of spatial distribution of the plasma was carried out for analyzing the plasma structure and dynamics. The unique laser induced plasma consists of two distinct regions; the first is a small area of plasma (called primary plasma), which gives off intense continuous emission spectra for a short time just above the surface of the target. The other area (secondary plasma) expands with time around the primary plasma, emitting sharp atomic line spectra with negligibly low background signals.

It is clearly shown that emission due to the gushed atoms from the target form shell structure, and the ionization of the atoms proceeds at slower rate than the excitation of the neutral atoms. The displacement of the emission expansion is proportional to the two-fifths power of time. It has been also observed that the rising point in the time-resolved spatial distribution of the emission 1s the same regardless of the difference in atomic weight. These results support the model that the secondary plasma is excited by a shock wave with primary plasma serving as the initial explosion source.

By using helium and argon as a surrounding gases, two different excitation processes take place in farming the secondary plasma. The first excitation process is due to the shock wave mechanism, while the second process is due to the metastable state of the noble gases. It is believed that this second process transfers metastable energy to the vaporized atoms of the target for emission, even long after the laser bombardment ends, thus giving total emission intensity that is higher in the noble gases than yielding in air.

The high temperature generated in the secondary plasma as a result of its high propagating front speed has made it favorable for use in detecting atoms such as halogens which are usually very difficult to identify because of their high lying electronic energy level. Analytical application to the detection of halogen atoms in chemical powder and calcium in food material shows good linearity in the calibration curve. In the ordinary Laser Microprobe Spectra-chemical Analysis (LMSA), the calibration curve is not linear due to the strong self absorption. The detection limit of Cl, Ca is 5 ppm and 10 ppm respectively which is-better than ICP (50 ppm for Cl) and other methods. So far, ICP emission spectrometry has been used as the most convenient method for simultaneous multi elemental analysis of food materials. Our method will be developed as a rapid, high-precision, highly sensitive quantitative analytical method for not only food materials but also other biological and geological samples."

"A comprehensive study has been made on the dynamical process-taking place in the laser-plasma generation induced by a TEA CO2 laser bombardment on metal target and non-metal target from low to high pressures surrounding gas. In the case of metal target, pure zinc plate was used as a target and bombarded with 400-mJ-laser pulse energy. Dynamical characterization of plasma expansion and excitation were examined in detail both for target atomic emission (Zn I 481.0 nm) and gas atomic emission (He 1 587.6 nm) by using a unique time-resolved spatial distribution measurement and conventional emission spectroscopic detection method. The results showed that the plasma expands and develops with time. The mechanism of plasma generation can be classified into three cases depending on .the surrounding gas pressures; target shock wave plasma in the pressure range between 2 Ton and 20 Ton, coupling shock wave plasma in the pressure range between 50 Torr and 200 Torr and gas break down shock wave plasma in the pressure range between 200 Ton and I atm. In all cases in the laser-plasma generation under TEA CO2 laser bombardment on metal target, shock wave process always plays important role for exciting the target atoms and gas molecules.In the case of non-metal target, a museum glass was used as a target and bombarded with a 400 nd laser pulse energy. By using the conventional emission spectroscopic detection method, namely temporally and spatially integrated and time-resolved spatially integrated of plasma emission, it was shown that the plasma mainly consists of target atomic emission. Only weak gas atomic emission intensity could be observed even at I atm of surrounding gas pressure. These results indicate that the gas breakdown is not a major process responsible to the plasma formation even at high pressure surrounding gas. Shock wave process was considered as an important role in this plasma formation. By the use of shadowgraph technique to detect the density jump signal due to the shock wave front involving a He-Ne laser as a probe light, simultaneous detection of the shock wave front and the emission front was successfully implemented. The result showed that at the initial stages of plasma expansion shock wave front and emission front coincide and move together with time. At the later stages of plasma expansion the two fronts became separate with the emission front left behind the shock wave front. These results are completely coinciding with the shock wave plasma model. Unfortunately, in this experiment we succeed to detect the density jump signal only for high pressure surrounding gas, above 100 Torr. At the pressures lower than 100 Torr the density jump signal was very weak and it is difficult to distinguish with the noise including in the signal.The other important experimental results that support the shock wave plasma model were also obtained in this experiment, namely the coincidence of emission front regardless of their atomic weight and sub-target effect. By using lead glass as a sample, which contain Pb, Si, and Ca, it was confirmed that the emission front of the Pb I 450.8 nm, Si 1288.2 nm and Ca I 422.6 nm almost coincide regardless of their atomic weight. This result also supports the shock wave plasma model because, by the stagnation of the propelling atoms, the front position of the all atoms coincides regardless of its mass. In the case of sub-target effect, confirm that plasma could be produced even for soft target if sub-target is set behind the sample. In this case we use a quartz sample as a sub-target and a vinyl tape was attached to the quartz sample as a target. The TEA CO2 laser bombardment was used at 150 ml and at 1 atm of air. The main role of the subtarget is to produce a repulsion force for atom gushing with high speed. For shock wave, high speed is necessary condition to compress the gas.Coincidence of the movement of the shock wave front and the emission front in the initial stages of plasma expansion is a direct proof of the shock wave plasma model. By improving the detection technique of the density jump associated with the shock wave, the correlation between the shock wave front and the emission front was examined in detail. For this purpose rainbow interferometer system, which has higher sensitivity compared with the shadowgraph technique, was used to detect the density jump signal. We succeed to realize simultaneous detection of shock wave front and emission front from 3 Ton until 1 atm of air when a quartz sample is bombarded with a 600 nil TEA C02 laser. In all pressure that were examined, the shock wave front and the emission front always coincide and move together with time in the initial stages and separate at the later stages with emission front left behind the shock wave front. The coincidence of the shock wave front and emission front and move together with time at the initial stages of plasma expansion was also obtained by using ruby as a sample at 10 Torr and 100 Ton of air as well as with museum glass at the same laser pulse energy.Another important experimental result obtained in this experiment is that confirmation of the coincidence of the target atomic emission front and gas atomic emission front and density jump. This confirmation was obtained by examined a Quartz sample in 50 Ton of helium and a zinc sample in 100 Ton of helium. This result strongly supports the shock wave plasma model because, in ordinary shock tube experiment, gas emission takes place just behind the shock wave.From a practical point of view of direct microanalysis for spectrochemicaI application of alloy metal samples such as brass, selective vaporization effect was also studied. The results showed that even for Nd-YAG laser with short pulse duration (8 ns) and high power density (30 GWcm 2), selective vaporization take place to a certain extend. It was demonstrated in this experiment that selective vaporization is enhanced if the laser irradiation was repeated on the same spot of sample surface. Meanwhile it was also shown in this experiment that the effect of selective vaporization could be significantly suppressed by increasing the surrounding gas pressure from 2 Toff to around 50 Torr of air."

"A special interferometric technique with high sensitivity has been devised on the basis of rainbows refractometer without the use of an additional and delicate amplitude-splitting setup. This new technique was use for the characterization of shock wave plasma induced by a Q-sw Nd-YAG laser on various kinds of metal samples under reduced gas pressures. An unmistakable signal of density jump was detected simultaneously with the emission front signal. It is proved that at the initial stage of the secondary plasma expansion, the front of the emission and the front of the blast wave was coincide and move together with time. However, at a later stage, the front of the emission will separate from that of the blast wave induced in the surrounding gas at low pressures. Using Cu and Zn samples, the experimental result showed that the separation of the emission front and blast wave front took place at 4 mm above sample surface for the laser energy of 140 mJ."

"ABSTRAKSaat ini teknologi nuklir berkembang dengan baik di Indonesia dan pemanfaatannya baik di bidang kesehatan, pertanian, peternakan, industri dan energi digunakan sepenuhnya untuk kesejahteraan seluruh masyarakat Indonesia. Dalam pengembangan dan pemanfaatan teknologi nuklir tentu harus mempertimbangkan dan meminimalisir efek bahaya dari radiasi nuklir, baik untuk pekerja yang berada dilingkungan instalasi nuklir maupun bahaya kontaminasi lingkungan disekitar instalasi nuklir. Untuk itu kegiatan pemantauan, pendeteksian dan pengukuran radiasi mutlak diperlukan. Umumnya kegiatan pemantauan, pendeteksian dan pengukuran radiasi dilakukan dengan perangkat deteksi nuklir. Pada penelitian kali ini dilakukan metode alternatif pengukuran, analisis dan identifikasi unsur radioaktif dengan teknik laser induced plasma spectroscopy LIPS . Penggunaan teknologi LIPS dipilih karena LIPS adalah suatu teknik analisis sampel secara in situ, kualitatif dan kuantitatif yang cepat, dan hampir tanpa preparasi sampel. Analisis dan identifikasi unsur radiaoaktif dilakukan dengan menembakkan laser pulsa NdYAG Q-Switch 355 nm, 10 Hz, durasi pulsa 5.5 ns, f = 100 mm, dengan variasi energi 5.5 mJ - 140 mJ dan dengan variasi tekanan udara 4 Torr ndash; 1 atm pada sampel material radioaktif alamiah atau Naturally Occurring Radioactive Material NORM dengan metoda ablasi laser yang dilanjutkan dengan metoda spectral plasma analisis. Berdasarkan penelitian yang telah dilakukan, secara kualitatif teknik LIPS mampu mengidentifikasi adanya unsur radioaktif Uranium U dan Thorium Th yang terdapat pada sampel uji dengan energi laser optimum sebesar 107 mJ dan secara kuantitatif didapatkan nilai prediksi konsentrasi unsur Uranium sebesar 155 ppm dengan persentase error 11.3 dan nilai batas deteksi sebesar 7.89 ppm, nilai prediksi konsentrasi unsur Thorium sebesar 124 ppm dengan persentase error 8 dan nilai batas deteksi sebesar 12.4 ppm. Dengan kata lain teknik LIPS secara inheren sangat cocok dan sangat memungkinkan digunakan sebagai teknik pengukuran, analisis dan identifikasi keberadaan unsur radioaktif.

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ABSTRACTNuclear technology is currently well developed in Indonesia and its use in the field of health, agriculture, industry and energy is completely used for the welfare of all the people of Indonesia. In the development and utilization of nuclear technology should certainly consider and minimize the effects of nuclear radiation hazards, both for the workers who are in the environment of nuclear installations and the danger of contamination of the environment around nuclear installations. Therefore monitoring activity, detection and measurement of radiation is absolutely necessary. Generally the monitoring activity, detection and measurement of radiation carried by the nuclear detection devices. In this study, alternative methods of measurement, analysis and identification of radioactive elements is carried out by using laser induced plasma spectroscopy LIPS . The use of LIPS technology is selected since LIPS is a technique in situ sample analysis, qualitative and quantitative fast, and almost no sample preparation. Analysis and identification of the radioactive element is carried out by firing laser pulses NdYAG Q Switch 355 nm, 10 Hz, pulse duration of 5.5 ns, f 100 mm, with a variation of the energy 5.5 mJ 140 mJ and with variations in air pressure 4 Torr 1 atm in a sample of Naturally Occurring Radioactive Material NORM with laser ablation method, followed by plasma spectral analysis method. Based on the research that has been done, LIPS technique is qualitatively able to identify the presence of radioactive elements, i.e. Uranium U and thorium Th contained in the test sample with a laser energy optimum of 107 mJ and quantitatively obtained predictive value of elemental concentrations of Uranium of 155 ppm along with 11.3 of percentage error and 7.89 ppm of detection limit value, also the predictive value of the elemental concentration of thorum of 124 ppm along with 8 of percentage error and 12.4 ppm of detection limit value. In other words, LIPS technique is inherently very suitable and it is possible to use as a measurement technique, analysis and identification of the presence of radioactive materials."

"A TEA CO2 laser pulse (50 mJ, 100 ns) was focused under reduced pressure on the silicone grease painted on copper plate as a sub-target with a power density of 6 GW/cm2. The comparison was made on the characteristics of the induced laser plasma between the two cases, with sub-target and without sub-target. It is proved that emission spectrum assigned to silicone atom can be detected only for the case with sub-target. It is also proved that in the absence of the sub-target, the gushing speed of the atoms is very low, while for the case with sub-target, the gushing speed of atoms becomes very fast. It is shown that the setting of sub-target is very effective to make laser-induced shock-wave plasma and it is very effective to realize quantitative analysis of soft material."